Localwire.Graphinder.ndproj

<?xml version="1.0" encoding="utf-8" standalone="yes"?>
<NDepend AppName="Localwire.Graphinder" Platform="DotNet">
  <OutputDir KeepXmlFiles="False">C:\Repositories\Localwire.Graphinder\NDependOut</OutputDir>
  <Assemblies>
    <Name>Localwire.Graphinder.Core</Name>
    <Name>Localwire.Graphinder.Core.Tests</Name>
    <Name>Localwire.Graphinder.ConsoleApp</Name>
    <Name>Localwire.Graphinder.Algorithms.DataAccess</Name>
    <Name>Localwire.Graphinder.Users.Core</Name>
    <Name>Localwire.Graphinder.Users.Data</Name>
    <Name>Localwire.Graphinder.Algorithms.Data.Tests</Name>
    <Name>Localwire.Graphinder.Algorithms.Service</Name>
    <Name>Localwire.Graphinder.Algorithms.WorkerApi</Name>
    <Name>Localwire.Graphinder.Algorithms.GatewayApi</Name>
    <Name>GatewayService</Name>
    <Name>Localwire.Graphinder.Algorithms.DTO</Name>
  </Assemblies>
  <FrameworkAssemblies>
    <Name>mscorlib</Name>
    <Name>System.Core</Name>
    <Name>System</Name>
    <Name>System.Reactive.Core</Name>
    <Name>System.Reactive.Linq</Name>
    <Name>System.Reactive.Interfaces</Name>
    <Name>xunit.core</Name>
    <Name>NSubstitute</Name>
    <Name>xunit.assert</Name>
    <Name>EntityFramework</Name>
    <Name>System.Data.Entity</Name>
    <Name>System.Data</Name>
    <Name>System.Web.Optimization</Name>
    <Name>Autofac</Name>
    <Name>System.Web.Mvc</Name>
    <Name>RestSharp</Name>
    <Name>System.Web</Name>
    <Name>System.Web.Http</Name>
    <Name>Autofac.Integration.WebApi</Name>
    <Name>System.Configuration</Name>
    <Name>System.Web.Http.WebHost</Name>
    <Name>Microsoft.Owin</Name>
    <Name>Microsoft.AspNet.Identity.Core</Name>
    <Name>Microsoft.AspNet.Identity.Owin</Name>
    <Name>Microsoft.Owin.Security</Name>
    <Name>Microsoft.Owin.Security.OAuth</Name>
    <Name>Owin</Name>
    <Name>System.Net.Http</Name>
    <Name>System.ComponentModel.DataAnnotations</Name>
    <Name>Microsoft.AspNet.Identity.EntityFramework</Name>
    <Name>System.Web.Http.Owin</Name>
    <Name>Microsoft.Owin.Security.Cookies</Name>
  </FrameworkAssemblies>
  <Dirs>
    <Dir>C:\Repositories\Localwire.Graphinder\Algorithms\Localwire.Graphinder.Algorithms.Core\bin\Debug</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Algorithms\Localwire.Graphinder.Algorithms.Core.Tests\bin\Debug</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Localwire.Graphinder.Console\bin\Debug</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Localwire.Graphinder.Users.Core\bin\Debug</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Localwire.Graphinder.Users.Data\bin\Debug</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Algorithms\Localwire.Graphinder.Algorithms.Data.Tests\bin\Debug</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Algorithms\Localwire.Graphinder.Algorithms.WorkerService\bin\Debug</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Algorithms\Localwire.Graphinder.Algorithms.WorkerApi\bin</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Algorithms\Localwire.Graphinder.Algorithms.GatewayApi\bin</Dir>
    <Dir>C:\Repositories\Localwire.Graphinder\Algorithms\Localwire.Graphinder.Algorithms.GatewayService\bin\Debug</Dir>
    <Dir>C:\WINDOWS\Microsoft.NET\Framework\v4.0.30319</Dir>
    <Dir>C:\WINDOWS\Microsoft.NET\Framework\v4.0.30319\WPF</Dir>
  </Dirs>
  <MergeCodeGeneratedByCompiler>True</MergeCodeGeneratedByCompiler>
  <Report Kind="0" SectionsEnabled="45055" XslPath="" Flags="261120" />
  <BuildComparisonSetting ProjectMode="DontCompare" BuildMode="MostRecentAnalysisResultAvailable" ProjectFileToCompareWith="" BuildFileToCompareWith="" NDaysAgo="1" FocusOnRecentRulesViolations="False" />
  <BaselineInUISetting ProjectMode="DontCompare" BuildMode="MostRecentAnalysisResultAvailable" ProjectFileToCompareWith="" BuildFileToCompareWith="" NDaysAgo="1" FocusOnRecentRulesViolations="False" />
  <CoverageFiles CoverageDir="" UncoverableAttribute="" />
  <TrendMetrics UseCustomLog="False" LogRecurrence="3" LogLabel="2" UseCustomDir="False" CustomDir="">
    <Chart Name="Lines of Code" ShowInReport="True">
      <Serie MetricName="# Lines of Code" MetricUnit="Loc" Color="#FF00BFFF" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="# Lines of Code Covered" MetricUnit="Loc" Color="#FF32CD32" ChartType="Area" ScaleExp="0" />
      <Serie MetricName="# Lines of Code (NotMyCode)" MetricUnit="Loc" Color="#FFA9A9A9" ChartType="Area" ScaleExp="0" />
      <Serie MetricName="# Lines of Comments" MetricUnit="Lines" Color="#FF008000" ChartType="Line" ScaleExp="0" />
    </Chart>
    <Chart Name="Rules Violated" ShowInReport="True">
      <Serie MetricName="# Rules" MetricUnit="Rules" Color="#FF66CDAA" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="# Rules Violated" MetricUnit="Rules" Color="#FFFF8C00" ChartType="Area" ScaleExp="0" />
      <Serie MetricName="# Critical Rules Violated" MetricUnit="Rules" Color="#FFFF0000" ChartType="Area" ScaleExp="0" />
    </Chart>
    <Chart Name="Rules Violations" ShowInReport="True">
      <Serie MetricName="# Rules Violations" MetricUnit="Violations" Color="#FFFF8C00" ChartType="Area" ScaleExp="0" />
      <Serie MetricName="# Critical Rules Violations" MetricUnit="Violations" Color="#FFFF0000" ChartType="Area" ScaleExp="0" />
    </Chart>
    <Chart Name="Percentage Coverage by Tests" ShowInReport="True">
      <Serie MetricName="Percentage Code Coverage" MetricUnit="%" Color="#FF32CD32" ChartType="Area" ScaleExp="0" />
    </Chart>
    <Chart Name="Max" ShowInReport="True">
      <Serie MetricName="Max IL Cyclomatic Complexity for Methods" MetricUnit="Paths" Color="#FFFF0000" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="Max # Lines of Code for Methods (JustMyCode)" MetricUnit="LoC" Color="#FF0000FF" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="Max # of Methods for Types" MetricUnit="Methods" Color="#FF32CD32" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="Max IL Nesting Depth for Methods" MetricUnit="Scopes" Color="#FFFFD700" ChartType="Line" ScaleExp="0" />
    </Chart>
    <Chart Name="Average" ShowInReport="True">
      <Serie MetricName="Average IL Cyclomatic Complexity for Methods" MetricUnit="Paths" Color="#FFFF0000" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="Average # Lines of Code for Methods" MetricUnit="LoC" Color="#FF0000FF" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="Average # Methods for Types" MetricUnit="Methods" Color="#FF32CD32" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="Average IL Nesting Depth for Methods" MetricUnit="Scopes" Color="#FFFFD700" ChartType="Line" ScaleExp="0" />
    </Chart>
    <Chart Name="Third-Party Usage" ShowInReport="True">
      <Serie MetricName="# Third-Party Types Used" MetricUnit="Types" Color="#FF0000FF" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="# Third-Party Methods Used" MetricUnit="Methods" Color="#FFFF0000" ChartType="Line" ScaleExp="0" />
      <Serie MetricName="# Third-Party Assemblies Used" MetricUnit="Assemblies" Color="#FF646464" ChartType="Line" ScaleExp="1" />
      <Serie MetricName="# Third-Party Namespaces Used" MetricUnit="Namespaces" Color="#FF32CD32" ChartType="Line" ScaleExp="1" />
      <Serie MetricName="# Third-Party Fields Used" MetricUnit="Fields" Color="#FFFFD700" ChartType="Line" ScaleExp="1" />
    </Chart>
  </TrendMetrics>
  <HistoricAnalysisResult PersistRecurrence="2" UseCustomDir="False" CustomDir="" />
  <SourceFileRebasing FromPath="" ToPath="" />
  <PathVariables />
  <RuleFiles />
  <ProjectRules AreActive="True" />
  <Queries>
    <Group Name="Code Quality" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Types too big - critical</Name>
warnif count > 0 from t in JustMyCode.Types where 
   t.NbLinesOfCode > 500 
   // We've commented # IL Instructions, because with LINQ syntax, a few lines of code can compile to hundreds of IL instructions.
   // || t.NbILInstructions > 3000
   orderby t.NbLinesOfCode descending
select new { t, t.NbLinesOfCode, t.NbILInstructions,
                t.Methods, t.Fields }

//<Description>
// This rule matches types with more than 500 lines of code.
//
// Types where *NbLinesOfCode > 500* are extremely complex 
// to develop and maintain.
// See the definition of the NbLinesOfCode metric here 
// http://www.ndepend.com/docs/code-metrics#NbLinesOfCode
//
// Maybe you are facing the **God Class** phenomenon:
// A **God Class** is a class that controls way too many other classes 
// in the system and has grown beyond all logic to become 
// *The Class That Does Everything*.
//
// In average, a line of code is compiled to around
// 6 IL instructions. This is why the code metric
// *NbILInstructions* is used here, in case the 
// code metric *NbLinesOfCode* is un-available because
// of missing assemblies corresponding PDB files.
// See the definition of the *NbILInstructions* metric here 
// http://www.ndepend.com/docs/code-metrics#NbILInstructions
//</Description>

//<HowToFix>
// Types with many lines of code
// should be split in a group of smaller types.
// 
// To refactor a *God Class* you'll need patience, 
// and you might even need to recreate everything from scratch.
// Here are a few advices:
//
// • Think before pulling out methods: on what data does this method operate? 
// What responsibility does it have?
//
// • Try to maintain the interface of the god class at first 
// and delegate calls to the new extracted classes. 
// In the end the god class should be a pure facade without own logic.
// Then you can keep it for convenience 
// or throw it away and start to use the new classes only.
//
// • Unit Tests can help: write tests for each method before extracting it 
// to ensure you don't break functionality.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Methods too complex - critical</Name>
warnif count > 0 from m in JustMyCode.Methods where 
  m.CyclomaticComplexity > 30 ||
  m.ILCyclomaticComplexity > 60 ||
  m.ILNestingDepth > 6
  orderby m.CyclomaticComplexity descending,
          m.ILCyclomaticComplexity descending,
          m.ILNestingDepth descending
select new { m, m.CyclomaticComplexity, 
                m.ILCyclomaticComplexity,
                m.ILNestingDepth  }

//<Description>
// This rule matches methods where *CyclomaticComplexity* > 30 
// or *ILCyclomaticComplexity* > 60
// or *ILNestingDepth* > 6.
// Such method is typically hard to understand and maintain.
//
// Maybe you are facing the **God Method** phenomenon.
// A "God Method" is a method that does way too many processes in the system 
// and has grown beyond all logic to become *The Method That Does Everything*.
// When need for new processes increases suddenly some programmers realize: 
// why should I create a new method for each processe if I can only add an *if*.
//
// See the definition of the *CyclomaticComplexity* metric here:
// http://www.ndepend.com/docs/code-metrics#CC
//
// See the definition of the *ILCyclomaticComplexity* metric here:
// http://www.ndepend.com/docs/code-metrics#ILCC
//
// See the definition of the *ILNestingDepth* metric here:
// http://www.ndepend.com/docs/code-metrics#ILNestingDepth
//</Description>

//<HowToFix>
// A large and complex method should be split in smaller methods, 
// or even one or several classes can be created for that.
//
// During this process it is important to question the scope of each
// variable local to the method. This can be an indication if
// such local variable will become an instance field of the newly created class(es).
//
// Large *switch…case* structures might be refactored through the help
// of a set of types that implement a common interface, the interface polymorphism
// playing the role of the *switch cases tests*.
//
// Unit Tests can help: write tests for each method before extracting it 
// to ensure you don't break functionality.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Methods with too many parameters - critical</Name>
warnif count > 0 from m in JustMyCode.Methods where 
  m.NbParameters > 8
  orderby m.NbParameters descending
select new { m, m.NbParameters }

//<Description>
// This rule matches methods with more than 8 parameters.
// Such method is painful to call and might degrade performance.
// See the definition of the *NbParameters* metric here: 
// http://www.ndepend.com/docs/code-metrics#NbParameters
//</Description>

//<HowToFix>
// More properties/fields can be added to the declaring type to 
// handle numerous states. An alternative is to provide 
// a class or a structure dedicated to handle arguments passing.
// For example see the class *System.Diagnostics.ProcessStartInfo* 
// and the method *System.Diagnostics.Process.Start(ProcessStartInfo)*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Quick summary of methods to refactor</Name>
warnif count > 0 from m in JustMyCode.Methods where 
                                    // Code Metrics' definitions
  m.NbLinesOfCode > 30 ||           // http://www.ndepend.com/docs/code-metrics#NbLinesOfCode
  // We've commented # IL Instructions, because with LINQ syntax, a few lines of code can compile to hundreds of IL instructions.
  // m.NbILInstructions > 200 ||    // http://www.ndepend.com/docs/code-metrics#NbILInstructions
  m.CyclomaticComplexity > 20 ||    // http://www.ndepend.com/docs/code-metrics#CC
  m.ILCyclomaticComplexity > 50 ||  // http://www.ndepend.com/docs/code-metrics#ILCC
  m.ILNestingDepth > 5 ||           // http://www.ndepend.com/docs/code-metrics#ILNestingDepth
  m.NbParameters > 5 ||             // http://www.ndepend.com/docs/code-metrics#NbParameters
  m.NbVariables > 8 ||              // http://www.ndepend.com/docs/code-metrics#NbVariables
  m.NbOverloads > 6                 // http://www.ndepend.com/docs/code-metrics#NbOverloads

select new { m, m.NbLinesOfCode, m.NbILInstructions, m.CyclomaticComplexity, 
             m.ILCyclomaticComplexity, m.ILNestingDepth, 
             m.NbParameters, m.NbVariables, m.NbOverloads } 
             
//<Description>
// Methods matched by this rule somehow violate 
// one or several basic quality principles,
// whether it is too large (too many *lines of code*), 
// too complex (too many *if*, *switch case*, loops…)
// has too many variables, too many parameters
// or has too many overloads.
//</Description>

//<HowToFix>
// To refactor such method and increase code quality and maintainability,
// certainly you'll have to split the method into several smaller methods
// or even create one or several classes to implement the logic.
//
// During this process it is important to question the scope of each
// variable local to the method. This can be an indication if
// such local variable will become an instance field of the newly created class(es).
//
// Large *switch…case* structures might be refactored through the help
// of a set of types that implement a common interface, the interface polymorphism
// playing the role of the *switch cases tests*.
//
// Unit Tests can help: write tests for each method before extracting it 
// to ensure you don't break functionality.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods too big</Name>
warnif count > 0 from m in JustMyCode.Methods where 
   m.NbLinesOfCode > 30
   // We've commented # IL Instructions, because with LINQ syntax, a few lines of code can compile to hundreds of IL instructions.
   // || m.NbILInstructions > 200
   orderby m.NbLinesOfCode descending,
           m.NbILInstructions descending
select new { m, m.NbLinesOfCode, m.NbILInstructions }

//<Description>
// This rule matches methods where *NbLinesOfCode > 30* or 
// (commented per default) *NbILInstructions > 200*.
// Such method can be hard to understand and maintain.
//
// However rules like *Methods too complex* or *Methods with too many variables*
// might be more relevant to detect *painful to maintain* methods, 
// because complexity is more related to numbers of *if*, 
// *switch case*, loops… than to just number of lines. 
//
// See the definition of the *NbLinesOfCode* metric here 
// http://www.ndepend.com/docs/code-metrics#NbLinesOfCode
//</Description>

//<HowToFix>
// Usually too big methods should be split in smaller methods.
//
// But long methods with no branch conditions, that typically initialize some data,
// are not necessarily a problem to maintain nor to test, and might not need 
// refactoring.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods too complex</Name>
warnif count > 0 from m in JustMyCode.Methods where 
  m.CyclomaticComplexity > 20 ||
  m.ILCyclomaticComplexity > 40 ||
  m.ILNestingDepth > 4
  orderby m.CyclomaticComplexity descending,
          m.ILCyclomaticComplexity descending,
          m.ILNestingDepth descending
select new { m, m.CyclomaticComplexity, 
                m.ILCyclomaticComplexity,
                m.ILNestingDepth  }

//<Description>
// This rule matches methods where *CyclomaticComplexity > 20* 
// or *ILCyclomaticComplexity > 40*
// or *ILNestingDepth > 4*.
// Such method is typically hard to understand and maintain.
//
// See the definition of the *CyclomaticComplexity* metric here:
// http://www.ndepend.com/docs/code-metrics#CC
//
// See the definition of the *ILCyclomaticComplexity* metric here: 
// http://www.ndepend.com/docs/code-metrics#ILCC
//
// See the definition of the *ILNestingDepth* metric here: 
// http://www.ndepend.com/docs/code-metrics#ILNestingDepth
//</Description>

//<HowToFix>
// A large and complex method should be split in smaller methods, 
// or even one or several classes can be created for that.
//
// During this process it is important to question the scope of each
// variable local to the method. This can be an indication if
// such local variable will become an instance field of the newly created class(es).
//
// Large *switch…case* structures might be refactored through the help
// of a set of types that implement a common interface, the interface polymorphism
// playing the role of the *switch cases tests*.
//
// Unit Tests can help: write tests for each method before extracting it 
// to ensure you don't break functionality.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods potentially poorly commented</Name>
warnif count > 0 from m in JustMyCode.Methods where 
  m.PercentageComment < 20 && 
  m.NbLinesOfCode > 20  
  orderby m.PercentageComment ascending
select new { m, m.PercentageComment, m.NbLinesOfCode, m.NbLinesOfComment }

//<Description>
// This rule matches methods with less than 20% of comment lines and that have 
// at least 20 lines of code. Such method might need to be more commented.
//
// See the definitions of the *Comments metric* here:
// http://www.ndepend.com/docs/code-metrics#PercentageComment
// http://www.ndepend.com/docs/code-metrics#NbLinesOfComment
//</Description>

//<HowToFix>
// Typically add more comment. But code commenting is subject to controversy.
// While poorly written and designed code would needs a lot of comment 
// to be understood, clean code doesn't need that much comment, especially
// if variables and methods are properly named and convey enough information.
// Unit-Test code can also play the role of code commenting.
//
// However, even when writing clean and well-tested code, one will have
// to write **hacks** at a point, usually to circumvent some API limitations or bugs.
// A hack is a non-trivial piece of code, that doesn't make sense at first glance,
// and that took time and web research to be found.
// In such situation comments must absolutely be used to express the intention, 
// the need for the hacks and the source where the solution has been found.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods with too many parameters</Name>
warnif count > 0 from m in JustMyCode.Methods where 
  m.NbParameters > 5 
  orderby m.NbParameters descending
select new { m, m.NbParameters }

//<Description>
// This rule matches methods with more than 5 parameters.
// Such method might be painful to call and might degrade performance.
// See the definition of the *NbParameters* metric here: 
// http://www.ndepend.com/docs/code-metrics#NbParameters
//</Description>

//<HowToFix>
// More properties/fields can be added to the declaring type to 
// handle numerous states. An alternative is to provide 
// a class or a structure dedicated to handle arguments passing.
// For example see the class *System.Diagnostics.ProcessStartInfo* 
// and the method *System.Diagnostics.Process.Start(ProcessStartInfo))*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods with too many local variables</Name>
warnif count > 0 from m in JustMyCode.Methods where 
  m.NbVariables > 15 
  orderby m.NbVariables descending
select new { m, m.NbVariables }

//<Description>
// This rule matches methods with more than 15 variables.
//
// Methods where *NbVariables > 8* are hard to understand and maintain.
// Methods where *NbVariables > 15* are extremely complex and must be refactored. 
//
// See the definition of the *Nbvariables* metric here: 
// http://www.ndepend.com/docs/code-metrics#Nbvariables
//</Description>

//<HowToFix>
// To refactor such method and increase code quality and maintainability,
// certainly you'll have to split the method into several smaller methods
// or even create one or several classes to implement the logic.
//
// During this process it is important to question the scope of each
// variable local to the method. This can be an indication if
// such local variable will become an instance field of the newly created class(es).
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods with too many overloads</Name>
warnif count > 0 from m in JustMyCode.Methods where 
  m.NbOverloads > 6 && 
  !m.IsOperator // Don't report operator overload
  orderby m.NbOverloads descending
let overloads = 
 m.IsConstructor ? m.ParentType.Constructors :
                   m.ParentType.Methods.Where(m1 => m1.SimpleName == m.SimpleName)
select new { m, overloads }

//<Description>
// Method overloading is the ability to create multiple methods of the same name 
// with different implementations, and various set of parameters.
//
// This rule matches sets of method with more than 6 overloads.
//
// Such method set might be a problem to maintain 
// and provokes higher coupling than necessary.
//
// See the definition of the *NbOverloads* metric here 
// http://www.ndepend.com/docs/code-metrics#NbOverloads
//</Description>

//<HowToFix>
// Typically the *too many overloads* phenomenon appears when an algorithm
// takes a various set of in-parameters. Each overload is presented as 
// a facility to provide a various set of in-parameters.
// In such situation, the C# and VB.NET language feature named 
// *Named and Optional arguments* should be used.
//
// The *too many overloads* phenomenon can also be a consequence of the usage
// of the **visitor design pattern** http://en.wikipedia.org/wiki/Visitor_pattern 
// since a method named *Visit()* must be provided for each sub type.
// In such situation there is no need for fix.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types with too many methods</Name>
warnif count > 0 from t in JustMyCode.Types 

  // Optimization: Fast discard of non-relevant types 
  where t.Methods.Count() > 20

  // Don't match these methods
  let methods = t.Methods.Where(
       m => !(m.IsGeneratedByCompiler ||
              m.IsConstructor || m.IsClassConstructor ||
              m.IsPropertyGetter || m.IsPropertySetter ||
              m.IsEventAdder || m.IsEventRemover))

  where methods.Count() > 20 
  orderby methods.Count() descending
select new { t, 
             nbMethods = methods.Count(),
             instanceMethods = methods.Where(m => !m.IsStatic), 
             staticMethods = methods.Where(m => m.IsStatic)}

//<Description>
// This rule matches types with more than 20 methods. 
// Such type might be hard to understand and maintain.
//
// Notice that methods like constructors or property 
// and event accessors are not taken account.
//
// Having many methods for a type might be a symptom
// of too many responsibilities implemented.
//
// Maybe you are facing the **God Class** phenomenon:
// A **God Class** is a class that controls way too many other classes 
// in the system and has grown beyond all logic to become 
// *The Class That Does Everything*.
//</Description>

//<HowToFix>
// To refactor such type and increase code quality and maintainability,
// certainly you'll have to split the type into several smaller types
// that together, implement the same logic.
//
// To refactor a *God Class* you'll need patience, 
// and you might even need to recreate everything from scratch.
// Here are a few advices:
//
// • Think before pulling out methods:
// What responsibility does it have?
// Can you isolate some subsets of methods that operate on the same subsets of fields?
//
// • Try to maintain the interface of the god class at first 
// and delegate calls to the new extracted classes. 
// In the end the god class should be a pure facade without own logic.
// Then you can keep it for convenience 
// or throw it away and start to use the new classes only.
//
// • Unit Tests can help: write tests for each method before extracting it 
// to ensure you don't break functionality.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types with too many fields</Name>
warnif count > 0 from t in JustMyCode.Types 

  // Optimization: Fast discard of non-relevant types 
  where !t.IsEnumeration &&
         t.Fields.Count() > 20
        
  // Count instance fields and non-constant static fields
  let fields = t.Fields.Where(f =>
          !f.IsGeneratedByCompiler &&
          !f.IsLiteral &&
          !(f.IsStatic && f.IsInitOnly) &&
           JustMyCode.Contains(f) )

  where fields.Count() > 20 
 
  orderby fields.Count() descending
select new { t, 
   instanceFields = fields.Where(f => !f.IsStatic),
   staticFields = fields.Where(f => f.IsStatic),
   
   // See definition of Size of Instances metric here:
   // http://www.ndepend.com/docs/code-metrics#SizeOfInst
   t.SizeOfInst 
}

//<Description>
// This rule matches types with more than 20 fields. 
// Such type might be hard to understand and maintain.
//
// Notice that constant fields and static-readonly fields are not counted.
// Enumerations types are not counted also.
//
// Having many fields for a type might be a symptom
// of too many responsibilities implemented.
//</Description>

//<HowToFix>
// To refactor such type and increase code quality and maintainability,
// certainly you'll have to group subsets of fields into smaller types
// and dispatch the logic implemented into the methods 
// into these smaller types.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types with poor cohesion</Name>
warnif count > 0 from t in JustMyCode.Types where 
  (t.LCOM > 0.8 || t.LCOMHS > 0.95) && 
  t.NbFields > 10 && 
  t.NbMethods >10 
  orderby t.LCOM descending, t.LCOMHS descending
select new { t, t.LCOM, t.LCOMHS, 
                t.NbMethods, t.NbFields }

//<Description>
// This rule is based on the *LCOM code metric*,
// LCOM stands for **Lack Of Cohesion of Methods**.
// See the definition of the LCOM metric here 
// http://www.ndepend.com/docs/code-metrics#LCOM
//
// The LCOM metric measures the fact that most methods are using most fields.
// A class is considered utterly cohesive (which is good)
// if all its methods use all its instance fields.
//
// Only types with enough methods and fields are taken account to avoid bias.
// The LCOM takes its values in the range [0-1].
//
// This rule matches types with LCOM higher than 0.8.
// Such value generally pinpoints a **poorly cohesive class**.
//
// There are several LCOM metrics. 
// The LCOM HS (HS stands for Henderson-Sellers) takes its values in the range [0-2]. 
// A LCOM HS value higher than 1 should be considered alarming.
//</Description>

//<HowToFix>
// To refactor a poorly cohesive type and increase code quality and maintainability,
// certainly you'll have to split the type into several smaller and more cohesive types
// that together, implement the same logic.
//</HowToFix>]]></Query>
    </Group>
    <Group Name="Code Quality Regression" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>From now, all methods added or refactored should respect basic quality principles</Name>
warnif count > 0 from m in JustMyCode.Methods where

// *** Only match new or refactored methods since Baseline for Comparison ***
 (m.WasAdded() || m.CodeWasChanged()) &&
 
// Low Quality methods// Metrics' definitions
(  m.NbLinesOfCode > 30 ||          // http://www.ndepend.com/docs/code-metrics#NbLinesOfCode
   m.NbILInstructions > 200 ||      // http://www.ndepend.com/docs/code-metrics#NbILInstructions
   m.CyclomaticComplexity > 20 ||   // http://www.ndepend.com/docs/code-metrics#CC
   m.ILCyclomaticComplexity > 50 || // http://www.ndepend.com/docs/code-metrics#ILCC
   m.ILNestingDepth > 4 ||          // http://www.ndepend.com/docs/code-metrics#ILNestingDepth
   m.NbParameters > 5 ||            // http://www.ndepend.com/docs/code-metrics#NbParameters
   m.NbVariables > 8 ||             // http://www.ndepend.com/docs/code-metrics#NbVariables
   m.NbOverloads > 6 )
select new { m, m.NbLinesOfCode, m.NbILInstructions, m.CyclomaticComplexity, 
             m.ILCyclomaticComplexity, m.ILNestingDepth, 
             m.NbParameters, m.NbVariables, m.NbOverloads }  // http://www.ndepend.com/docs/code-metrics#NbOverloads

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
// This rule operates only on methods added or refactored since the baseline.
// The same effect can be obtained for any rules through:
// *Dashboard > Filter Recent Violations Only*.
// Doing so let's focus on code quality on recent changes only.
//
// Methods matched by this rule not only have been recently added or refactored,
// but also somehow violate one or several basic quality principles,
// whether it is too large (too many *lines of code*), 
// too complex (too many *if*, *switch case*, loops…)
// has too many variables, too many parameters
// or has too many overloads.
//</Description>

//<HowToFix>
// To refactor such method and increase code quality and maintainability,
// certainly you'll have to split the method into several smaller methods
// or even create one or several classes to implement the logic.
//
// During this process it is important to question the scope of each
// variable local to the method. This can be an indication if
// such local variable will become an instance field of the newly created class(es).
//
// Large *switch…case* structures might be refactored through the help
// of a set of types that implement a common interface, the interface polymorphism
// playing the role of the *switch cases tests*.
//
// Unit Tests can help: write tests for each method before extracting it 
// to ensure you don't break functionality.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>From now, all types added or refactored should respect basic quality principles</Name>
warnif count > 0 from t in JustMyCode.Types where

// *** Only match new or refactored types since Baseline for Comparison ***
(t.WasAdded() || t.CodeWasChanged()) &&

// Eliminate interfaces, enumerations or types only with constant fields
// by making sure we are matching type with code.
t.NbLinesOfCode > 10 &&

// Optimization: Fast discard of non-relevant types 
(t.Fields.Count() > 20 || t.Methods.Count() > 20)
      
// Count instance fields and non-constant static fields
let fields = t.Fields.Where(f => 
      !f.IsLiteral &&
      !(f.IsStatic && f.IsInitOnly))

// Don't match these methods
let methods = t.Methods.Where(
   m => !(m.IsConstructor || m.IsClassConstructor ||
          m.IsGeneratedByCompiler ||
          m.IsPropertyGetter || m.IsPropertySetter ||
          m.IsEventAdder || m.IsEventRemover))
  
where 

// Low Quality types     Metrics' definitions are available here:
//     http://www.ndepend.com/docs/code-metrics#MetricsOnTypes
(  // Types with too many methods
   fields.Count() > 20 ||

   methods.Count() > 20 ||
               
   // Complex Types that use more than 50 other types
   t.NbTypesUsed > 50
)
select new { t, t.NbLinesOfCode, 

  instanceMethods = methods.Where(m => !m.IsStatic), 
  staticMethods = methods.Where(m => m.IsStatic),
  
  instanceFields = fields.Where(f => !f.IsStatic),
  staticFields = fields.Where(f => f.IsStatic),
  
  t.TypesUsed }

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
// This rule operates only on types added or refactored since the baseline.
// The same effect can be obtained for any rules through:
// *Dashboard > Filter Recent Violations Only*.
// Doing so let's focus on code quality on recent changes only.
//
// Types matched by this rule not only have been recently added or refactored,
// but also somehow violate one or several basic quality principles,
// whether it has too many methods,
// it has too many fields,
// or is using too many types.
// Any of these criterions is often a symptom of a type with too many responsibilities.
//
// Notice that to count methods and fields, methods like constructors 
// or property and event accessors are not taken account.
// Notice that constants fields and static-readonly fields are not counted.
// Enumerations types are not counted also.
//</Description>

//<HowToFix>
// To refactor such type and increase code quality and maintainability,
// certainly you'll have to split the type into several smaller types
// that together, implement the same logic.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>From now, all types added or refactored should be 100% covered by tests</Name>
warnif count > 0 from t in JustMyCode.Types where

  // *** Only match new or refactored types since Baseline for Comparison ***
  (t.WasAdded() || t.CodeWasChanged()) &&

  // …that are not 100% covered by tests
  t.PercentageCoverage < 100

  let methodsCulprit = t.Methods.Where(m => m.PercentageCoverage < 100)

select new { t, t.PercentageCoverage, methodsCulprit }

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
// This rule operates only on types added or refactored since the baseline.
// The same effect can be obtained for any rules through:
// *Dashboard > Filter Recent Violations Only*.
// Doing so let's focus on code quality on recent changes only.
//
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// Often covering 10% of remaining uncovered code of a class, 
// requires as much work as covering the first 90%.
// For this reason, typically teams estimate that 90% coverage is enough.
// However *untestable code* usually means *poorly written code* 
// which usually leads to *error prone code*.
// So it might be worth refactoring and making sure to cover the 10% remaining code
// because **most tricky bugs might come from this small portion of hard-to-test code**.
//
// Not all classes should be 100% covered by tests (like UI code can be hard to test)
// but you should make sure that most of the logic of your application
// is defined in some *easy-to-test classes*, 100% covered by tests.
//
// In this context, this rule warns when a type added or refactored since the baseline,
// is not fully covered by tests.
//</Description>

//<HowToFix>
// Write more unit-tests dedicated to cover code not covered yet.
// If you find some *hard-to-test code*, it is certainly a sign that this code
// is not *well designed* and hence, needs refactoring.
//
// You'll find code impossible to cover by unit-tests, like calls to *MessageBox.Show()*.
// An infrastructure must be defined to be able to *mock* such code at test-time.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid decreasing code coverage by tests of types</Name>

warnif count > 0 
from t in JustMyCode.Types where
  t.IsPresentInBothBuilds() &&
  t.PercentageCoverage < t.OlderVersion().PercentageCoverage

select new { t,
    OldCov = t.OlderVersion().PercentageCoverage,
    NewCov = t.PercentageCoverage,
    OldLoc = t.OlderVersion().NbLinesOfCode,
    NewLoc = t.NbLinesOfCode,
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// This rule warns when a type code coverage ratio 
// decreased since the baseline. 
// This can mean that some tests have been removed
// but more often, this means that the type has been modified,
// and that changes haven't been covered by tests.
//
// To visualize changes in code, right-click a matched type and select:
//
// • Compare older and newer versions of source file
//
// • or Compare older and newer versions disassembled with Reflector
//</Description>

//<HowToFix>
// Write more unit-tests dedicated to cover changes in matched types
// not covered yet.
// If you find some *hard-to-test code*, it is certainly a sign that this code
// is not *well designed* and hence, needs refactoring.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types that used to be 100% covered but not anymore</Name>
        
warnif count > 0
from t in JustMyCode.Types where 
   t.IsPresentInBothBuilds() &&
   t.OlderVersion().PercentageCoverage == 100 &&
   t.PercentageCoverage < 100
let culpritMethods = t.Methods.Where(m => m.PercentageCoverage < 100)
select new {t, t.PercentageCoverage, culpritMethods }

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// Often covering 10% of remaining uncovered code of a class, 
// requires as much work as covering the first 90%.
// For this reason, typically teams estimate that 90% coverage is enough.
// However *untestable code* usually means *poorly written code* 
// which usually leads to *error prone code*.
// So it might be worth refactoring and making sure to cover the 10% remaining code
// **because most tricky bugs might come from this small portion of hard-to-test code**.
//
// Not all classes should be 100% covered by tests (like UI code can be hard to test)
// but you should make sure that most of the logic of your application
// is defined in some *easy-to-test classes*, 100% covered by tests.
//
// In this context, this rule warns when a type fully covered by tests is now only partially covered.
//</Description>

//<HowToFix>
// Write more unit-tests dedicated to cover code not covered anymore.
// If you find some *hard-to-test code*, it is certainly a sign that this code
// is not *well designed* and hence, needs refactoring.
//
// You'll find code impossible to cover by unit-tests, like calls to *MessageBox.Show()*.
// An infrastructure must be defined to be able to *mock* such code at test-time.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid making complex methods even more complex (Source CC)</Name>

warnif count > 0 
from m in JustMyCode.Methods where
 !m.IsAbstract &&
  m.IsPresentInBothBuilds() &&
  m.CodeWasChanged()

let oldCC = m.OlderVersion().CyclomaticComplexity
where oldCC > 6 && m.CyclomaticComplexity > oldCC 

select new { m,
    oldCC ,
    newCC = m.CyclomaticComplexity ,
    oldLoc = m.OlderVersion().NbLinesOfCode,
    newLoc = m.NbLinesOfCode,
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// The method complexity is measured through the code metric
// *Cyclomatic Complexity* defined here:
// http://www.ndepend.com/docs/code-metrics#CC
//
// This rule warns when a method already complex
// (i.e with *Cyclomatic Complexity* higher than 6)
// become even more complex since the baseline.
//
// This rule needs assemblies PDB files and source code 
// to be available at analysis time, because the *Cyclomatic Complexity*
// is inferred from the source code and source code location
// is inferred from PDB files. See:
// http://www.ndepend.com/docs/ndepend-analysis-inputs-explanation
//
// To visualize changes in code, right-click a matched method and select:
//
// • Compare older and newer versions of source file
//
// • or Compare older and newer versions disassembled with Reflector
//</Description>

//<HowToFix>
// A large and complex method should be split in smaller methods, 
// or even one or several classes can be created for that.
//
// During this process it is important to question the scope of each
// variable local to the method. This can be an indication if
// such local variable will become an instance field of the newly created class(es).
//
// Large *switch…case* structures might be refactored through the help
// of a set of types that implement a common interface, the interface polymorphism
// playing the role of the *switch cases tests*.
//
// Unit Tests can help: write tests for each method before extracting it 
// to ensure you don't break functionality.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid making complex methods even more complex (IL CC)</Name>

warnif count > 0 
from m in JustMyCode.Methods where
 !m.IsAbstract &&
  m.IsPresentInBothBuilds() &&
  m.CodeWasChanged()

let oldCC = m.OlderVersion().ILCyclomaticComplexity
where oldCC > 10 && m.ILCyclomaticComplexity > oldCC 

select new { m,
    oldCC ,
    newCC = m.ILCyclomaticComplexity ,
    oldLoc = m.OlderVersion().NbLinesOfCode,
    newLoc = m.NbLinesOfCode,
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// The method complexity is measured through the code metric
// *IL Cyclomatic Complexity* defined here:
// http://www.ndepend.com/docs/code-metrics#ILCC
//
// This rule warns when a method already complex
// (i.e with *IL Cyclomatic Complexity* higher than 10)
// become even more complex since the baseline.
//
// If assemblies PDB files and source code 
// are available at analysis time,
// the *Cyclomatic Complexity* can be inferred from source code,
// and this is more precise than inferring it from IL code.
// Hence, prefer use the rule
// *Avoid making complex methods even more complex (Source CC)*
// that offers more precise result.
//
// To visualize changes in code, right-click a matched method and select:
//
// • Compare older and newer versions of source file
//
// • or Compare older and newer versions disassembled with Reflector
//</Description>

//<HowToFix>
// A large and complex method should be split in smaller methods, 
// or even one or several classes can be created for that.
//
// During this process it is important to question the scope of each
// variable local to the method. This can be an indication if
// such local variable will become an instance field of the newly created class(es).
//
// Large *switch…case* structures might be refactored through the help
// of a set of types that implement a common interface, the interface polymorphism
// playing the role of the *switch cases tests*.
//
// Unit Tests can help: write tests for each method before extracting it 
// to ensure you don't break functionality.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid making large methods even larger</Name>

warnif count > 0 
from m in JustMyCode.Methods where
 !m.IsAbstract &&
  m.IsPresentInBothBuilds() &&
  m.CodeWasChanged() &&
 // Eliminate constructors from match, since they get larger
 // as soons as some fields initialization are added.
 !m.IsConstructor &&
 !m.IsClassConstructor

let oldLoc = m.OlderVersion().NbLinesOfCode
where oldLoc > 15 && m.NbLinesOfCode > oldLoc

select new { m,
    oldLoc,
    newLoc = m.NbLinesOfCode,
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule warns when a method already large
// (i.e with more than 15 lines of code)
// become even larger since the baseline.
//
// The method size is measured through the code metric
// *# Lines of Code* defined here:
// http://www.ndepend.com/docs/code-metrics#NbLinesOfCode
//
// This rule needs assemblies PDB files 
// to be available at analysis time, because the *# Lines of Code*
// is inferred from PDB files. See:
// http://www.ndepend.com/docs/ndepend-analysis-inputs-explanation
//
// To visualize changes in code, right-click a matched method and select:
//
// • Compare older and newer versions of source file
//
// • or Compare older and newer versions disassembled with Reflector
//</Description>

//<HowToFix>
// Usually too big methods should be split in smaller methods.
//
// But long methods with no branch conditions, that typically initialize some data,
// are not necessarily a problem to maintain, and might not need refactoring.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid adding methods to a type that already had many methods</Name>

warnif count > 0 

// Don't count constructors and methods generated by the compiler!
let getMethodsProc = new Func<IType, IList<IMethod>>(
   t => t.Methods.Where(m =>
      !m.IsConstructor && !m.IsClassConstructor && 
      !m.IsGeneratedByCompiler).ToArray()) 


from t in JustMyCode.Types where
  
  t.IsPresentInBothBuilds()

  // Optimization: fast discard of non-relevant types
  where t.OlderVersion().NbMethods > 15

  let oldMethods = getMethodsProc(t.OlderVersion())
  where oldMethods.Count > 15

  let newMethods = getMethodsProc(t)
  where newMethods.Count > oldMethods.Count

  let addedMethods = newMethods.Where(m => m.WasAdded())
  let removedMethods = oldMethods.Where(m => m.WasRemoved())

select new { 
    t,
    nbOldMethods = oldMethods.Count,
    nbNewMethods = newMethods.Count,
    addedMethods ,
    removedMethods
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// Types where number of methods is greater than 15 
// might be hard to understand and maintain.
//
// This rule lists types that already had more than 15 methods
// at the baseline time, and for which new methods have been added.
//
// Having many methods for a type might be a symptom
// of too many responsibilities implemented.
//
// Notice that constructors and methods generated by the compiler 
// are not taken account.
//</Description>

//<HowToFix>
// To refactor such type and increase code quality and maintainability,
// certainly you'll have to split the type into several smaller types
// that together, implement the same logic.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[//<Name>Avoid transforming an immutable type into a mutable one</Name>

warnif count > 0
from t in Application.Types where
   t.IsPresentInBothBuilds() &&
   t.OlderVersion().IsImmutable &&
  !t.IsImmutable && 
  // Don't take account of immutable types transformed into static types (not deemed as immtable)
  !t.IsStatic
let culpritFields = t.Fields.Where(f => f.IsImmutable)
select new {
  t, 
  culpritFields
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// A type is considered as *immutable* if its instance fields
// cannot be modified once an instance has been built by a constructor.
//
// Being immutable has several fortunate consequences for a type.
// For example its instance objects can be used concurrently 
// from several threads without the need to synchronize accesses.
//
// Hence users of such type often rely on the fact that the type is immutable.
// If an immutable type becomes mutable, there are chances that this will break 
// users code.
// This is why this rule warns about such immutable type that become mutable.
//</Description>

//<HowToFix>
// If being immutable is an important property for a matched type,
// then the code must be refactored to preserve immutability.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid adding instance fields to a type that already had many instance fields</Name>

warnif count > 0 

// Count instance fields and non-readonly static fields
let getFieldsProc = new Func<IType, IList<IField>>(
   t => t.Fields.Where(f => 
          !f.IsLiteral &&
          !f.IsGeneratedByCompiler &&
          !(f.IsStatic && f.IsInitOnly)).ToArray()) 


from t in JustMyCode.Types where
  
 !t.IsEnumeration &&
  t.IsPresentInBothBuilds()

  // Optimization: fast discard of non-relevant types
  where t.OlderVersion().NbFields > 15

  let oldFields = getFieldsProc(t.OlderVersion())
  where oldFields.Count > 15

  let newFields = getFieldsProc(t)
  where newFields.Count > oldFields.Count

  let addedFields = newFields.Where(f => f.WasAdded())
  let removedFields = oldFields.Where(f => f.WasRemoved())

select new { 
    t,
    nbOldFields = oldFields.Count,
    nbNewFields = newFields.Count,
    addedFields ,
    removedFields
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// Types where number of fields is greater than 15 
// might be hard to understand and maintain.
//
// This rule lists types that already had more than 15 fields
// at the baseline time, and for which new fields have been added.
//
// Having many fields for a type might be a symptom
// of too many responsibilities implemented.
//
// Notice that *constants* fields and *static-readonly* fields are not taken account.
// Enumerations types are not taken account also.
//</Description>

//<HowToFix>
// To refactor such type and increase code quality and maintainability,
// certainly you'll have to group subsets of fields into smaller types
// and dispatch the logic implemented into the methods 
// into these smaller types.
//</HowToFix>]]></Query>
    </Group>
    <Group Name="Object Oriented Design" Active="True" ShownInReport="True">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Base class should not use derivatives</Name>
        
warnif count > 0 
from baseClass in JustMyCode.Types
where baseClass.IsClass && baseClass.NbChildren > 0 // <-- for optimization!
let derivedClassesUsed = baseClass.DerivedTypes.UsedBy(baseClass)
where derivedClassesUsed.Count() > 0
select new { baseClass, derivedClassesUsed }

//<Description>
// In *Object-Oriented Programming*, the **open/closed principle** states:
// *software entities (components, classes, methods, etc.) should be open 
// for extension, but closed for modification*. 
// http://en.wikipedia.org/wiki/Open/closed_principle
//
// Hence a base class should be designed properly to make it easy to derive from,
// this is *extension*. But creating a new derived class, or modifying an
// existing one, shouldn't provoke any *modification* in the base class.
// And if a base class is using some derivative classes somehow, there
// are good chances that such *modification* will be needed.
//
// Extending the base class is not anymore a simple operation,
// this is not good design.
//</Description>

//<HowToFix>
// Understand the need for using derivatives, 
// then imagine a new design, and then refactor.
//
// Typically an algorithm in the base class needs to access something 
// from derived classes. You can try to encapsulate this access behind 
// an abstract or a virtual method.
//
// If you see in the base class some conditions on *typeof(DerivedClass)*
// not only *urgent refactoring* is needed. Such condition can easily 
// be replaced through an abstract or a virtual method.
//
// Sometime you'll see a base class that creates instance of some derived classes.
// In such situation, certainly using the *factory method pattern* 
// http://en.wikipedia.org/wiki/Factory_method_pattern
// or the *abstract factory pattern* 
// http://en.wikipedia.org/wiki/Abstract_factory_pattern
// will improve the design. 
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Class shouldn't be too deep in inheritance tree</Name>
        
warnif count > 0 from t in JustMyCode.Types 
where t.IsClass
let baseClasses = t.BaseClasses.ExceptThirdParty()

where baseClasses.Count() >= 3

select new { t, baseClasses, 
                // The metric value DepthOfInheritance takes account
                // of third-party base classessee its definition here:
                // http://www.ndepend.com/docs/code-metrics#DIT
                t.DepthOfInheritance } 

//<Description>
// This rule warns about classes having 3 or more base classes.
// Notice that third-party base classes are not counted
// because this rule is about your code design, not 
// third-party libraries consumed design.
//
// *In theory*, there is nothing wrong having a *long inheritance chain*,
// if the modelization has been well thought out,
// if each base class is a well-designed refinement of the domain.
//
// *In practice*, modeling properly a domain demands a lot of effort
// and experience and more often than not, a *long inheritance chain*
// is a sign of confused design, that will be hard to work with and maintain.
//</Description>

//<HowToFix>
// In *Object-Oriented Programming*, a well-known motto is
// **Favor Composition over Inheritance**.
//
// This is because *inheritance* comes with pitfalls.
// In general, the implementation of a derived class is very bound up with 
// the base class implementation. Also a base class exposes implementation
// details to its derived classes, that's why it's often said that 
// inheritance breaks encapsulation. 
//
// On the other hands, *Composition* favors binding with interfaces
// over binding with implementations. Hence, not only the encapsulation
// is preserved, but the design is clearer, because interfaces make it explicit
// and less coupled.
//
// Hence, to break a *long inheritance chain*, *Composition* is often
// a powerful way to enhance the design of the refactored underlying logic.
//
// You can also read: 
// http://en.wikipedia.org/wiki/Composition_over_inheritance and
// http://stackoverflow.com/questions/49002/prefer-composition-over-inheritance
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Class with no descendant should be sealed if possible</Name>
warnif count > 0 from t in JustMyCode.Types where 
  t.IsClass && 
  t.NbChildren ==0 && 
 !t.IsSealed && 
 !t.IsStatic 
// && !t.IsPublic //<-- You might want to add this condition 
                  // if you are developing a framework
                  // with classes that are intended to be 
                  // sub-classed by your clients.
  orderby t.NbLinesOfCode descending
select new { t, t.NbLinesOfCode }


//<Description>
// If a *non-static* class isn't declared with the keyword *sealed*,
// it means that it can be subclassed everywhere the *non-sealed* 
// class is visible.
//
// Making a class a *base class* requires significant design effort.
// Subclassing a *non-sealed* class, not initially designed 
// to be subclassed, will lead to unanticipated design issue.
//
// Most classes are *non-sealed* because developers don't care about 
// the keyword *sealed*, not because the primary intention was to write 
// a class that can be subclassed.
//
// There are minor performance gain in declaring a class as *sealed*.
// But the real benefit of doing so, is actually to **express the 
// intention**: *this class has not be designed to be a base class, 
// hence it is not allowed to subclass it*.
//
// Notice that by default this rule matches also *public* class.
// If you are developing a framework with classes that are intended 
// to be subclassed by your clients, just uncomment the line
// *&& !t.IsPublic*.
//</Description>

//<HowToFix>
// For each matched class, take the time to assess if it is really
// meant to be subclassed. Certainly most matched class will end up
// being declared as *sealed*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Overrides of Method() should call base.Method()</Name>
warnif count > 0
from t in Types  // Take account of third-party base classes also

// Bother only classes with descendant
where t.IsClass && t.NbChildren > 0

from mBase in t.InstanceMethods
where  mBase.IsVirtual &&
      !mBase.IsThirdParty &&
      !mBase.IsAbstract && 
      !mBase.IsExplicitInterfaceImpl
from mOverride in mBase.OverridesDirectDerived
where !mOverride.IsUsing(mBase)
select new { mOverride, shouldCall = mBase, definedInBaseClass = mBase.ParentType }

//<Description>
// Typically overrides of a base method, should **refine** or **complete** 
// the behavior of the base method. If the base method is not called, 
// the base behavior is not refined but it is *replaced*. 
//
// Violations of this rule are a sign of *design flaw*,
// especially if the actual design provides valid reasons 
// that advocates that the base behavior must be replaced and not refined.
//</Description>

//<HowToFix>
// You should investigate if *inheritance* is the right choice
// to bind the base class implementation with the derived classes
// implementations. Does presenting the method with polymorphic 
// behavior through an interface, would be a better design choice?
//
// In such situation, often using the design pattern **template method**
// http://en.wikipedia.org/wiki/Template_method_pattern might help
// improving the design.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Do not hide base class methods</Name>
warnif count > 0

// Define a lookup table indexing methods by their name including parameters signature.
let lookup = Methods.Where(m => !m.IsConstructor && !m.IsStatic && !m.IsGeneratedByCompiler)
                    .ToLookup(m1 => m1.Name)

from t in Application.Types
where !t.IsStatic && t.IsClass &&
   // Discard classes deriving directly from System.Object
   t.DepthOfInheritance > 1 
where t.BaseClasses.Any()

// For each methods not overriding any methods (new slot), 
// let's check if it hides by name some methods defined in base classes.
from m in t.InstanceMethods
where m.IsNewSlot && !m.IsExplicitInterfaceImpl && !m.IsGeneratedByCompiler

// Notice how lookup is used to quickly retrieve methods with same name as m.
// This makes the query 10 times faster than iterating each base methods to check their name.
let baseMethodsHidden = lookup[m.Name].Where(m1 => m1 != m && t.DeriveFrom(m1.ParentType))

where baseMethodsHidden.Count() > 0
select new { m, baseMethodsHidden }

//<Description>
// Method hiding is when a base class has a non-virtual method *M()*,
// and a derived class has also a method *M()* with the same signature.
// In such situation, calling *base.M()* does something different
// than calling *derived.M()*.
//
// Notice that this is not *polymorphic* behavior. With *polymorphic* 
// behavior, calling both *base.M()* and *derived.M()* on an instance 
// object of *derived*, invoke the same implementation.
//
// This situation should be avoided because it obviously leads to confusion.
// This rule warns about all method hiding cases in the code base.
//</Description>

//<HowToFix>
// To fix a violation of this rule, remove or rename the method, 
// or change the parameter signature so that the method does 
// not hide the base method.
//
// However *method hiding is for those times when you need to have two 
// things to have the same name but different behavior*. This is a very
// rare situations, described here:
// http://blogs.msdn.com/b/ericlippert/archive/2008/05/21/method-hiding-apologia.aspx
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>A stateless class or structure might be turned into a static type</Name>

warnif count > 0 from t in JustMyCode.Types where
  !t.IsStatic &&                  
  !t.IsGeneric &&
   t.InstanceFields.Count() == 0 &&

   // Don't match:
   // --> types that implement some interfaces.
   t.NbInterfacesImplemented == 0 &&

   // --> or classes that have sub-classes children.                            
   t.NbChildren == 0 &&

   // --> or classes that have a base class
   ((t.IsClass && t.DepthOfDeriveFrom("System.Object".AllowNoMatch()) == 1) ||
     t.IsStructure) 
   
select t

//<Description>
// This rule matches classes and structures that are not static, nor generic,
// that doesn't have any instance fields, that doesn't implement any interface
// nor has a base class (different than *System.Object*).
//
// Such class or structure is a *stateless* collection of *pure* functions, 
// that doesn't act on any *this* object data. Such collection of *pure* functions  
// is better hosted in a **static class**. Doing so simplifies the client code  
// that doesn't have to create an object anymore to invoke the *pure* functions.
//</Description>

//<HowToFix>
// Declare all methods as *static* and transform the class or structure
// into a *static* class.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Non-static classes should be instantiated or turned to static</Name>
warnif count > 0
from t in JustMyCode.Types
where  t.IsClass &&
    //!t.IsPublic &&   // if you are developing a framework, 
                       // you might not want to match public classes
      !t.IsStatic && 
      !t.IsAttributeClass && // Attributes class are never seen as instantiated

       // Don't suggest to turn to static, classes that implement interfaces
       t.InterfacesImplemented.Count() == 0 &&

      !t.DeriveFrom("System.MarshalByRefObject".AllowNoMatch()) && // Types instantiated through remoting infrastructure
        
      // XML serialized type might never be seen as instantiated.
      !t.HasAttribute("System.Xml.Serialization.XmlRootAttribute".AllowNoMatch()) &&
      !t.IsUsing("System.Xml.Serialization.XmlElementAttribute".AllowNoMatch()) &&
      !t.IsUsing("System.Xml.Serialization.XmlAttributeAttribute".AllowNoMatch())
 
// find the first constructor of t called
let ctorCalled = t.Constructors.FirstOrDefault(ctor => ctor.NbMethodsCallingMe > 0)

// match t if none of its constructors is called.
where ctorCalled == null
select new { t, t.Visibility }

// Notice that classes only instantiated through reflection, like plug-in root classes
// are matched by this rules.

//<Description>
// If the constructors of a class are never called, the class is
// never instantiated, and should be defined as a *static class*.
//
// However this rule doesn't match instantiation through reflection.
// As a consequence, plug-in root classes, instantiated through reflection
// via *IoC frameworks*, can be *false positives* for this rule.
//
// Notice that by default this rule matches also *public* class.
// If you are developing a framework with classes that are intended 
// to be instantiated by your clients, just uncomment the line
// *!t.IsPublic*.
//</Description>

//<HowToFix>
// First it is important to investigate why the class is never instantiated.
// If the reason is *the class hosts only static methods* then the class
// can be safely declared as *static*.
//
// Others reasons like, *the class is meant to be instantiated via reflection*,
// or *is meant to be instantiated only by client code* should lead to
// adapt this rule code to avoid these matches.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods should be declared static if possible</Name>
warnif count > 0

from t in JustMyCode.Types.Where(t =>
   !t.IsStatic && !t.IsInterface &&
   !t.IsEnumeration && !t.IsDelegate &&
   !t.IsGeneratedByCompiler)

let methodsThatCanBeMadeStatic = 
   from m in t.InstanceMethods

   // An instance method can be turned to static if it is not virtual, 
   // not using the this reference and also, not using
   // any of its class or base classes instance fields or instance methods.
   where !m.IsAbstract && !m.IsVirtual &&
         !m.AccessThis && !m.IsExplicitInterfaceImpl &&

          // Optimization: Using FirstOrDefault() avoid to check all members, 
          //               as soon as one member is found
          //               we know the method m cannot be made static.
          m.MembersUsed.FirstOrDefault(
              mUsed => !mUsed.IsStatic && 
                       (mUsed.ParentType == t || 
                        t.DeriveFrom(mUsed.ParentType))
          ) == null 
   select m

from m in methodsThatCanBeMadeStatic
let staticFieldsUsed = m.ParentType.StaticFields.UsedBy(m).Where(f => !f.IsGeneratedByCompiler)
select new { m, staticFieldsUsed }

//<Description>
// When an instance method can be *safely* declared as static you should declare it as static.
//
// Whenever you write a method, you fulfill a contract in a given scope. 
// The narrower the scope is, the smaller the chance is that you write a bug.
//
// When a method is static, you can't access non-static members; hence, your scope is
// narrower. So, if you don't need and will never need (even in subclasses) instance
// fields to fulfill your contract, why give access to these fields to your method? 
// Declaring the method static in this case will let the compiler check that you 
// don't use members that you do not intend to use.
//
// Declaring a method as static if possible is also good practice because clients can 
// tell from the method signature that calling the method can't alter the object's state.
//
// Doing so, is also a micro performance optimization, since a static method is a 
// bit cheaper to invoke than an instance method, because the *this* reference* 
// doesn't need anymore to be passed.
//
// Notice that if a matched method is a handler, bound to an event through code  
// generated by a designer, declaring it as static might break the designer 
// generated code, if the generated code use the *this* invocation syntax, 
// (like *this.Method()*).
//</Description>

//<HowToFix>
// Declare matched methods as static.
//
// Since such method doesn't use any instance fields and methods of its type and 
// base-types, you should consider if it makes sense, to move such a method  
// to a static utility class.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Constructor should not call a virtual method</Name>
warnif count > 0

from t in Application.Types where 
   t.IsClass &&
  !t.IsGeneratedByCompiler &&
  !t.IsSealed

from ctor in t.Constructors 
let virtualMethodsCalled = 
   from mCalled in ctor.MethodsCalled
   where mCalled.IsVirtual && !mCalled.IsFinal && 
         // Only take care of just-my-code virtual methods called
         JustMyCode.Contains(mCalled) &&
         (  mCalled.ParentType == t ||
           (t.DeriveFrom(mCalled.ParentType) && 
            // Don't accept Object methods since they can be called
            // from another reference than the 'this' reference.
            mCalled.ParentType.FullName != "System.Object")
         )
   select mCalled
where virtualMethodsCalled.Count() > 0

select new { ctor , 
             virtualMethodsCalled, 
             // If there is no derived type, it might be 
             // an opportunity to mark t as sealed.
             t.DerivedTypes }

//<Description>
// This rule matches constructors of a non-sealed class that call one or
// several virtual methods.
//
// When an object written in C# is constructed, what happens is that constructors 
// run in order from the base class to the most derived class.
//
// Also objects do not change type as they are constructed, but start out as 
// the most derived type, with the method table being for the most derived type. 
// This means that virtual method calls always run on the most derived type,
// even when calls are made from the constructor.
//
// When you combine these two facts you are left with the problem that if you 
// make a virtual method call in a constructor, and it is not the most derived 
// type in its inheritance hierarchy, then it will be called on a class whose 
// constructor has not been run, and therefore may not be in a suitable state 
// to have that method called.
//
// Hence this situation makes the class *fragile to derive from*.
//</Description>

//<HowToFix>
// Violations reported can be solved by re-designing object initialisation
// or by declaring the parent class as *sealed*, if possible.
//</HowToFix>
]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[//<Name>Avoid the Singleton pattern</Name>
warnif count > 0
from t in Application.Types
where !t.IsStatic && !t.IsAbstract && (t.IsClass || t.IsStructure)

// All ctors of a singleton are private
where t.Constructors.Where(ctor => !ctor.IsPrivate).Count() == 0

// A singleton contains one static field of its parent type, to reference the unique instance
let staticFieldInstances = t.StaticFields.WithFieldType(t)
where staticFieldInstances.Count() == 1
select new { t, staticFieldInstance = staticFieldInstances.First() }

//<Description>
// The *singleton pattern* consists in enforcing that a class has just
// a single instance: http://en.wikipedia.org/wiki/Singleton_pattern
// At first glance, this pattern looks appealing, it is simple to implement,
// it adresses a common situation, and as a consequence it is widely used.
//
// However, we discourage you from using singleton classes because experience
// shows that **singleton often results in less testable and less maintainable code**.
// Singleton is *by-design*, not testable. Each unit test should use their own objects
// while singleton forces multiple unit-tests to use the same instance object.
//
// Also the singleton static *GetInstance()* method allows *magic* access to that 
// single object and its state from wherever developers want! This potentially
// attractive facility unfortunatly ends up into *unorganized*/*messy* code that 
// will require effort to be refactored. 
// 
// More details available in these discussions:
//  http://codebetter.com/patricksmacchia/2011/05/04/back-to-basics-usage-of-static-members/
//  http://adamschepis.com/blog/2011/05/02/im-adam-and-im-a-recovering-singleton-addict/
//</Description>

//<HowToFix>
// This rule matches *the classic syntax of singletons*, where one   
// static field hold the single instance of the parent class. We underline that  
// *the problem is this particular syntax*, that plays against testability.
// The problem is not the fact that a single instance of the class lives 
// at runtime.
//
// Hence to fix matches fo this rule, creates the single instance 
// at the startup of the program, and pass it to all classes and methods
// that need to access it.
//
// If multiple singletons are identified, they actually form together a 
// *program execution context*. Such context can be unified in a unique
// singleton context. Doing so will make it easier to propagate the 
// context across the various program units.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Don't assign static fields from instance methods</Name>
        
warnif count > 0
from f in Application.Fields where 
  f.IsStatic &&
 !f.IsLiteral &&
 !f.IsInitOnly &&
 !f.IsGeneratedByCompiler &&
  // Contract API define such a insideContractEvaluation static field
  f.Name != "insideContractEvaluation"
let assignedBy = f.MethodsAssigningMe.Where(m => !m.IsStatic)
where assignedBy .Count() > 0
select new { f, assignedBy }
     
//<Description>
// Assigning static fields from instance methods leads to
// poorly maintainable and non-thread-safe code.
//
// More discussion on the topic can be found here:
// http://codebetter.com/patricksmacchia/2011/05/04/back-to-basics-usage-of-static-members/
//</Description>

//<HowToFix>
// If the *static* field is just assigned once in the program
// lifetime, make sure to declare it as *readonly* and assign 
// it inline, or from the static constructor.
//
// In *Object-Oriented-Programming* the natural artifact 
// to hold states that can be modified is **instance fields**.
//
// Hence to fix violations of this rule, make sure to
// hold assignable states through *instance* fields, not
// through *static* fields.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid empty interfaces</Name>
warnif count > 0 from t in JustMyCode.Types where 
  t.IsInterface && 
  t.NbMethods == 0
select new { t, t.TypesThatImplementMe }

//<Description>
//Interfaces define members that provide 
//a behavior or usage contract. 
//The functionality that is described by the interface 
//can be adopted by any type, regardless of where the type 
//appears in the inheritance hierarchy. 
//A type implements an interface by providing implementations 
//for the members of the interface. 
//An empty interface does not define any members. 
//Therefore, it does not define a contract that can be implemented.
//
//If your design includes empty interfaces that types 
//are expected to implement, you are probably using an interface 
//as a marker or a way to identify a group of types. 
//If this identification will occur at run time, 
//the correct way to accomplish this is to use a custom attribute. 
//Use the presence or absence of the attribute, 
//or the properties of the attribute, to identify the target types. 
//If the identification must occur at compile time, 
//then it is acceptable to use an empty interface.
//</Description>

//<HowToFix>
//Remove the interface or add members to it. 
//If the empty interface is being used to label a set of types, 
//replace the interface with a custom attribute.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid types initialization cycles</Name>
warnif count > 0
 
// Types initialization cycle can only happen between types of an assembly.
from assembly in Application.Assemblies
                
let cctorSuspects = assembly.ChildMethods.Where(
  m => m.IsClassConstructor &&
       // Optimization: types involved in a type cycle necessarily don't have type level.
       m.ParentType.Level == null)

where cctorSuspects.Count() > 1
let typesSuspects = cctorSuspects.ParentTypes().ToHashSet()

//
// dicoTmp associates to each type suspect T, a set of types from typesSuspects
// that contains at least a method or a field used directly or indirectly by the cctor of T.
//
let dicoTmp = cctorSuspects.ToDictionary(
    cctor => cctor.ParentType,
    cctor => ((IMember)cctor).ToEnumerable().FillIterative(
              members => from m in members 
                         from mUsed in (m is IMethod) ? (m as IMethod).MembersUsed : new IMember[0]
                         where mUsed.ParentAssembly == assembly 
                         select mUsed)
              .DefinitionDomain
              .Select(m => m.ParentType) // Don't need .Distinct() here, because of ToHashSet() below.
              .Except(cctor.ParentType)
              .Intersect(typesSuspects)
              .ToHashSet()
) 

//
// dico associates to each type suspect T, the set of types initialized (directly or indirectly)
// by the initialization of T. This second step is needed, because if a cctor of a type T1 
// calls a member of a type T2, not only the cctor of T1 triggers the initialization of T2,
// but also it triggers the initialization of all types that are initialized by T2 initialization.
//
let dico = typesSuspects.Where(t => dicoTmp[t].Count() > 0).ToDictionary(
   typeSuspect => typeSuspect,
   typeSuspect => typeSuspect.ToEnumerable().FillIterative(
                         types => from t in types
                                  from tUsed in dicoTmp[t]
                                  select tUsed)
                   .DefinitionDomain
                   .Except(typeSuspect)
                   .ToHashSet()
)


//
// Now that dico is prepared, detect the cctor cycles
//
from t in dico.Keys

   // Thanks to the work done to build dico, it is now pretty easy
   // to spot types involved in an initialization cyle with t! 
   let usersAndUseds = from tTmp in dico[t]
                       where dico.ContainsKey(tTmp) && dico[tTmp].Contains(t)
                       select tTmp
   where usersAndUseds.Count() > 0
 
   // Here we've found type(s) both using and used by the suspect type.
   // A cycle involving the type t is found!
   let typeInitCycle = usersAndUseds.Append(t)


   // Compute methodsCalled and fieldsUsed, useful to explore
   // how a cctor involved in a type initialization cycle, triggers other type initialization.
   let methodsCalledDepth = assembly.ChildMethods.DepthOfIsUsedBy(t.ClassConstructor)
   let fieldsUsedDepth = assembly.ChildFields.DepthOfIsUsedBy(t.ClassConstructor)

   let methodsCalled = methodsCalledDepth.DefinitionDomain.OrderBy(m => methodsCalledDepth[m]).ToArray()
   let fieldsUsed = fieldsUsedDepth.DefinitionDomain.OrderBy(f => fieldsUsedDepth[f]).ToArray()

// Use the tick box to: Group cctors methods By parent types
select new { t.ClassConstructor, 
             cctorsCycle= typeInitCycle.Select(tTmp => tTmp.ClassConstructor),

             // methodsCalled and fieldsUsed are members used directly and indirectly by the cctor.
             // Export these members to the dependency graph (right click the cell Export/Append … to the Graph)
             // and see how the cctor trigger the initialization of other types
             methodsCalled,
             fieldsUsed 
}

//<Description>
// The *class constructor* (also called *static constructor*, and named *cctor* in IL code)
// of a type, if any, is executed by the CLR at runtime, the first time the type is used.
// A *cctor* doesn't need to be explicitly declared in C# or VB.NET, to exist in compiled IL code.
// Having a static field inline initialization is enough to have 
// the *cctor* implicitly declared in the parent class or structure.
//
// If the *cctor* of a type *t1* is using the type *t2* and if the *cctor* of *t2* is using *t1*,
// some type initialization unexpected and hard-to-diagnose buggy behavior can occur.
// Such a cyclic chain of initialization is not necessarily limited to two types
// and can embrace *N* types in the general case.
// More information on types initialization cycles can be found here:
// http://codeblog.jonskeet.uk/2012/04/07/type-initializer-circular-dependencies/
//
// The present code rule enumerates types initialization cycles.
// Some *false positives* can appear if some lambda expressions are defined 
// in *cctors* or in methods called by *cctors*. In such situation, this rule
// considers these lambda expressions as executed at type initialization time, 
// while it is not necessarily the case.
//</Description>

//<HowToFix>
// Types initialization cycles create confusion and unexpected behaviors.
// If several states hold by several classes must be initialized during the first
// access of any of those classes, a better design option is to create a dedicated 
// class whose responsibility is to initialize and hold all these states.
//</HowToFix>]]></Query>
    </Group>
    <Group Name="Design" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid custom delegates</Name>
warnif count > 0 
from t in Application.Types where t.IsDelegate

let invokeMethod = (from m in t.Methods where m.SimpleName == "Invoke" select m).Single()
let signature1 = invokeMethod.Name.Substring(
   invokeMethod.SimpleName.Length, 
   invokeMethod.Name.Length - invokeMethod.SimpleName.Length)

// 'ref' and 'out' parameters cannot be supported
where !signature1.Contains("&")

let signature2 = signature1.Replace("(","<").Replace(")",">")
let signature3 = signature2 == "<>" ? "" : signature2
let resultTypeName = invokeMethod.ReturnType == null ? "????" :
                     invokeMethod.ReturnType.FullName == "System.Void" ? "" :
                     invokeMethod.ReturnType.Name
let replaceWith = 
      resultTypeName == "Boolean" && invokeMethod.NbParameters == 1 ?
   "Predicate" + signature3 : resultTypeName == "" ?
   "Action" + signature3  : invokeMethod.NbParameters ==0 ?
   "Func<" + resultTypeName + ">" :
   "Func" + signature3.Replace(">", "," + resultTypeName + ">")
             
select new { t, replaceWith }

//<Description>
// Generic delegates sould be preferred over custom delegates.
// Generic delegates are:
//
// • *Action<…>* to represent any method with *void* return type.
//
// • *Func<…>* to represent any method with a return type. The last 
// generic argument is the return type of the prototyped methods.
//
// • *Predicate<T>* to represent any method that takes an instance
// of *T* and that returns a *boolean*.
//
// • Expression<…> that represents function definitions that can be 
// compiled and subsequently invoked at runtime but can also be 
// serialized and passed to remote processes.
//
// Thanks to generic delegates, not only the code using these custom 
// delegates will become clearer, but you'll be relieved from the 
// maintenance of these delegate types.
//
// Notice that delegates that are consumed by *DllImport* extern methods
// must not be converted, else this could provoke marshalling issues.
//</Description>

//<HowToFix>
// Remove custom delegates and replace them with generic
// delegates shown in the **replaceWith** column. 
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types with disposable instance fields must be disposable</Name>
        
warnif count > 0

// Several IDisposable types can be found if several .NET Fx are referenced.
let iDisposables = ThirdParty.Types.WithFullName("System.IDisposable")
where iDisposables.Any() // in case the code base doesn't use at all System.IDisposable

from t in Application.Types.Except(Application.Types.ThatImplementAny(iDisposables))
where !t.IsGeneratedByCompiler 

let instanceFieldsDisposable = 
    t.InstanceFields.Where(f => f.FieldType != null &&
                                f.FieldType.InterfacesImplemented.Intersect(iDisposables).Any())

where instanceFieldsDisposable.Any()
select new { t, instanceFieldsDisposable }

//<Description>
// This rule warns when a class declares and implements an instance field that 
// is a *System.IDisposable* type and the class does not implement *IDisposable*.
//
// A class implements the *IDisposable* interface to dispose of unmanaged resources 
// that it owns. An instance field that is an *IDisposable* type indicates that 
// the field owns an unmanaged resource. A class that declares an *IDisposable* 
// field indirectly owns an unmanaged resource and should implement the 
// *IDisposable* interface. If the class does not directly own any unmanaged 
// resources, it should not implement a finalizer.
//</Description>

//<HowToFix>
// To fix a violation of this rule, implement *IDisposable* and from the 
// *IDisposable.Dispose()* method call the *Dispose()* method of the field(s).
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Disposable types with unmanaged resources should declare finalizer</Name>

// This default rule is disabled by default,
// see in the rule description (below) why.
// warnif count > 0

// Several IDisposable type can be found if several .NET Fx are referenced.
let iDisposables = ThirdParty.Types.WithFullName("System.IDisposable")
where iDisposables.Any() // in case the code base doesn't use at all System.IDisposable

let disposableTypes = Application.Types.ThatImplementAny(iDisposables)
let unmanagedResourcesFields = disposableTypes.ChildFields().Where(f => 
   !f.IsStatic && 
    f.FieldType != null && 
    f.FieldType.FullName.EqualsAny(
       "System.IntPtr",
       "System.UIntPtr",
       "System.Runtime.InteropServices.HandleRef")).ToHashSet()
let disposableTypesWithUnmanagedResource = unmanagedResourcesFields.ParentTypes()

from t in disposableTypesWithUnmanagedResource
where !t.HasFinalizer
let unmanagedResourcesTypeFields = unmanagedResourcesFields.Intersect(t.InstanceFields)
select new { t, unmanagedResourcesTypeFields }

//<Description>
//A type that implements *System.IDisposable*, 
//and has fields that suggest the use of unmanaged resources, 
//does not implement a finalizer as described by *Object.Finalize()*.
//A violation of this rule is reported 
//if the disposable type contains fields of the following types:
//
// • *System.IntPtr*
//
// • *System.UIntPtr*
//
// • *System.Runtime.InteropServices.HandleRef*
//
// Notice that this default rule is disabled by default,
// because it typically reports *false positive* for classes
// that just hold some references to managed resources,
// without the responsibility to dispose them.
//
// To enable this rule just uncomment *warnif count > 0*.
//</Description>

//<HowToFix>
//To fix a violation of this rule, 
//implement a finalizer that calls your *Dispose()* method.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Methods that create disposable object(s) and that don't call Dispose()</Name>
 
// Uncomment this to transform this code query into a code rule.
// warnif count > 0

// Several IDisposable types can be found if several .NET Fx are referenced.
let iDisposables = ThirdParty.Types.WithFullName("System.IDisposable")
where iDisposables.Any() // in case the code base doesn't use at all System.IDisposable
 
// Build sequences of disposableTypes and disposeMethods
let disposableTypes = Types.ThatImplementAny(iDisposables).Concat(iDisposables)
let disposeMethods = disposableTypes.ChildMethods().WithName("Dispose()").ToHashSet()


// -> You can refine this code query by assigning to disposableTypesToLookAfter something like:
//    disposableTypes.WithFullNameIn("Namespace.TypeName1", "Namespace.TypeName2", ...)
let disposableTypesToLookAfter = disposableTypes


// -> You can refine this code query by assigning to methodsToLookAfter something like:
//    Application.Assemblies.WithNameLike("Asm").ChildMethods()
let methodsToLookAfter = Application.Methods


// Enumerate methods that create any disposable type, without calling Dispose()
from m in methodsToLookAfter.ThatCreateAny(disposableTypesToLookAfter )

where !m.MethodsCalled.Intersect(disposeMethods).Any()
select new {
   m,
   disposableObjectsCreated = disposableTypes.Where(t => m.CreateA(t)),
   m.MethodsCalled 
}

//<Description>
// This code query enumerates methods that create one or several disposable object(s), 
// without calling any Dispose() method.
//
// This code query is not a code rule because it is acceptable to do so, 
// as long as disposable objects are disposed somewhere else.
//
// This code query is designed to be be easily refactored 
// to look after only specific disposable types, or specific caller methods. 
//
// You can then refactor this code query to adapt it to your needs and transform it into a code rule.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Classes that are candidate to be turned into structures</Name>

warnif count > 0 from t in JustMyCode.Types where 
  t.IsClass &&
 !t.IsGeneratedByCompiler &&
 !t.IsStatic &&
  t.SizeOfInst > 0 &&
  t.SizeOfInst <= 16 &&   // Structure instance must not be too big, 
                          // else it degrades performance.

  t.NbChildren == 0 &&    // Must not have children

  // Must not implement interfaces to avoid boxing mismatch 
  // when structures implements interfaces.
  t.InterfacesImplemented.Count() == 0 &&

  // Must derive directly from System.Object
  t.DepthOfDeriveFrom("System.Object".AllowNoMatch()) == 1
  
  // && t.IsSealed    <-- You might want to add this condition 
  //                      to restraint the set.
  // && t.IsImmutable <-- Structures should be immutable type.
  // && t.!IsPublic   <-- You might want to add this condition if 
  //                      you are developping a framework with classes 
  //                      that are intended to be sub-classed by 
  //                      your clients.
  
select new { t, t.SizeOfInst, t.InstanceFields } 

//<Description>
// *Int32*, *Double*, *Char* or *Boolean* are structures and not classes.
// Structure are particularly suited to implement **lightweight value**s.
// Hence a class is candidate to be turned into a structure
// when its instances are *lightweight values*.
//
// This is a matter of *performance*. It is expected that a program
// works with plenty of *short lived lightweight values*.
// In such situation, the advantage of using *struct* instead of
// *class*, (in other words, the advantage of using *values* instead
// of *objects*), is that *values* are not managed by the garbage collector.
// This means that values are cheaper to deal with. 
//
// This rule matches classes that looks like being *lightweight values*.
// The characterization of such class is:
//
// • Its instances have a small *memory footprint* (at most 16 bytes)
//
// • Its instances have a memory footprint greater than zero
// (i.e the class has at least one instance field).
//
// • It implements no interfaces.
//
// • It has no derived classes.
//
// • It derives directly from *System.Object*.
//
// This rule doesn't take account if instances of matched
// classes are numerous *short-lived* objects.
// These criterions are just indications. Only you can decide if it is 
// *performance wise* to transform a class into a structure.
//
// A related case-study of using *class* or *struct* for *Tuple<…>* generic 
// types can be found here:
// http://stackoverflow.com/questions/2410710/why-is-the-new-tuple-type-in-net-4-0-a-reference-type-class-and-not-a-value-t
//</Description>

//<HowToFix>
// Just use the keyword *struct* instead of the keyword *class*.
//
// **CAUTION:** Before applying this rule, make sure to understand 
// the **deep implications** of transforming a class into a structure.
// http://msdn.microsoft.com/en-us/library/aa664471(v=vs.71).aspx
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid namespaces with few types</Name>
warnif count > 0 from n in JustMyCode.Namespaces 
where n.Name.Length > 0 // Don't match anonymous namespaces
let types = n.ChildTypes.Where(t => !t.IsGeneratedByCompiler)
where 
  types.Count() < 5 
  orderby types.Count() ascending
select new { n, types } 

//<Description>
// This rule warns about namespaces other than the global namespace 
// that contain less than five types.
//
// Make sure that each of your namespaces has a logical organization
// and that a valid reason exists to put types in a sparsely 
// populated namespace. 
// 
// Namespaces should contain types that are used together in most 
// scenarios. When their applications are mutually exclusive, 
// types should be located in separate namespaces. For example, 
// the *System.Web.UI* namespace contains types that are used 
// in Web applications, and the *System.Windows.Forms* namespace 
// contains types that are used in Windows-based applications. 
// Even though both namespaces have types that control aspects 
// of the user interface, these types are not designed for 
// use in the same application. Therefore, they are located in 
// separate namespaces.
//
// Careful namespace organization can also be helpful because 
// it increases the discoverability of a feature. By examining the 
// namespace hierarchy, library consumers should be able to locate
// the types that implement a feature.
//</Description>

//<HowToFix>
// To fix a violation of this rule, try to combine namespaces 
//that contain just a few types into a single namespace.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Nested types should not be visible</Name>
warnif count > 0 from t in JustMyCode.Types where 
  t.IsNested && 
 !t.IsGeneratedByCompiler &&
 !t.IsPrivate 
select new { 
   t, 
   t.Visibility 
} 

//<Description>
// This rule warns about nested types not declared as private.
//
// A nested type is a type declared within the scope of another 
// type. Nested types are useful for encapsulating private 
// implementation details of the containing type. Used 
// for this purpose, nested types should not be externally visible.
//
// Do not use externally visible nested types for logical 
// grouping or to avoid name collisions; instead use namespaces.
//
// Nested types include the notion of member accessibility, 
// which some programmers do not understand clearly.
//
// Protected types can be used in subclasses and nested types 
// in advanced customization scenarios.
//</Description>

//<HowToFix>
// If you do not intend the nested type to be externally visible,
// change the type's accessibility. 
//
// Otherwise, remove the nested type from its parent and make it 
// *non-nested*.
//
// If the purpose of the nesting is to group some nested types, 
// use a namespace to create the hierarchy instead.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Declare types in namespaces</Name>
warnif count > 0 from n in Application.Namespaces where 
  // If an anonymous namespace can be found, 
  // it means that it contains types outside of namespaces.
  n.Name == ""

  // Eliminate anonymous namespaces that contains
  // only generated types. 
  let childTypes = n.ChildTypes.Where(t => !t.IsGeneratedByCompiler)
  where childTypes.Count() > 0
select new { 
   n, 
   childTypes,
   n.NbLinesOfCode } 

//<Description>
// Types are declared within namespaces to prevent name collisions,
// and as a way of organizing related types in an object hierarchy.
//
// Types outside any named namespace are in a *global 
// namespace* that cannot be referenced in code.
//
// The *global namespace* has no name, hence it is qualified as
// being the *anonymous namespace*.
//
// This rule warns about *anonymous namespaces*.
//</Description>

//<HowToFix>
// To fix a violation of this rule, 
// declare all types of all anonymous 
// namespaces in some named namespaces.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Empty static constructor can be discarded</Name>
warnif count > 0 from m in Application.Methods where 
  m.IsClassConstructor && 
  m.NbLinesOfCode == 0
select m

//<Description>
// The *class constructor* (also called *static constructor*, and named *cctor* in IL code)
// of a type, if any, is executed by the CLR at runtime, just before the first time the type is used.
//
// This rule warns about the declarations of *static constructors*
// that don't contain any lines of code. Such *cctors* are useless
// and can be safely removed.
//</Description>

//<HowToFix>
// Remove matched empty *static constructors*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Instances size shouldn't be too big</Name>
warnif count > 0 from t in JustMyCode.Types where 
  t.SizeOfInst > 64 
  orderby t.SizeOfInst descending
select new { t, t.SizeOfInst, t.InstanceFields }

//<Description>
// Types where *SizeOfInst > 64* might degrade performance 
// if many instances are created at runtime. 
// They can also be hard to maintain. 
//
// Notice that a class with a large *SizeOfInst* value
// doesn't necessarily have a lot of instance fields.
// It might derive from a class with a large *SizeOfInst* value.
//
// See the definition of the *SizeOfInst* metric here 
// http://www.ndepend.com/docs/code-metrics#SizeOfInst
//</Description>

//<HowToFix>
// A type with a large *SizeOInst* value hold *directly* 
// a lot of data. Typically, you can group this data into 
// smaller types that can then be composed.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Boxing/unboxing should be avoided</Name>
warnif percentage > 5 from m in Application.Methods where 
  m.IsUsingBoxing || 
  m.IsUsingUnboxing
select new { m, m.NbLinesOfCode, m.IsUsingBoxing, m.IsUsingUnboxing } 

//<Description>
// *Boxing* is the process of converting a value type to the type 
// *object* or to any interface type implemented by this value 
// type. When the CLR boxes a value type, it wraps the value 
// inside a *System.Object* and stores it on the managed heap.
//
// *Unboxing* extracts the value type from the object. Boxing 
// is implicit; unboxing is explicit.
//
// The concept of boxing and unboxing underlies the C# unified 
// view of the type system in which a value of any type can 
// be treated as an object. More about *boxing* and *unboxing*
// here: https://msdn.microsoft.com/en-us/library/yz2be5wk.aspx
//
// This rule warns when more than 5% of methods in a code base
// are using *boxing* or *unboxing*. Because *boxing* and 
// *unboxing* come with a performance penalty and can be often 
// avoided.
//</Description>

//<HowToFix>
// Thanks to .NET generic, and especially thanks to 
// generic collections, *boxing* and *unboxing* should 
// be rarely used. Hence in most situations the code can 
// be refactored to avoid relying on *boxing* and *unboxing*.
// See for example:
// http://stackoverflow.com/questions/4403055/boxing-unboxing-and-generics
//
// With a performance profiler, indentify methods that consume 
// a lot of CPU time. If such method uses *boxing* or 
// *unboxing*, especially in a **loop**, make sure to refactor it.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Attribute classes should be sealed</Name>
warnif count > 0 from t in Application.Types where 
  t.IsAttributeClass && 
 !t.IsSealed && 
 !t.IsAbstract && 
  t.IsPublic
select new { t, t.NbLinesOfCode } 

//<Description>
// The .NET Framework class library provides methods 
// for retrieving custom attributes. By default, 
// these methods search the attribute inheritance 
// hierarchy; for example 
// *System.Attribute.GetCustomAttribute()* 
// searches for the specified attribute type, or any 
// attribute type that extends the specified attribute 
// type.
//
// Sealing the attribute eliminates the search 
// through the inheritance hierarchy, and can improve 
// performance.
//</Description>

//<HowToFix>
// To fix a violation of this rule, seal the attribute 
// type or make it abstract.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Don't use obsolete types, methods or fields</Name>   
warnif count > 0
let obsoleteTypes = Types.Where(t => t.IsObsolete)
let obsoleteMethods = Methods.Where(m => m.IsObsolete).ToHashSet()
let obsoleteFields = Fields.Where(f => f.IsObsolete)

from m in JustMyCode.Methods.UsingAny(obsoleteTypes).Union(
          JustMyCode.Methods.UsingAny(obsoleteMethods)).Union(
          JustMyCode.Methods.UsingAny(obsoleteFields))
let obsoleteTypesUsed = obsoleteTypes.UsedBy(m)

// Optimization: MethodsCalled + Intersect() is faster than using obsoleteMethods.UsedBy()
let obsoleteMethodsUsed = m.MethodsCalled.Intersect(obsoleteMethods)
let obsoleteFieldsUsed = obsoleteFields.UsedBy(m)
select new { m, obsoleteTypesUsed, obsoleteMethodsUsed, obsoleteFieldsUsed }

//<Description>
// The attribute *System.ObsoleteAttribute* is used to tag
// types, methods or fields of an API that clients shouldn't 
// use because these code elements will be removed sooner
// or later.
//
// This rule warns about methods that use a type, a method
// or a field, tagged with *System.ObsoleteAttribute*.
//</Description>

//<HowToFix>
// Typically when a code element is tagged with
// *System.ObsoleteAttribute*, a *workaround message*
// is provided to clients.
//
// This *workaround message* will tell you what to do
// to avoid using the obsolete code element.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Don't forget to implement methods that throw NotImplementedException</Name>
warnif count > 0
from m in Application.Methods
where m.CreateA("System.NotImplementedException".AllowNoMatch())
select m

//<Description>
// The exception *NotImplementedException* is used to declare 
// a method *stub* that can be invoked, and defer the  
// development of the method implementation.
//
// This exception is especially useful when doing **TDD**
// (*Test Driven Development*) when tests are written first.
// This way tests fail until the implementation is written.
//
// Hence using *NotImplementedException* is a *temporary*
// facility, and before releasing, will come a time when 
// this exception shouldn't be used anywhere in code.
//
// This rule warns about method still using 
// *NotImplementedException*. 
//</Description>

//<HowToFix>
// Investigate first why *NotImplementedException* is still 
// used. Either the method must be implemented, or
// the method stub is not used and can be safely removed.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Override equals and operator equals on value types</Name>
warnif count > 0
from t in Application.Types where
  t.IsStructure
let equalsMethod = t.InstanceMethods.Where(m0 => m0.Name == "Equals(Object)").SingleOrDefault()
where equalsMethod == null
select t

//<Description>
// For value types, the inherited implementation of *Equals()* uses 
// the Reflection library, and compares the contents of all 
// fields. Reflection is computationally expensive, and comparing 
// every field for equality might be unnecessary.
//
// If you expect users to compare or sort instances, or use them 
// as hash table keys, your value type should implement *Equals()*.
// In C# and VB.NET, you should also provide an implementation of 
// the equality and inequality operators. 
//</Description>

//<HowToFix>
// To fix a violation of this rule, provide an implementation 
// of *Equals()* and implement the equality and inequality operators.
//</HowToFix>]]></Query>
    </Group>
    <Group Name="Architecture and Layering" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Avoid namespaces mutually dependent</Name>
warnif count > 0

// Optimization: restraint application assemblies set
// If some namespaces are mutually dependent
//  - They must be declared in the same assembly
//  - The parent assembly must ContainsNamespaceDependencyCycle
from assembly in Application.Assemblies.Where(a => a.ContainsNamespaceDependencyCycle != null && a.ContainsNamespaceDependencyCycle.Value)

// hashset is used to avoid reporting both A <-> B and B <-> A
let hashset = new HashSet<INamespace>()

// Optimization: restraint namespaces set
// If a namespace doesn't have a Level value, it must be in a dependency cycle
// or it must be using directly or indirectly a dependency cycle.
let namespacesSuspect = assembly.ChildNamespaces.Where(n => n.Level == null)

from nA in namespacesSuspect

// Select namespaces mutually dependent with nA
let unused = hashset.Add(nA) // Populate hashset
let namespacesMutuallyDependentWith_nA = nA.NamespacesUsed.Using(nA)
          .Except(hashset) // <-- avoid reporting both A <-> B and B <-> A 
where namespacesMutuallyDependentWith_nA.Count() > 0

from nB in namespacesMutuallyDependentWith_nA

// nA and nB are mutually dependent
// First select the one that shouldn't use the other.
// The first namespace is inferred from the fact that it is using less types of the second.
let typesOfBUsedByA = nB.ChildTypes.UsedBy(nA)
let typesOfAUsedByB = nA.ChildTypes.UsedBy(nB)
let first = (typesOfBUsedByA.Count() > typesOfAUsedByB.Count()) ? nB : nA
let second = (first == nA) ? nB : nA
let typesOfFirstUsedBySecond = (first == nA) ? typesOfAUsedByB : typesOfBUsedByA
let typesOfSecondUsedByFirst = (first == nA) ? typesOfBUsedByA : typesOfAUsedByB

select new { 
   first, 
   shouldntUseNamespace = second, 
   OK_typesOfFirstUsedBySecond = typesOfFirstUsedBySecond, 
   KO_typesOfSecondUsedByFirst = typesOfSecondUsedByFirst }
//<Description>
// This rule lists pair of namespace mutually dependent.
//
// The pair *{ first, second }* is formatted to show 
// **first namespace shouldn't use the second namespace**.
// The *first/second* order is inferred from the number of types 
// used by each other. The first namespace is using fewer types of 
// the second. In general this indicates that the first namespace  
// should be at a *lower-level* in the architecture than 
// the second.
//
// Following this rule is useful to avoid **namespaces dependency 
// cycles**. This will get the code architecture close to a 
// *layered architecture*, where *low-level* code is not allowed
// to use *high-level* code.
//
// In other words, abiding by this rule will help significantly
// getting rid of what is often called **spagetthi code:
// Entangled code that is not properly layered and structured**.
//
// More on this in our white books relative to partitioning code.
// http://www.ndepend.com/docs/white-books
//</Description>

//<HowToFix>
// Refactor the code to make sure that *the first namespace doesn't 
// use the second namespace*. To get started, first explore the 
// coupling between two namespaces mutually dependent:
// 
//  1) from the *right-click menu* export the first namespace to 
// the vertical header of the dependency matrix.
//
//  2) export the second namespace to the horizontal header of 
// the dependency matrix.
//
//  3) double-click the black matrix cell (it is black because of
// mutual dependency).
//
//  4) in the matrix command bar, click the button: 
// *Remove empty Row(s) and Column(s)*.
//
// At this point, the dependency matrix shows types involved 
// into the coupling.
//
// Some refactoring that helps uncouple two namespaces
// mutually dependent include:
//
// • Moving one or several types from the *low-level* namespaces
// to the *high-level* one, or do the opposite.
//
// • Use *Inversion of Control (IoC)*: 
// http://en.wikipedia.org/wiki/Inversion_of_control
// This can consist in creating new interfaces in the
// *low-level* namespace, implemented by classes
// in the *high-level* namespace. This way *low-level* 
// code can consume *high-level* code through interfaces, 
// without using directly *high-level* implementations.
// Interfaces can be passed to *low-level* code through
// the *high-level* namespace code, or through even 
// higher-level code. In related documentations 
// you can see these interfaces named as *callbacks*, 
// and the overall pattern is also known as 
// *Dependency Injection (DI)*:
// http://en.wikipedia.org/wiki/Dependency_injection
//</HowToFix>P
      ]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid namespaces dependency cycles</Name>
warnif count > 0

// Optimization: restraint application assemblies set
// If some namespaces are mutually dependent
//  - They must be declared in the same assembly
//  - The parent assembly must ContainsNamespaceDependencyCycle
from assembly in Application.Assemblies
                 .Where(a => a.ContainsNamespaceDependencyCycle != null && 
                             a.ContainsNamespaceDependencyCycle.Value)

// Optimization: restraint namespaces set
// A namespace involved in a cycle necessarily have a null Level.
let namespacesSuspect = assembly.ChildNamespaces.Where(n => n.Level == null)

// hashset is used to avoid iterating again on namespaces already caught in a cycle.
let hashset = new HashSet<INamespace>()


from suspect in namespacesSuspect
   // By commenting in this line, the query matches all namespaces involved in a cycle.
   where !hashset.Contains(suspect)

   // Define 2 code metrics
   // - Namespaces depth of is using indirectly the suspect namespace.
   // - Namespaces depth of is used by the suspect namespace indirectly.
   // Note: for direct usage the depth is equal to 1.
   let namespacesUserDepth = namespacesSuspect.DepthOfIsUsing(suspect)
   let namespacesUsedDepth = namespacesSuspect.DepthOfIsUsedBy(suspect)

   // Select namespaces that are both using and used by namespaceSuspect
   let usersAndUsed = from n in namespacesSuspect where 
                         namespacesUserDepth[n] > 0 && 
                         namespacesUsedDepth[n] > 0 
                      select n

   where usersAndUsed.Count() > 0

   // Here we've found namespace(s) both using and used by the suspect namespace.
   // A cycle involving the suspect namespace is found!
   let cycle = usersAndUsed.Append(suspect)

   // Fill hashset with namespaces in the cycle.
   // .ToArray() is needed to force the iterating process.
   let unused1 = (from n in cycle let unused2 = hashset.Add(n) select n).ToArray()

select new { suspect, cycle }

//<Description>
// This rule lists all *application namespace dependency cycles*.
// Each row shows a different cycle, indexed with one of the namespace entangled 
// in the cycle.
//
// To browse a cycle on the dependency graph or the dependency matrix, right click
// a cycle cell and export the matched namespaces to the dependency graph or matrix.
//
// In the matrix, dependency cycles are represented with red squares and black cells.
// To easily browse dependency cycles, the dependency matrix comes with an option:
// *Display Direct and Indirect Dependencies*
//
// Read our white books relative to partitioning code, 
// to know more about namespaces dependency cycles, and why avoiding them 
// is a *simple yet efficient* solution to clean the architecture of a code base.
// http://www.ndepend.com/docs/white-books
//</Description>

//<HowToFix>
// Removing first pairs of *mutually dependent namespaces* will eliminate
// most *namespaces dependency cycles*. This is why we suggest 
// focusing on matches of the default rule 
// **Avoid namespaces mutually dependent** before dealing
// with the present rule.
//
// Once solving all *mutually dependent namespaces*, remaining cycles
// matched by the present rule necessarily involve 3 or more namespaces
// like in: *A is using B is using C is using A*.
// Such cycle can be broken by identifying which namespace should
// be at the *lower-level*. For example if B should be at the
// *lower-level*, then it means C should be at the *higher-level*
// and to break the cycle, you just have to remove the dependency
// from B to C, with a pattern described in the *HowToFix* section
// of the rule *Avoid namespaces mutually dependent*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid partitioning the code base through many small library Assemblies</Name>
warnif count > 10
from a in Application.Assemblies where
  ( a.NbLinesOfCode < 1000 ||
    a.NbILInstructions < 7000 ) &&
  a.FilePath.FileExtension.ToLower() == ".dll"
select new { a, a.NbLinesOfCode, a.NbILInstructions }

//<Description>
// Each .NET Assembly compiled represents one or several physical file(s).
// Having too many library .NET Assemblies is a symptom of 
// considering **physical** .NET Assemblies as **logical** components.
//
// We advise having less, and bigger, .NET Assemblies
// and using the concept of namespaces to define logical components.
// Benefits are:
//
// • Faster compilation time.
//
// • Faster startup time for your program.
//
// • Easier deployment thanks to less files to manage.
//
// • If you are developing a Framework,
// less .NET assemblies to reference and manage for your clients.
//</Description>

//<HowToFix>
// Consider using the *physical* concept of assemblies for physical needs 
// only.
//
// Our white book about **Partitioning code base through .NET assemblies 
// and Visual Studio projects** explains in details valid and invalid
// reasons to use assemblies.
// Download it here:
// http://www.ndepend.com/Res/NDependWhiteBook_Assembly.pdf
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>UI layer shouldn't use directly DB types</Name>
        
warnif count > 0

// UI layer is made of types in namespaces using a UI framework
let uiTypes = Application.Namespaces.UsingAny(Assemblies.WithNameIn("PresentationFramework", "System.Windows", "System.Windows.Forms", "System.Web")).ChildTypes()

// You can easily customize this line to define what are DB types.
let dbTypes = ThirdParty.Assemblies.WithNameIn("System.Data", "EntityFramework", "NHibernate").ChildTypes()
              // Ideally even DataSet and associated, usage should be forbidden from UI layer: 
              // http://stackoverflow.com/questions/1708690/is-list-better-than-dataset-for-ui-layer-in-asp-net
              .Except(ThirdParty.Types.WithNameIn("DataSet", "DataTable", "DataRow"))

from uiType in uiTypes.UsingAny(dbTypes)
let dbTypesUsed = dbTypes.Intersect(uiType.TypesUsed)
select new { uiType, dbTypesUsed }

      
//<Description>
// This rule is more a *sample rule to adapt to your need*,
// than a rigid rule you should abide by. It shows how to
// define code layers in a rule and how to be warned about  
// layers dependencies violations.
//
// This rule first defines the UI layer and the DB framework 
// layer. Second it checks if any UI layer type is using 
// directly any DB framework layer type.
//
// • The **DB framework layer** is defined as the set of *third-party*
// types in the framework *ADO.NET*, *EntityFramework*, 
// *NHibernate* types, that the application is consuming. 
// It is easy to append and suppress any DB framework.
//
// • The UI layer (**User Interface Layer**) is defined as the
// set of types that use *WPF*, *Windows Form*, *ASP.NET*.
//
// *UI using directly DB frameworks* is generally considered 
// as *poor design* because DB frameworks accesses should be 
// a concept hidden to UI, encapsulated into a **dedicated 
// Data Access Layer (DAL)**.
//</Description>

//<HowToFix>
// This rule lists precisely which UI type uses which 
// DB framework type. Instead of fixing matches one by one,
// first imagine how DB framework accesses could be 
// encapsulated into a dedicated layer.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>UI layer shouldn't use directly DAL layer</Name>

warnif count > 0

// UI layer is made of types in namespaces using a UI framework
let uiTypes = Application.Namespaces.UsingAny(Assemblies.WithNameIn("PresentationFramework", "System.Windows", "System.Windows.Forms", "System.Web")).ChildTypes()

// Exclude commonly used DataSet and associated, from ADO.Net types
// You can easily customize this line to define what are DB types.
let dbTypes = ThirdParty.Assemblies.WithNameIn("System.Data", "EntityFramework", "NHibernate").ChildTypes()
              .Except(ThirdParty.Types.WithNameIn("DataSet", "DataTable", "DataRow"))

// DAL layer is made of types in namespaces using a DB framework
// .ToHashSet() results to faster execution of    dalTypes.Intersect(uiType.TypesIUse).
let dalTypes = Application.Namespaces.UsingAny(dbTypes).ChildTypes().ToHashSet()

from uiType in uiTypes.UsingAny(dalTypes)
let dalTypesUsed = dalTypes.Intersect(uiType.TypesUsed)
select new {
   uiType,
   // if dalTypesUsed is empty, it means that the uiType is part of the DAL
   dalTypesUsed
}

//<Description>
// This rule is more a *sample rule to adapt to your need*,
// than a rigid rule you should abide by. It shows how to
// define code layers in a rule and how to be warned about 
// layers dependencies violations.
//
// This rule first defines the UI layer and the DAL layer.
// Second it checks if any UI layer type is using directly
// any DAL layer type.
//
// • The DB layer (the DAL, **Data Access Layer**) is defined as 
// the set of types of the application that use *ADO.NET*, 
// *EntityFramework*, *NHibernate* types. It is easy to append 
// and suppress any DB framework.
//
// • The UI layer (**User Interface Layer**) is defined as the
// set of types that use *WPF*, *Windows Form*, *ASP.NET*.
//
// *UI using directly DAL* is generally considered as *poor 
// design* because DAL accesses should be a concept
// hidden to UI, encapsulated into an **intermediary domain 
// logic**.
//</Description>

//<HowToFix>
// This rule lists precisely which UI type uses which DAL type.
//
// More about this particular design topic here:
// http://www.kenneth-truyers.net/2013/05/12/the-n-layer-myth-and-basic-dependency-injection/
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Assemblies with poor cohesion (RelationalCohesion)</Name>
warnif count > 0 from a in Application.Assemblies 

// Build the types list on which we want to check cohesion
// This is the assembly 'a' type, minus enumeration
// and types generated by the compiler.
let types = a.ChildTypes.Where(
   t => !t.IsGeneratedByCompiler &&
        !t.IsEnumeration)
        // Absolutly need ToHashet() to have fast Intersect() calls below.
        .ToHashSet()

// Relational Cohesion metrics is relevant only if there are several types
where types.LongCount()> 20

// R is the total number of relationship between types of the assemblies. 
let R = types.Sum(t => t.TypesUsed.Intersect(types).Count())

// Relational Cohesion formula
let relationalCohesion = (float)R / types.Count
where  
  
  (relationalCohesion  < 1.5 || 
   relationalCohesion  > 4.0)
select new { 
  a, 
  a.ChildTypes,
  relationalCohesion, 
  a.RelationalCohesion }

//<Description>
// This rule computes the *Relational Cohesion* metric for
// the application assemblies, and warns about wrong values.
// 
// The *Relational Cohesion* for an assembly, is the total number 
// of relationship between types of the assemblies, divided 
// by the number of types. In other words it is the average
// number of types in the assembly used by a type in the assembly.
//
// As classes inside an assembly should be strongly related, 
// the cohesion should be high. On the other hand, a value 
// which is too high may indicate over-coupling. A good range 
// for *Relational Cohesion* is **1.5 to 4.0**.
//
// Notice that assemblies with less than 20 types are ignored.
//</Description>

//<HowToFix>
// Matches of this present rule might reveal either assemblies
// with specific coding constraints (like code generated that
// have particular structure) either issues in design.
//
// In the second case, large refactoring can be planned
// not to respect this rule in particular, but to increase
// the overall design and code maintainability.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Namespaces with poor cohesion (RelationalCohesion)</Name>
warnif count > 0 from n in Application.Namespaces 

// Build the types list on which we want to check cohesion
// This is the namespace children types, minus enumerations
// and types generated by the compiler.
let types = n.ChildTypes.Where(
   t => !t.IsGeneratedByCompiler &&
        !t.IsEnumeration)
        // Absolutly need ToHashet() to have fast Intersect() calls below.
        .ToHashSet()

// Relational Cohesion metrics is relevant only if there are enough types
where types.LongCount() > 20

// R is the total number of relationship between types of the namespaces. 
let R = types.Sum(t => t.TypesUsed.Intersect(types).Count())

// Relational Cohesion formula
let relationalCohesion = (float)R / types.Count
where  
  
  (relationalCohesion  < 1.5 || 
   relationalCohesion  > 4.0)
select new { 
  n, 
  n.ChildTypes,
  relationalCohesion
}

//<Description>
// This rule computes the *Relational Cohesion* metric for
// the application namespaces, and warns about wrong values.
// 
// The *Relational Cohesion* for a namespace, is the total number 
// of relationship between types of the namespaces, divided 
// by the number of types. In other words it is the average
// number of types in the namespace used by a type in the namespace.
//
// As classes inside an namespace should be strongly related, 
// the cohesion should be high. On the other hand, a value 
// which is too high may indicate over-coupling. A good range 
// for *Relational Cohesion* is **1.5 to 4.0**.
//
// Notice that namespaces with less than 20 types are ignored.
//</Description>

//<HowToFix>
// Matches of this present rule might reveal either namespaces
// with specific coding constraints (like code generated that
// have particular structure) either issues in design.
//
// In the second case, refactoring sessions can be planned
// to increase the overall design and code maintainability.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Assemblies that don't satisfy the Abstractness/Instability principle</Name>
warnif percentage > 15 from a in Application.Assemblies where 
  a.NormDistFromMainSeq > 0.7
  orderby a.NormDistFromMainSeq descending
select new { a, a.NormDistFromMainSeq }

//<Description>
// The **Abstractness versus Instability Diagram** that is shown in the NDepend 
// report helps to assess which assemblies are **potentially painful to maintain**
// (i.e concrete and stable) and which assemblies are **potentially useless** 
// (i.e abstract and instable).
//
// • **Abstractness**: If an assembly contains many abstract types 
// (i.e interfaces and abstract classes) and few concrete types, 
// it is considered as abstract.
//
// • **Stability**: An assembly is considered stable if its types 
// are used by a lot of types from other assemblies. In this context 
// stable means *painful to modify*.
//
// From these metrics, we define the *perpendicular normalized distance of
// an assembly from the idealized line* **A + I = 1** (called *main sequence*). 
// This metric is an indicator of the assembly's balance between abstractness 
// and stability. We precise that the word *normalized* means that the range 
// of values is [0.0 … 1.0].
//
// This rule warns about assemblies with a *normalized distance* greater than 
// than 0.7.
//
// This rules use the default code metric on assembly
// *Normalized Distance from the Main Sequence* explained here: 
// http://www.ndepend.com/docs/code-metrics#DitFromMainSeq
//
// These concepts have been originally introduced by *Robert C. Martin*
// in 1994 in this paper: http://www.objectmentor.com/resources/articles/oodmetrc.pdf
//</Description>

//<HowToFix>
// Violations of this rule indicate assemblies with an improper 
// *abstractness / stability* balance.
//
// • Either the assembly is *potentially painful to maintain* (i.e is massively
// used and contains mostly concrete types). This can be fixed by creating 
// abstractions to avoid too high coupling with concrete implementations.
//
// • Either the assembly is *potentially useless* (i.e contains mostly
// abstractions and is not used enough). In such situation, the design
// must be reviewed to see if it can be enhanced.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Example of custom rule to check for dependency</Name>
warnif count > 0 from a in Assemblies
where 
a.IsUsing("Foo1.Foo2".AllowNoMatch().MatchNamespace()) &&
(a.Name == @"Foo3")
select new { a, a.NbLinesOfCode }
// the assembly Foo3
// shouldn't use directly 
// the namespace Foo3.Foo4
// because (TODO insert your reason)

//<Description>
// This rule is a **sample rule** that shows how to
// check if a particular dependency exists or not, 
// from a code element **A** to a code element **B**,
// **A** and **B** being an *Assembly*, a *Namespace*, a *Type*, 
// a *Method* or a *Field*, **A** and **B** being not 
// necessarily of same kind (i.e two Assemblies or 
// two Namespaces…).
//
// Such rule can be generated:
//
// • by right clicking the cell in the *Dependency Matrix* 
// with **B** in row and **A** in column,
//
// • or by right-clicking the concerned arrow in the *Dependency 
// Graph* from **A** to **B**,
//
// and in both cases, click the menu
// **Generate a code rule that warns if this dependency exists**
//
// The generated rule will look like this one.
// It is now up to you to adapt this rule to check exactly 
// your needs.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Higher cohesion - lower coupling</Name>

let abstractNamespaces = JustMyCode.Namespaces.Where(
     n => n.ChildTypes.Where(t => !t.IsInterface && !t.IsEnumeration && !t.IsDelegate).Count() == 0
).ToHashSet()

let concreteNamespaces = JustMyCode.Namespaces.Except(abstractNamespaces).ToHashSet()

from n in concreteNamespaces
let namespacesUsed = n.NamespacesUsed.ExceptThirdParty()
let concreteNamespacesUsed = namespacesUsed.Except(abstractNamespaces)
let abstractNamespacesUsed = namespacesUsed.Except(concreteNamespaces)
select new { n, concreteNamespacesUsed , abstractNamespacesUsed }

//<Description>
// It is deemed as a good software architecture practice to clearly separate
// *abstract* namespaces that contain only abstractions (interfaces, enumerations, delegates)
// from *concrete* namespaces, that contain classes and structures.
//
// Typically, the more concrete namespaces rely on abstract namespaces *only*,
// the more **Decoupled** is the architecture, and the more **Cohesive** are 
// classes inside concrete namespaces.
//
// The present code query defines sets of abstract and concrete namespaces
// and show for each concrete namespaces, which concrete and abstract namespaces 
// are used. 
//</Description>

//<HowToFix>
// This query can be transformed into a code rule, depending if you wish to 
// constraint your code structure *coupling / cohesion* ratio.
//</HowToFix>]]></Query>
    </Group>
    <Group Name="API Breaking Changes" Active="True" ShownInReport="True">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>API Breaking Changes: Types</Name>

warnif count > 0 from t in codeBase.OlderVersion().Application.Types
where t.IsPubliclyVisible && 

     // The type has been removed, it was not tagged as obsolete
     // and its parent assembly hasn't been removed …
     ( ( t.WasRemoved() && 
        !t.ParentAssembly.WasRemoved() && 
        !t.IsObsolete) ||

     // … or the type is not publicly visible anymore
        !t.WasRemoved() && !t.NewerVersion().IsPubliclyVisible)

select new { 
   t,
   NewVisibility = 
      (t.WasRemoved() ? " " : 
       t.NewerVersion().Visibility.ToString()) 
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule warns if a type publicly visible in the *baseline*, 
// is not publicly visible anymore or if it has been removed.
// Clients code using such type will be broken.
//</Description>

//<HowToFix>
// Make sure that public types that used to be presented to
// clients, still remain public now, and in the future.
//
// If a public type must really be removed, you can tag it
// with *System.ObsoleteAttribute* with a *workaround message*
// during a few public releases, until it gets removed definitely.
// Notice that this rule doesn't match types removed that were
// tagged as obsolete.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>API Breaking Changes: Methods</Name>
warnif count > 0 from m in codeBase.OlderVersion().Application.Methods
where m.IsPubliclyVisible && 

     // The method has been removed, it was not tagged as obsolete
     // and its parent type hasn't been removed …
     ( ( m.WasRemoved() && 
        !m.ParentType.WasRemoved() && 
        !m.IsObsolete )

     // … or the method is not publicly visible anymore
     || (!m.WasRemoved() && !m.NewerVersion().IsPubliclyVisible) 

        // … or the method return type has changed
     || (!m.WasRemoved() && m.ReturnType != null && m.NewerVersion().ReturnType != null
                         && m.ReturnType.FullName != m.NewerVersion().ReturnType.FullName)        
      )

//--------------------------------------
// Handle special case: if between two versions a regular property becomes 
// an auto-property (or vice-versa) the property getter/setter method have 
// a different value for IMethod.IsGeneratedByCompiler
// since auto-property getter/setter are marked as generated by the compiler.
//
// If a method IsGeneratedByCompiler value changes between two versions, 
// NDepend doesn't pair the newer/older occurences of the method.
//
// Hence in such situation, a public method is seen as added 
// and a public method is seen as removed, but the API is not broken!
// The equivalentMethod-check below avoids reporting such 
// API Breaking Change false-positive.
let equivalentMethod = m.WasRemoved() && m.ParentType.IsPresentInBothBuilds() ?
   m.ParentType.NewerVersion().Methods
   .FirstOrDefault(m1 => 
       m1.IsPubliclyVisible &&
       m1.Name == m.Name &&
       m1.IsGeneratedByCompiler != m.IsGeneratedByCompiler &&
      (m1.ReturnType == null || m.ReturnType == null || m1.ReturnType.FullName == m.ReturnType.FullName)
    )
    : null
where equivalentMethod == null
//--------------------------------------


select new { 
   m,
   NewVisibility = 
      (m.WasRemoved() ? " " : 
       m.NewerVersion().Visibility.ToString()) 
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule warns if a method publicly visible in the *baseline*, 
// is not publicly visible anymore or if it has been removed.
// Clients code using such method will be broken.
//</Description>

//<HowToFix>
// Make sure that public methods that used to be presented to
// clients, still remain public now, and in the future.
//
// If a public method must really be removed, you can tag it
// with *System.ObsoleteAttribute* with a *workaround message*
// during a few public releases, until it gets removed definitely.
// Notice that this rule doesn't match methods removed that were
// tagged as obsolete.
//</HowToFix>
]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>API Breaking Changes: Fields</Name>
warnif count > 0 from f in codeBase.OlderVersion().Application.Fields
where f.IsPubliclyVisible &&

     // The field has been removed, it was not tagged as obsolete
     // and its parent type hasn't been removed …
     ( ( f.WasRemoved() && 
        !f.ParentType.WasRemoved() && 
        !f.IsObsolete)

     // … or the field is not publicly visible anymore
     ||  !f.WasRemoved() && !f.NewerVersion().IsPubliclyVisible)

     // … or the field type has changed
     || (!f.WasRemoved() && f.FieldType != null && f.NewerVersion().FieldType != null
                         && f.FieldType.FullName != f.NewerVersion().FieldType.FullName)

select new { 
   f,
   NewVisibility = 
      (f.WasRemoved() ? " " : 
       f.NewerVersion().Visibility.ToString()) 
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule warns if a field publicly visible in the *baseline*, 
// is not publicly visible anymore or if it has been removed.
// Clients code using such field will be broken.
//</Description>

//<HowToFix>
// Make sure that public fields that used to be presented to
// clients, still remain public now, and in the future.
//
// If a public field must really be removed, you can tag it
// with *System.ObsoleteAttribute* with a *workaround message*
// during a few public releases, until it gets removed definitely.
// Notice that this rule doesn't match fields removed that were
// tagged as obsolete.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>API Breaking Changes: Interfaces and Abstract Classes</Name>
warnif count > 0 from tNewer in Application.Types where 
 (tNewer.IsInterface || tNewer.IsClass && tNewer.IsAbstract) && 
  tNewer.IsPubliclyVisible && 
  tNewer.IsPresentInBothBuilds()

let tOlder = tNewer.OlderVersion() where tOlder.IsPubliclyVisible

let methodsRemoved = tOlder.Methods.Where(m => m.IsAbstract && m.WasRemoved())
let methodsAdded = tNewer.Methods.Where(m => m.IsAbstract && m.WasAdded())

where methodsAdded.Count() > 0 || methodsRemoved.Count() > 0
select new { 
   tNewer, 
   methodsAdded, 
   methodsRemoved 
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule warns if a publicly visible interface or abstract class 
// has been changed and contains new abstract methods or 
// if some abstract methods have been removed.
//
// Clients code that implement such interface or derive from 
// such abstract class will be broken.
//</Description>

//<HowToFix>
// Make sure that the public contracts of interfaces and abstract classes
// that used to be presented to clients, remain stable now, and in the future.
//
// If a public contract must really be changed, you can tag 
// abstract methods that will be removed with *System.ObsoleteAttribute*  
// with a *workaround message* during a few public releases, until it gets 
// removed definitely.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Broken serializable types</Name>
warnif count > 0

from t in Application.Types where

  // Collect types tagged with SerializableAttribute
  t.HasAttribute("System.SerializableAttribute".AllowNoMatch())  && 
 !t.IsDelegate &&
  t.IsPresentInBothBuilds() &&
  t.HasAttribute(t)

  // Find newer and older versions of NonSerializedAttribute
  let newNonSerializedAttribute = ThirdParty.Types.WithFullName("System.NonSerializedAttribute").SingleOrDefault()
  let oldNonSerializedAttribute = newNonSerializedAttribute == null ? null : newNonSerializedAttribute.OlderVersion()

  // Find added or removed fields not marked with NonSerializedAttribute
  let addedInstanceField = from f in t.InstanceFields where 
                             f.WasAdded() && 
                             (newNonSerializedAttribute == null || !f.HasAttribute(newNonSerializedAttribute))
                           select f
  let removedInstanceField = from f in t.OlderVersion().InstanceFields where 
                             f.WasRemoved() && 
                             (oldNonSerializedAttribute == null || !f.HasAttribute(oldNonSerializedAttribute))
                           select f
  where addedInstanceField.Count() > 0 || removedInstanceField.Count() > 0

select new { 
   t, 
   addedInstanceField, 
   removedInstanceField 
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule warns about breaking changes in types tagged with 
// *SerializableAttribute*.
//
// To do so, this rule searches for serializable type with serializable 
// instance fields added or removed. Notice that it doesn't take account
// of fields tagged with *NonSerializedAttribute*.
//
// From http://msdn.microsoft.com/library/system.serializableattribute.aspx :
// "All the public and private fields in a type that are marked by the 
//  *SerializableAttribute*  are serialized by default, unless the type 
//  implements the *ISerializable* interface to  override the serialization process. 
//  The default serialization process excludes fields that are marked 
//  with the *NonSerializedAttribute* attribute."
//</Description>

//<HowToFix>
// Make sure that the serialization process of serializable types remains
// stable now, and in the future.
// 
// Else you'll have to deal with **Version Tolerant Serialization**
// that is explained here:
// https://msdn.microsoft.com/en-us/library/ms229752(v=vs.110).aspx
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Avoid changing enumerations Flags status</Name>
warnif count > 0 

let oldFlags = codeBase.OlderVersion().ThirdParty.Types.WithFullName("System.FlagsAttribute").SingleOrDefault()
let newFlags = ThirdParty.Types.WithFullName("System.FlagsAttribute").SingleOrDefault()
where oldFlags != null && newFlags != null

from t in Application.Types where
   t.IsEnumeration &&
   t.IsPresentInBothBuilds() 
let hasFlagsAttributeNow = t.HasAttribute(newFlags)
let usedToHaveFlagsAttribute = t.OlderVersion().HasAttribute(oldFlags) 
where hasFlagsAttributeNow != usedToHaveFlagsAttribute
select new { 
   t, 
   hasFlagsAttributeNow, 
   usedToHaveFlagsAttribute 
}

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This rule matches enumeration types that used to be tagged
// with *FlagsAttribute* in the *baseline*, and not anymore.
// It also matches the opposite, enumeration types that are now
// tagged with *FlagsAttribute*, and were not tagged in the *baseline*.
//
// Being tagged with *FlagsAttribute* is a strong property for an enumeration.
// Not so much in terms of *behavior* (only the *enum.ToString()* method
// behavior changes when an enumeration is tagged with *FlagsAttribute*)
// but in terms of *meaning*: is the enumeration a **range of values**
// or a **range of flags**?
//
// As a consequence, changing the *FlagsAttribute*s status of an enumeration can 
// have significant impact for its clients.
//</Description>

//<HowToFix>
// Make sure the *FlagsAttribute* status of each enumeration remains stable
// now, and in the future.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>API: New publicly visible types</Name>
from t in Application.Types
where t.IsPubliclyVisible && 

     // The type has been removed and its parent assembly hasn't been removed …
     ( (t.WasAdded() && !t.ParentAssembly.WasAdded()) ||

     // … or the type existed but was not publicly visible
       !t.WasAdded() && !t.OlderVersion().IsPubliclyVisible)

select new { 
   t,
   OldVisibility = 
      (t.WasAdded() ? " " : 
       t.OlderVersion().Visibility.ToString()) 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists types that are new in the public 
// surface of the analyzed assemblies.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>API: New publicly visible methods</Name>
from m in Application.Methods
where m.IsPubliclyVisible && 

     // The method has been removed and its parent assembly hasn't been removed …
     ( (m.WasAdded() && !m.ParentType.WasAdded()) ||

     // … or the method existed but was not publicly visible
       !m.WasAdded() && !m.OlderVersion().IsPubliclyVisible)

//--------------------------------------
// Handle special case: if between two versions a regular property becomes 
// an auto-property (or vice-versa) the property getter/setter method have 
// a different value for IMethod.IsGeneratedByCompiler
// since auto-property getter/setter are marked as generated by the compiler.
//
// If a method IsGeneratedByCompiler value changes between two versions, 
// NDepend doesn't pair the newer/older occurences of the method.
//
// Hence in such situation, a public method is seen as added 
// and a public method is seen as removed, but the API is not broken!
// The equivalentMethod-check below avoids reporting such 
// API Breaking Change false-positive.
let equivalentMethod = m.WasAdded() && m.ParentType.IsPresentInBothBuilds() ?
   m.ParentType.OlderVersion().Methods
   .FirstOrDefault(m1 => 
       m1.IsPubliclyVisible &&
       m1.Name == m.Name &&
       m1.IsGeneratedByCompiler != m.IsGeneratedByCompiler)
    : null
where equivalentMethod == null
//--------------------------------------

select new { 
   m,
   OldVisibility = 
      (m.WasAdded() ? " " : 
       m.OlderVersion().Visibility.ToString())
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists methods that are new in the public 
// surface of the analyzed assemblies.
//</Description>
]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>API: New publicly visible fields</Name>
from f in Application.Fields
where f.IsPubliclyVisible && 

     // The method has been removed and its parent assembly hasn'f been removed …
     ( (f.WasAdded() && !f.ParentType.WasAdded()) ||

     // … or the t existed but was not publicly visible
       !f.WasAdded() && !f.OlderVersion().IsPubliclyVisible)

select new { 
   f,
   OldVisibility = 
      (f.WasAdded() ? " " : 
       f.OlderVersion().Visibility.ToString())
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists fields that are new in the public 
// surface of the analyzed assemblies.
//</Description>]]></Query>
    </Group>
    <Group Name="Code Diff Summary" Active="True" ShownInReport="True">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>New assemblies</Name>
from a in Application.Assemblies where a.WasAdded()
select new { a, a.NbLinesOfCode }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *assemblies* that have been added since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Assemblies removed</Name>
from a in codeBase.OlderVersion().Application.Assemblies where a.WasRemoved()
select new { a, a.NbLinesOfCode }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *assemblies* that have been removed since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Assemblies where code was changed</Name>
from a in Application.Assemblies where a.CodeWasChanged()
select new { 
   a, 
   a.NbLinesOfCode, 
   oldNbLinesOfCode = a.OlderVersion().NbLinesOfCode.GetValueOrDefault() ,
   delta = (int) a.NbLinesOfCode.GetValueOrDefault() - a.OlderVersion().NbLinesOfCode.GetValueOrDefault() 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *assemblies* in which, code has been changed since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>New namespaces</Name>
from n in Application.Namespaces where 
 !n.ParentAssembly.WasAdded() &&
  n.WasAdded()
select new { n, n.NbLinesOfCode }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *namespaces* that have been added since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Namespaces removed</Name>
from n in codeBase.OlderVersion().Application.Namespaces where 
 !n.ParentAssembly.WasRemoved() &&
  n.WasRemoved()
select new { n, n.NbLinesOfCode }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *namespaces* that have been removed since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Namespaces where code was changed</Name>
from n in Application.Namespaces where n.CodeWasChanged()
select new { 
   n, 
   n.NbLinesOfCode, 
   oldNbLinesOfCode = n.OlderVersion().NbLinesOfCode.GetValueOrDefault() ,
   delta = (int) n.NbLinesOfCode.GetValueOrDefault() - n.OlderVersion().NbLinesOfCode.GetValueOrDefault() 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *namespaces* in which, code has been changed since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>New types</Name>
from t in Application.Types where 
 !t.ParentNamespace.WasAdded() &&
  t.WasAdded() &&
 !t.IsGeneratedByCompiler
select new { t, t.NbLinesOfCode }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *types* that have been added since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types removed</Name>
from t in codeBase.OlderVersion().Application.Types where 
 !t.ParentNamespace.WasRemoved() &&
  t.WasRemoved() &&
 !t.IsGeneratedByCompiler
select new { t, t.NbLinesOfCode }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *types* that have been removed since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types where code was changed</Name>

from t in Application.Types where t.CodeWasChanged() 
//select new { t, t.NbLinesOfCode }
select new { 
   t, 
   t.NbLinesOfCode, 
   oldNbLinesOfCode = t.OlderVersion().NbLinesOfCode ,
   delta = (int?) t.NbLinesOfCode - t.OlderVersion().NbLinesOfCode 
} 
//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *types* in which, code has been changed since the *baseline*.
//
// To visualize changes in code, right-click a matched type and select:
//
// • Compare older and newer versions of source file
//
// • Compare older and newer versions disassembled with Reflector
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Heuristic to find types moved from one namespace or assembly to another</Name>
let typesRemoved = codeBase.OlderVersion().Types.Where(t => t.WasRemoved())
let typesAdded = Types.Where(t => t.WasAdded())

from tMoved in typesAdded.Join(
   typesRemoved,
   t => t.Name,
   t => t.Name,
   (tNewer, tOlder) => new { tNewer, 
                             OlderParentNamespace = tOlder.ParentNamespace,
                             OlderParentAssembly = tOlder.ParentAssembly  } ) 
select tMoved

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *types* moved from one namespace or assembly to another.
// The heuristic implemented consists in making a **join LINQ query** on
// type name (without namespace prefix), applied to the two sets of types *added* 
// and types *removed*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types directly using one or several types changed</Name>
let typesChanged = Application.Types.Where(t => t.CodeWasChanged()).ToHashSet()

from t in JustMyCode.Types.UsingAny(typesChanged) where
  !t.CodeWasChanged() && 
  !t.WasAdded()
let typesChangedUsed = t.TypesUsed.Intersect(typesChanged) 
select new { t, typesChangedUsed }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists types *unchanged* since the *baseline*
// but that use directly some *types* where code has been changed 
// since the *baseline*.
//
// For such matched type, the code hasen't been changed, but still the overall
// behavior might have been changed.
//
// The query result includes types changed directly used,
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types indirectly using one or several types changed</Name>
let typesChanged = Application.Types.Where(t => t.CodeWasChanged()).ToHashSet()

// 'depth' represents a code metric defined on types using
// directly or indirectly any type where code was changed.
let depth = JustMyCode.Types.DepthOfIsUsingAny(typesChanged) 

from t in depth.DefinitionDomain where
  !t.CodeWasChanged() && 
  !t.WasAdded()

let typesChangedDirectlyUsed = t.TypesUsed.Intersect(typesChanged) 
let depthOfUsingTypesChanged = depth[t]
orderby depthOfUsingTypesChanged 

select new { 
   t, 
   depthOfUsingTypesChanged, 
   typesChangedDirectlyUsed 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists types *unchanged* since the *baseline*
// but that **use directly or indirectly** some *types* where 
// code has been changed since the *baseline*.
//
// For such matched type, the code hasen't been changed, but still the overall
// behavior might have been changed.
// 
// The query result includes types changed directly used, and the **depth of usage**
// of types indirectly used, *depth of usage* as defined in the documentation of
// *DepthOfIsUsingAny()* NDepend API method:
// http://www.ndepend.com/api/webframe.html?NDepend.API~NDepend.CodeModel.ExtensionMethodsSequenceUsage~DepthOfIsUsingAny.html
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>New methods</Name>
from m in Application.Methods where 
 !m.ParentType.WasAdded() &&
  m.WasAdded() &&
 !m.IsGeneratedByCompiler
select new { m, m.NbLinesOfCode }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *methods* that have been added since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods removed</Name>
from m in codeBase.OlderVersion().Application.Methods where 
 !m.ParentType.WasRemoved() &&
  m.WasRemoved() &&
 !m.IsGeneratedByCompiler
select new { m, m.NbLinesOfCode }

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *methods* that have been removed since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods where code was changed</Name>
from m in Application.Methods where m.CodeWasChanged()
select new { 
   m, 
   m.NbLinesOfCode, 
   oldNbLinesOfCode = m.OlderVersion().NbLinesOfCode ,
   delta = (int?) m.NbLinesOfCode - m.OlderVersion().NbLinesOfCode 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *methods* in which, code has been changed since the *baseline*.
//
// To visualize changes in code, right-click a matched method and select:
//
// • Compare older and newer versions of source file
//
// • Compare older and newer versions disassembled with Reflector
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods directly calling one or several methods changed</Name>
let methodsChanged = Application.Methods.Where(m => m.CodeWasChanged()).ToHashSet()

from m in JustMyCode.Methods.UsingAny(methodsChanged ) where
  !m.CodeWasChanged() && 
  !m.WasAdded()
let methodsChangedCalled = m.MethodsCalled.Intersect(methodsChanged) 
select new { 
   m, 
   methodsChangedCalled 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists methods *unchanged* since the *baseline*
// but that call directly some *methods* where code has been changed 
// since the *baseline*.
//
// For such matched method, the code hasen't been changed, but still the overall
// behavior might have been changed.
//
// The query result includes methods changed directly used,
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods indirectly calling one or several methods changed</Name>
let methodsChanged = Application.Methods.Where(m => m.CodeWasChanged()).ToHashSet()

// 'depth' represents a code metric defined on methods using
// directly or indirectly any method where code was changed.
let depth = JustMyCode.Methods.DepthOfIsUsingAny(methodsChanged) 

from m in depth.DefinitionDomain where
  !m.CodeWasChanged() && 
  !m.WasAdded()

let methodsChangedDirectlyUsed = m.MethodsCalled.Intersect(methodsChanged) 
let depthOfUsingMethodsChanged = depth[m]
orderby depthOfUsingMethodsChanged 

select new { 
   m, 
   depthOfUsingMethodsChanged, 
   methodsChangedDirectlyUsed 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists methods *unchanged* since the *baseline*
// but that **use directly or indirectly** some *methods* where 
// code has been changed since the *baseline*.
//
// For such matched method, the code hasen't been changed, but still the overall
// behavior might have been changed.
// 
// The query result includes methods changed directly used, and the **depth of usage**
// of methods indirectly used, *depth of usage* as defined in the documentation of
// *DepthOfIsUsingAny()* NDepend API method:
// http://www.ndepend.com/api/webframe.html?NDepend.API~NDepend.CodeModel.ExtensionMethodsSequenceUsage~DepthOfIsUsingAny.html
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>New fields</Name>
from f in Application.Fields where 
 !f.ParentType.WasAdded() &&
  f.WasAdded() &&
 !f.IsGeneratedByCompiler
select f

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *fields* that have been added since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Fields removed</Name>
from f in codeBase.OlderVersion().Application.Fields where 
 !f.ParentType.WasRemoved() &&
  f.WasRemoved() &&
 !f.IsGeneratedByCompiler
select f

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *fields* that have been removed since the *baseline*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third party types that were not used and that are now used</Name>
from t in ThirdParty.Types where t.IsUsedRecently()
select new { 
   t, 
   t.Methods, 
   t.Fields, 
   t.TypesUsingMe 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *types* defined in **third-party assemblies**, that were not 
// used at *baseline* time, and that are now used.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third party types that were used and that are not used anymore</Name>
from t in codeBase.OlderVersion().Types where t.IsNotUsedAnymore()
select new { 
   t, 
   t.Methods, 
   t.Fields, 
   TypesThatUsedMe = t.TypesUsingMe 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *types* defined in **third-party assemblies**, that were  
// used at *baseline* time, and that are not used anymore.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third party methods that were not used and that are now used</Name>
from m in ThirdParty.Methods where 
  m.IsUsedRecently() &&
 !m.ParentType.IsUsedRecently()
select new { 
   m, 
   m.MethodsCallingMe
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *methods* defined in **third-party assemblies**, that were not 
// used at *baseline* time, and that are now used.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third party methods that were used and that are not used anymore</Name>
from m in codeBase.OlderVersion().Methods where 
  m.IsNotUsedAnymore() &&
 !m.ParentType.IsNotUsedAnymore()
select new { 
   m, 
   MethodsThatCalledMe = m.MethodsCallingMe
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *methods* defined in **third-party assemblies**, that were  
// used at *baseline* time, and that are not used anymore.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third party fields that were not used and that are now used</Name>
from f in ThirdParty.Fields where 
  f.IsUsedRecently() &&
 !f.ParentType.IsUsedRecently()
select new { 
   f, 
   f.MethodsUsingMe 
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *fields* defined in **third-party assemblies**, that were not 
// used at *baseline* time, and that are now used.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third party fields that were used and that are not used anymore</Name>
from f in codeBase.OlderVersion().Fields where 
  f.IsNotUsedAnymore() &&
 !f.ParentType.IsNotUsedAnymore()
select new {
   f, 
   MethodsThatUsedMe = f.MethodsUsingMe
}

//<Description>
// This query is executed only if a *baseline for comparison* is defined (*diff mode*).
//
// This code query lists *fields* defined in **third-party assemblies**, that were  
// used at *baseline* time, and that are not used anymore.
//</Description>]]></Query>
    </Group>
    <Group Name="Test and Code Coverage" Active="True" ShownInReport="True">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>C.R.A.P method code metric</Name>

warnif count > 0
from m in JustMyCode.Methods

// Don't match too short methods
where m.NbLinesOfCode > 10

let CC = m.CyclomaticComplexity
let uncov = (100 - m.PercentageCoverage) / 100f
let CRAP = (CC * CC * uncov * uncov * uncov) + CC
where CRAP != null && CRAP > 30
orderby CRAP descending, m.NbLinesOfCode descending
select new { m, CRAP, CC, m.PercentageCoverage, m.NbLinesOfCode }

//<Description>
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// **Change Risk Analyzer and Predictor** (i.e. CRAP) is a code metric
// that helps in pinpointing overly complex and untested code.
// Is has been first defined here: 
// http://www.artima.com/weblogs/viewpost.jsp?thread=215899
//
// The Formula is:  **CRAP(m) = CC(m)^2 * (1 – cov(m)/100)^3 + CC(m)**
//
// • where *CC(m)* is the *cyclomatic complexity* of the method *m*
//
// • and *cov(m)* is the *percentage coverage* by tests of the method *m*
//
// Matched methods cumulates two highly *error prone* code smells:
//
// • A complex method, difficult to develop and maintain.
//
// • Non 100% covered code, difficult to refactor without introducing any regression bug.
//
// The highest the CRAP score, the more painful to maintain and error prone is the method.
//
// An arbitrary threshold of 30 is fixed for this code rule as suggested by inventors.
//
// Notice that no amount of testing will keep methods with a Cyclomatic Complexity
// highest than 30, out of CRAP territory.
//
// Notice that this rule doesn't match too short method
// with less than 10 lines of code.
//</Description>

//<HowToFix>
// In such situation, it is recommended to both refactor the complex method logic
// into several smaller and less complex methods 
// (that might belong to some new types especially created),
// and also write unit-tests to full cover the refactored logic. 
//
// You'll find code impossible to cover by unit-tests, like calls to *MessageBox.Show()*.
// An infrastructure must be defined to be able to *mock* such code at test-time.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Complex methods partially covered by tests should be 100% covered</Name>

warnif count > 0 from m in JustMyCode.Methods 
 where 
     // These metrics' definitions are available here: 
     // http://www.ndepend.com/docs/code-metrics#MetricsOnMethods
     (  m.NbLinesOfCode > 30 || 
        m.ILCyclomaticComplexity > 50 || 
        m.ILNestingDepth > 4 || 
        m.NbVariables > 8) && 

     // Take care only of complex methods 
     // already partially covered, but not completely covered.
     m.PercentageCoverage > 0 &&
     m.PercentageCoverage < 100

  orderby m.NbLinesOfCodeNotCovered ascending,
          m.NbLinesOfCode descending
select new { m, m.PercentageCoverage, m.NbLinesOfCode, 
             m.NbLinesOfCodeCovered, m.NbLinesOfCodeNotCovered, 
             m.ILCyclomaticComplexity, m.ILNestingDepth, m.NbVariables }

//<Description>
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// There are default rules that warn about complex methods to refactor.
// The present rule warns about complex methods that are already a bit covered by tests
// but not 100% covered by tests.
//
// Such situation cumulates two highly *error prone* code smells:
//
// • A complex method, difficult to develop and maintain.
//
// • Non 100% covered code, difficult to refactor without creating any regression bug.
//
// Because the complex method is already covered partially by tests,
// it might be not so costly to write more tests to full cover it.
//</Description>

//<HowToFix>
// In such situation, it is recommended to both:
//
// • refactor the complex method logic
// into several smaller and less complex methods 
// (that might belong to some new types especially created),
//
// • and also write more unit-tests to full cover the refactored logic. 
//
// You'll find code impossible to cover by unit-tests, like calls to *MessageBox.Show()*.
// An infrastructure must be defined to be able to *mock* such code at test-time.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Method changed poorly covered</Name>
warnif count > 0
from m in Application.Methods where 
  m.PercentageCoverage < 30 && 
  m.CodeWasChanged() 
  orderby m.NbLinesOfCode descending, 
           m.NbLinesOfCodeNotCovered ,
           m.PercentageCoverage
select new { m, m.PercentageCoverage, m.NbLinesOfCode, 
             m.NbLinesOfCodeNotCovered }  

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
// This rule operates only on methods added or refactored since the baseline.
//
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// It is important to write code mostly covered by tests 
// to achieve *maintainable* and *non-error-prone* code.
//
// In real-world, many code bases are poorly covered by tests.
// However it is not practicable to stop the development for months
// to refactor and write tests to achieve high code coverage ratio.
//
// Hence it is recommended that each time a method (or a type) gets refactored,
// the developer takes the time to write associated unit-tests to cover it.
//
// Doing so will help to increase significantly the maintainability of the code base.
// You'll notice that quickly, refactoring will also be driven by testability, 
// and as a consequence, the overall code structure and design will increase as well.
//</Description>

//<HowToFix>
// Write unit-tests to cover the code of most methods and classes refactored.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Method added poorly covered</Name>
warnif count > 0
from m in Application.Methods where
  m.NbLinesOfCode > 0 &&
  m.PercentageCoverage < 30 && 
  m.WasAdded() 
  orderby m.NbLinesOfCode descending, 
           m.NbLinesOfCodeNotCovered ,
           m.PercentageCoverage
select new { m, m.PercentageCoverage, m.NbLinesOfCode, 
             m.NbLinesOfCodeNotCovered }

//<Description>
// This rule is executed only if a *baseline for comparison* is defined (*diff mode*).
// This rule operates only on methods added or refactored since the baseline.
//
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// It is important to write code mostly covered by tests 
// to achieve *maintainable* and *non-error-prone* code.
//
// In real-world, many code bases are poorly covered by tests.
// However it is not practicable to stop the development for months
// to refactor and write tests to achieve high code coverage ratio.
//
// Hence it is recommended that each time a method (or a type) gets added,
// the developer takes the time to write associated unit-tests to cover it.
//
// Doing so will help to increase significantly the maintainability of the code base.
// You'll notice that quickly, refactoring will also be driven by testability, 
// and as a consequence, the overall code structure and design will increase as well.
//</Description>

//<HowToFix>
// Write unit-tests to cover the code of most methods and classes added.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types 95% to 99% covered</Name>
warnif count > 0
from t in Application.Types where 
  t.PercentageCoverage >= 95 && 
  t.PercentageCoverage <= 99 &&
 !t.IsGeneratedByCompiler

  let methodsCulprit = t.Methods.Where(m => m.PercentageCoverage < 100)

  orderby t.NbLinesOfCode descending , 
           t.NbLinesOfCodeNotCovered ,
           t.PercentageCoverage
select new { t, t.PercentageCoverage, t.NbLinesOfCode, 
             t.NbLinesOfCodeNotCovered, methodsCulprit } 

//<Description>
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// Often covering the few percents of remaining uncovered code of a class, 
// requires as much work as covering the first 90%.
// For this reason, often teams estimate that 90% coverage is enough.
// However *untestable code* usually means *poorly written code* 
// which usually leads to *error prone code*.
// So it might be worth refactoring and making sure to cover the few uncovered lines of code
// **because most tricky bugs might come from this small portion of hard-to-test code**.
//
// Not all classes should be 100% covered by tests (like UI code can be hard to test)
// but you should make sure that most of the logic of your application
// is defined in some *easy-to-test classes*, 100% covered by tests.
//</Description>

//<HowToFix>
// Write more unit-tests dedicated to cover code not covered yet.
// If you find some *hard-to-test code*, it is certainly a sign that this code
// is not *well designed* and hence, needs refactoring.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Namespaces 95% to 99% covered</Name>
warnif count > 0
from n in Application.Namespaces where 
  n.PercentageCoverage >= 95 && 
  n.PercentageCoverage <= 99 

  let methodsCulprit = n.ChildMethods.Where(m => m.PercentageCoverage < 100)

  orderby n.NbLinesOfCode descending , 
           n.NbLinesOfCodeNotCovered ,
           n.PercentageCoverage
select new { n, n.PercentageCoverage, n.NbLinesOfCode, 
             n.NbLinesOfCodeNotCovered, methodsCulprit  } 

//<Description>
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// Often covering the few percents of remaining uncovered code of 
// one or several classes in a namespace
// requires as much work as covering the first 90%.
// For this reason, often teams estimate that 90% coverage is enough.
// However *untestable code* usually means *poorly written code* 
// which usually leads to *error prone code*.
// So it might be worth refactoring and making sure to cover the few uncovered lines of code
// **because most tricky bugs might come from this small portion of hard-to-test code**.
//
// Not all classes should be 100% covered by tests (like UI code can be hard to test)
// but you should make sure that most of the logic of your application
// is defined in some *easy-to-test classes*, 100% covered by tests.
//</Description>

//<HowToFix>
// Write more unit-tests dedicated to cover code not covered yet in the namespace.
// If you find some *hard-to-test code*, it is certainly a sign that this code
// is not *well designed* and hence, needs refactoring.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types tagged with FullCoveredAttribute should be 100% covered</Name>
warnif count > 0 
from t in Application.Types where
  t.HasAttribute ("NDepend.Attributes.FullCoveredAttribute".AllowNoMatch()) &&
  t.PercentageCoverage < 100

let notFullCoveredMethods = t.Methods.Where(
                               m =>  m.NbLinesOfCode> 0 && 
                                     m.PercentageCoverage < 100 &&
                                    !m.HasAttribute("NDepend.Attributes.UncoverableByTestAttribute".AllowNoMatch()))

orderby t.NbLinesOfCodeNotCovered descending 

select new { t, t.PercentageCoverage, t.NbLinesOfCodeNotCovered, notFullCoveredMethods,
                t.NbLinesOfCode, t.NbLinesOfCodeCovered }

//<Description>
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// By using a **FullCoveredAttribute**, you can express in source code the intention
// that a class is 100% covered by tests, and should remain 100% covered in the future.
// If you don't want to link *NDepend.API.dll*, 
// you can use your own attribute and adapt the source code of this rule.
//
// Benefits of using a **FullCoveredAttribute** are twofold:
// Not only the intention is expressed in source code,
// but it is also continuously checked by the present rule.
//
// Often covering 10% of remaining uncovered code of a class, 
// requires as much work as covering the first 90%.
// For this reason, often teams estimate that 90% coverage is enough.
// However *untestable code* usually means *poorly written code* which usually means *error prone code*.
// So it might be worth refactoring and making sure to cover the 10% remaining code
// **because most tricky bugs might come from this small portion of hard-to-test code**.
//
// Not all classes should be 100% covered by tests (like UI code can be hard to test)
// but you should make sure that most of the logic of your application
// is defined in some *easy-to-test classes*, 100% covered by tests.
//</Description>

//<HowToFix>
// Write more unit-tests dedicated to cover code of matched classes not covered yet.
// If you find some *hard-to-test code*, it is certainly a sign that this code
// is not *well designed* and hence, needs refactoring.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types 100% covered should be tagged with FullCoveredAttribute</Name>
        
warnif count > 0 from t in JustMyCode.Types where
 !t.HasAttribute ("NDepend.Attributes.FullCoveredAttribute".AllowNoMatch()) &&
  t.PercentageCoverage == 100 &&
 !t.IsGeneratedByCompiler
select new { t, t.NbLinesOfCode }

//<Description>
// This rule is executed only if some code coverage data is imported
// from some code coverage files.
//
// By using a **FullCoveredAttribute**, you can express in source code the intention
// that a class is 100% covered by tests, and should remain 100% covered in the future.
//
// Benefits of using a **FullCoveredAttribute** are twofold:
// Not only the intention is expressed in source code,
// but it is also continuously checked by the present rule.
//</Description>

//<HowToFix>
// Just tag types 100% covered by tests with the **FullCoveredAttribute**
// that can be found in *NDepend.API.dll*,
// or by an attribute of yours defined in your own code 
// (in which case this rule must be adapted).
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types not covered at all</Name>
from t in Application.Types where 
  t.PercentageCoverage == 0
  orderby t.NbLinesOfCode descending
select new { t, t.NbLinesOfCode }

//<Description>
// This query is executed only if some code coverage data is imported
// from some code coverage files.
//
// This code query lists types not covered at all by any test.
//
// Often, when code is not covered at all by test, one can reach
// decent coverage ratio (like 50% to 90%) just by writing a few tests.
//
// The idea is not to cover code for the sake of it.
// The idea is that thanks to a small effort of writing a few tests,
// one can continuously check, that a significant portion of code 
// runs without a problem. 
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Namespaces not covered at all</Name>
from n in Application.Namespaces where 
  n.PercentageCoverage == 0
  orderby n.NbLinesOfCode descending
select new { n, n.NbLinesOfCode} 

//<Description>
// This query is executed only if some code coverage data is imported
// from some code coverage files.
//
// This code query lists namespaces not covered at all by any test.
//
// Often, when code is not covered at all by test, one can reach
// decent coverage ratio (like 50% to 90%) just by writing a few tests.
//
// The idea is not to cover code for the sake of it.
// The idea is that thanks to a small effort of writing a few tests,
// one can continuously check, that a significant portion of code 
// runs without a problem. 
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Test Methods</Name>

let testAttr = ThirdParty.Types.WithNameIn("TestAttribute", "TestCaseAttribute")
let testMethods = Methods.TaggedWithAnyAttributes(testAttr)
from m in testMethods 
select m

//<Description>
// We advise to not include test assemblies in code analyzed by NDepend.
// We estimate that it is acceptable and practical to lower the quality gate of test code,
// because the important measures for tests are:
//
// • The coverage ratio, 
//
// • And the amount of logic results asserted: This includes both
// assertions in test code, and assertions in code covered by tests, 
// like *Code Contract* assertions and *Debug.Assert(…)* assertions.
//
// But if you wish to enforce the quality of test code, you'll need to 
// consider test assemblies in your list of application assemblies 
// analyzed by NDepend.
//
// In such situation, this code query lists tests methods and you can 
// reuse this code in custom rules.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods directly called by test Methods</Name>

let testAttr = ThirdParty.Types.WithNameIn("TestAttribute", "TestCaseAttribute")
let testMethods = Methods.TaggedWithAnyAttributes(testAttr).ToHashSet()

// --- Uncomment this line if your test methods are in dedicated test assemblies ---
//let testAssemblies = testMethods.ParentAssemblies().ToHashSet()

from m in Application.Methods.UsedByAny(testMethods)

// --- Uncomment this line if your test methods are in dedicated test assemblies ---
//where !testAssemblies.Contains(m.ParentAssembly)

select new { m , 
             calledByTests = m.MethodsCallingMe.Intersect(testMethods ),
             // --- Uncomment this line if your project import some coverage data ---
             // m.PercentageCoverage 
}


//<Description>
// This query lists all methods directly called by tests methods.
// Overrides of virtual and abstract methods, called through polymorphism, are not listed.
// Methods solely invoked through a delegate are not listed.
// Methods solely invoked through reflection are not listed.
//
// We advise to not include test assemblies in code analyzed by NDepend.
// We estimate that it is acceptable and practical to lower the quality gate of test code,
// because the important measures for tests are:
//
// • The coverage ratio, 
//
// • And the amount of logic results asserted: This includes both
// assertions in test code, and assertions in code covered by tests, 
// like *Code Contract* assertions and *Debug.Assert(…)* assertions.
//
// But if you wish to run this code query,
// you'll need to consider test assemblies in your list of 
// application assemblies analyzed by NDepend.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods directly and indirectly called by test Methods</Name>

let testAttr = from t in ThirdParty.Types.WithNameIn("TestAttribute", "TestCaseAttribute") select t
let testMethods = Methods.TaggedWithAnyAttributes(testAttr)

// --- Uncomment this line if your test methods are in dedicated test assemblies ---
// let testAssemblies = testMethods.ParentAssemblies().ToHashSet()

let depthOfCalledByTest = Application.Methods.DepthOfIsUsedByAny(testMethods)
from pair in depthOfCalledByTest
where pair.Value > 0 
orderby pair.Value ascending
// --- Uncomment this line if your test methods are in dedicated test assemblies ---
//&& !testAssemblies.Contains(pair.CodeElement.ParentAssembly)

select new { 
  method = pair.CodeElement, 
  // (depthOfCalledByTests == 1) means that the method is directly called by tests
  // (depthOfCalledByTests == 2) means that the method is directly called by a method directly called by tests
  // …
  depthOfCalledByTests = pair.Value,
  nbLinesOfCode = pair.CodeElement.NbLinesOfCode,
  // --- Uncomment this line if your project import some coverage data ---
  // m.PercentageCoverage
}

//<Description>
// This query lists all methods *directly or indirectly* called by tests methods.
// *Indirectly* called by a test means that a test method calls a method, that calls a method…
// From this recursion, a code metric named *depthOfCalledByTests* is inferred,
// The value *1* means directly called by test,
// the value *2* means called by a method that is called by a test…
//
// Overrides of virtual and abstract methods, called through polymorphism, are not listed.
// Methods solely invoked through a delegate are not listed.
// Methods solely invoked through reflection are not listed.
//
// We advise to not include test assemblies in code analyzed by NDepend.
// We estimate that it is acceptable and practical to lower the quality gate of test code,
// because the important measures for tests are:
//
// • The coverage ratio, 
//
// • And the amount of logic results asserted: This includes both
// assertions in test code, and assertions in code covered by tests, 
// like *Code Contract* assertions and *Debug.Assert(…)* assertions.
//
// But if you wish to run this code query,
// you'll need to consider test assemblies in your list of 
// application assemblies analyzed by NDepend.
//</Description>]]></Query>
    </Group>
    <Group Name="Dead Code" Active="True" ShownInReport="True">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Potentially dead Types</Name>
        
warnif count > 0
// Filter procedure for types that should'nt be considered as dead
let canTypeBeConsideredAsDeadProc = new Func<IType, bool>(
   t => !t.IsPublic && //   Public types might be used by client applications of your assemblies.
         t.Name != "Program" && 
        !t.IsGeneratedByCompiler &&

         // If you don't want to link NDepend.API.dll, you can use your own IsNotDeadCodeAttribute 
         // and adapt the source code of this rule.
        !t.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) &&

         // Exclude static types that define only const fields
         // because they cannot be seen as used in IL code.
        !(t.IsStatic && t.NbMethods == 0 && !t.Fields.Where(f => !f.IsLiteral).Any()))

// Select types unused
let typesUnused = 
   from t in JustMyCode.Types where
   t.NbTypesUsingMe == 0 && canTypeBeConsideredAsDeadProc(t)
   select t

// Dead types = types used only by unused types (recursive)
let deadTypesMetric = typesUnused.FillIterative(
types => from t in codeBase.Application.Types.UsedByAny(types).Except(types)
         where canTypeBeConsideredAsDeadProc(t) &&
               t.TypesUsingMe.Intersect(types).Count() == t.NbTypesUsingMe
         select t)

from t in deadTypesMetric.DefinitionDomain
select new { 
  t, 
  depth = deadTypesMetric[t],
  t.TypesUsingMe  
}

//<Description>
// This rule lists *potentially* **dead types**.
// A dead type is a type that can be removed
// because it is never used by the program.
//
// This rule lists not only types not used anywhere in code,
// but also types used only by types not used anywhere in code.
// This is why this rule comes with a column *TypesusingMe* and
// this is why there is a code metric named *depth*:
//
// • A *depth* value of *0* means the type is not used.
//
// • A *depth* value of *1* means the type is used only by types not used.
//
// • etc…
//
// By reading the source code of this rule, you'll see that by default,
// *public* types are not matched, because such type might not be used
// by the analyzed code, but still be used by client code, not analyzed by NDepend.
// This default behavior can be easily changed.
//</Description>

//<HowToFix>
// *Static analysis* cannot provide an *exact* list of dead types,
// because there are several ways to use a type *dynamically* (like through reflection).
//
// For each type matched by this query, first investigate if the type is used somehow
// (like through reflection).
// If the type is really never used, it is important to remove it 
// to avoid maintaining useless code.
// If you estimate the code of the type might be used in the future, 
// at least comment it, and provide an explanatory comment about the future intentions.
//
// If a type is used somehow,
// but still is matched by this rule, you can tag it with the attribute 
// **IsNotDeadCodeAttribute** found in *NDepend.API.dll* to avoid matching the type again.
// You can also provide your own attribute for this need, 
// but then you'll need to adapt this code rule.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Potentially dead Methods</Name>
        
warnif count > 0
// Filter procedure for methods that should'nt be considered as dead
let canMethodBeConsideredAsDeadProc = new Func<IMethod, bool>(
    m => !m.IsPubliclyVisible &&       // Public methods might be used by client applications of your assemblies.
         !m.IsEntryPoint &&            // Main() method is not used by-design.
         !m.IsExplicitInterfaceImpl && // The IL code never explicitly calls explicit interface methods implementation.
         !m.IsClassConstructor &&      // The IL code never explicitly calls class constructors.
         !m.IsFinalizer &&             // The IL code never explicitly calls finalizers.
         !m.IsVirtual &&               // Only check for non virtual method that are not seen as used in IL.
         !(m.IsConstructor &&          // Don't take account of protected ctor that might be call by a derived ctors.
           m.IsProtected) &&
         !m.IsEventAdder &&            // The IL code never explicitly calls events adder/remover.
         !m.IsEventRemover &&
         !m.IsGeneratedByCompiler &&
         !m.ParentType.IsDelegate &&

         // Methods tagged with these two attributes are called by the serialization infrastructure.
         !m.HasAttribute("System.Runtime.Serialization.OnSerializingAttribute".AllowNoMatch()) &&
         !m.HasAttribute("System.Runtime.Serialization.OnDeserializedAttribute".AllowNoMatch()) &&

         // If you don't want to link NDepend.API.dll, you can use your own IsNotDeadCodeAttribute 
         // and adapt the source code of this rule.
         !m.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()))

// Get methods unused
let methodsUnused = 
   from m in JustMyCode.Methods where 
   m.NbMethodsCallingMe == 0 && 
   canMethodBeConsideredAsDeadProc(m)
   select m

// Dead methods = methods used only by unused methods (recursive)
let deadMethodsMetric = methodsUnused.FillIterative(
   methods => // Unique loop, just to let a chance to build the hashset.
              from o in (new object()).ToEnumerable()
              // Use a hashet to make Intersect calls much faster!
              let hashset = methods.ToHashSet()
              from m in codeBase.Application.Methods.UsedByAny(methods).Except(methods)
              where canMethodBeConsideredAsDeadProc(m) &&
                    // Select methods called only by methods already considered as dead
                    hashset.Intersect(m.MethodsCallingMe).Count() == m.NbMethodsCallingMe
              select m)

from m in JustMyCode.Methods.Intersect(deadMethodsMetric.DefinitionDomain)
select new { 
  m,
  depth = deadMethodsMetric[m],
  m.MethodsCallingMe 
}
      
//<Description>
// This rule lists *potentially* **dead methods**.
// A dead method is a method that can be removed
// because it is never called by the program.
//
// This rule lists not only methods not called anywhere in code,
// but also methods called only by methods not called anywhere in code.
// This is why this rule comes with a column *MethodsCallingMe* and
// this is why there is a code metric named *depth*:
//
// • A *depth* value of *0* means the method is not called.
//
// • A *depth* value of *1* means the method is called only by methods not called.
//
// • etc…
//
// By reading the source code of this rule, you'll see that by default,
// *public* methods are not matched, because such method might not be called
// by the analyzed code, but still be called by client code, not analyzed by NDepend.
// This default behavior can be easily changed.
//</Description>

//<HowToFix>
// *Static analysis* cannot provide an *exact* list of dead methods,
// because there are several ways to invoke a method *dynamically* (like through reflection).
//
// For each method matched by this query, first investigate if the method is invoked somehow
// (like through reflection).
// If the method is really never invoked, it is important to remove it 
// to avoid maintaining useless code.
// If you estimate the code of the method might be used in the future, 
// at least comment it, and provide an explanatory comment about the future intentions.
//
// If a method is invoked somehow,
// but still is matched by this rule, you can tag it with the attribute 
// **IsNotDeadCodeAttribute** found in *NDepend.API.dll* to avoid matching the method again.
// You can also provide your own attribute for this need, 
// but then you'll need to adapt this code rule.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Potentially dead Fields</Name>
warnif count > 0
from f in JustMyCode.Fields where
   f.NbMethodsUsingMe == 0 && 
   !f.IsPublic &&     // Although not recommended, public fields might be used by client applications of your assemblies.
   !f.IsLiteral &&    // The IL code never explicitly uses literal fields.
   !f.IsEnumValue &&  // The IL code never explicitly uses enumeration value.
    f.Name != "value__"  && // Field named 'value__' are relative to enumerations and the IL code never explicitly uses them.
   !f.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) &&
   !f.IsGeneratedByCompiler
   // If you don't want to link NDepend.API.dll, you can use your own IsNotDeadCodeAttribute
   // and adapt the source code of this rule.
select f

//<Description>
// This rule lists *potentially* **dead fields**.
// A dead field is a field that can be removed
// because it is never used by the program.
//
// By reading the source code of this rule, you'll see that by default,
// *public* fields are not matched, because such field might not be used
// by the analyzed code, but still be used by client code, not analyzed by NDepend.
// This default behavior can be easily changed.
// Some others default rules in the *Visibility* group, warn about public fields. 
//
// More restrictions are applied by this rule because of some *by-design* limitations.
// NDepend mostly analyzes compiled IL code, and the information that
// an enumeration value or a literal constant (which are fields) is used
// is lost in IL code. Hence by default this rule won't match such field.
//</Description>

//<HowToFix>
// *Static analysis* cannot provide an *exact* list of dead fields,
// because there are several ways to assign or read a field *dynamically* 
// (like through reflection).
//
// For each field matched by this query, first investigate 
// if the field is used somehow (like through reflection).
// If the field is really never used, it is important to remove it 
// to avoid maintaining a useless code element.
//
// If a field is used somehow,
// but still is matched by this rule, you can tag it with the attribute 
// **IsNotDeadCodeAttribute** found in *NDepend.API.dll* 
// to avoid matching the field again.
// You can also provide your own attribute for this need, 
// but then you'll need to adapt this code rule.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Wrong usage of IsNotDeadCodeAttribute</Name>

warnif count == 1

let tAttr = Types.WithFullName("NDepend.Attributes.IsNotDeadCodeAttribute").FirstOrDefault()
where tAttr != null

// Get types that do a wrong usage of IsNotDeadCodeAttribute
let types = from t in Application.Types where 
   t.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) &&

   ( // types used don't need to be tagged with IsNotDeadCodeAttribute!
     t.TypesUsingMe.Count(t1 => 
        !t.NestedTypes.Contains(t1) && 
        !t1.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) ) > 0  ||
   
     // Static types that define only const fields cannot be seen as used in IL code.
     // They don't need to be tagged with IsNotDeadCodeAttribute.
     (t.IsStatic && t.NbMethods == 0 && !t.Fields.Where(f => !f.IsLiteral).Any())
   )
   select t

// Get methods that do a wrong usage of IsNotDeadCodeAttribute
let methods = from m in Application.Methods where 
   m.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) &&
   m.MethodsCallingMe.Count(m1 => !m1.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch())) > 0
   select m

// Get fields that do a wrong usage of IsNotDeadCodeAttribute
let fields = from f in Application.Fields where 
   f.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) &&
   f.MethodsUsingMe.Count(m1 => !m1.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch())) > 0
   select f

where types.Count() > 0 || methods.Count() > 0 || fields.Count() > 0
select new { tAttr, types , methods, fields }

//<Description>
// The attribute **NDepend.Attributes.IsNotDeadCodeAttribute**
// is defined in *NDepend.API.dll*. This attribute is used
// to mean that a code element is not used directly, but is used 
// somehow, like through reflection.
//
// This attribute is used in the dead code rules,
// *Potentially dead Types*, *Potentially dead Methods* 
// and *Potentially dead Fields*. 
// If you don't want to link *NDepend.API.dll*, you can use 
// your own *IsNotDeadCodeAttribute* and adapt the source code of
// this rule, and the source code of the *dead code* rules.
//
// In this context, this code rule matches code elements 
// (types, methods, fields) that are tagged with this attribute,
// but still used directly somewhere in the code.
//</Description>

//<HowToFix>
// Just remove *IsNotDeadCodeAttribute* tagging of
// types, methods and fields matched by this rule
// because this tag is not useful anymore.
//</HowToFix>]]></Query>
    </Group>
    <Group Name="Visibility" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods that could have a lower visibility</Name>
warnif count > 0 from m in JustMyCode.Methods where 
  m.Visibility != m.OptimalVisibility &&
  !m.HasAttribute("NDepend.Attributes.CannotDecreaseVisibilityAttribute".AllowNoMatch()) &&
  !m.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) &&
  // If you don't want to link NDepend.API.dll, you can use your own attributes 
  // and adapt the source code of this rule.
  
  // Eliminate default constructor from the result.
  // Whatever the visibility of the declaring class,
  // default constructors are public and introduce noise
  // in the current rule.
  !( m.IsConstructor && m.IsPublic && m.NbParameters == 0) &&

  // Don't decrease the visibility of Main() methods.
  !m.IsEntryPoint

select new { 
   m, 
   m.Visibility , 
   CouldBeDeclared = m.OptimalVisibility,
   m.MethodsCallingMe 
}

//<Description>
// This rule warns about methods that can be declared with a lower visibility
// without provoking any compilation error.
// For example *private* is a visibility lower than *internal* 
// which is lower than *public*.
//
// **Narrowing visibility** is a good practice because doing so **promotes encapsulation**.
// The scope from which methods can be called is then reduced to a minimum. 
//
// Notice that methods tagged with one of the attribute
// *NDepend.Attributes.CannotDecreaseVisibilityAttribute* or
// *NDepend.Attributes.IsNotDeadCodeAttribute*, found in *NDepend.API.dll*
// are not matched. If you don't want to link *NDepend.API.dll* but still
// wish to rely on this facility, you can declare these attributes in your code.
//</Description>

//<HowToFix>
// Declare each matched method with the specified *optimal visibility*
// in the *CouldBeDeclared* rule result column.
//
// By default, this rule matches *public methods*. If you are publishing an API
// many public methods matched should remain public. In such situation,
// you can opt for the *coarse solution* to this problem by adding in the 
// rule source code *&& !m.IsPubliclyVisible* or you can prefer the 
// *finer solution* by tagging each concerned method with 
// *CannotDecreaseVisibilityAttribute*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types that could have a lower visibility</Name>
warnif count > 0 from t in JustMyCode.Types where 

  t.Visibility != t.OptimalVisibility &&

  // If you don't want to link NDepend.API.dll, you can use your own attributes
  // and adapt the source code of this rule.
  !t.HasAttribute("NDepend.Attributes.CannotDecreaseVisibilityAttribute".AllowNoMatch()) &&
  !t.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) &&

  // XML serialized type must remain public.
  !t.HasAttribute("System.Xml.Serialization.XmlRootAttribute".AllowNoMatch()) &&

  // Static types that define only const fields cannot be seen as used in IL code.
  // They don't have to be tagged with CannotDecreaseVisibilityAttribute.
  !( t.IsStatic && 
    !t.Methods.Any(m => !m.IsClassConstructor) && 
    !t.Fields.Any(f => !f.IsLiteral && !(f.IsStatic && f.IsInitOnly))) &&

  // A type used by an interface that has the same visibility
  // cannot have its visibility decreased, else a compilation error occurs!
  !t.TypesUsingMe.Any(tUser => 
        tUser.IsInterface && 
        tUser.Visibility == t.Visibility) &&

  // Don't change the visibility of a type that contain an entry point method.
  !t.Methods.Any(m =>m.IsEntryPoint)

select new { 
   t, 
   t.Visibility , 
   CouldBeDeclared = t.OptimalVisibility, 
   t.TypesUsingMe
}

//<Description>
// This rule warns about types that can be declared with a lower visibility
// without provoking any compilation error.
// For example *private* is a visibility lower than *internal* 
// which is lower than *public*.
//
// **Narrowing visibility** is a good practice because doing so **promotes encapsulation**.
// The scope from which types can be consumed is then reduced to a minimum. 
//
// Notice that types tagged with one of the attribute
// *NDepend.Attributes.CannotDecreaseVisibilityAttribute* or
// *NDepend.Attributes.IsNotDeadCodeAttribute*, found in *NDepend.API.dll*
// are not matched. If you don't want to link *NDepend.API.dll* but still
// wish to rely on this facility, you can declare these attributes in your code.
//</Description>

//<HowToFix>
// Declare each matched type with the specified *optimal visibility*
// in the *CouldBeDeclared* rule result column.
//
// By default, this rule matches *public types*. If you are publishing an API
// many public types matched should remain public. In such situation,
// you can opt for the *coarse solution* to this problem by adding in the 
// rule source code *&& !m.IsPubliclyVisible* or you can prefer the 
// *finer solution* by tagging each concerned type with 
// *CannotDecreaseVisibilityAttribute*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Fields that could have a lower visibility</Name>
warnif count > 0 from f in JustMyCode.Fields where 
  f.Visibility != f.OptimalVisibility &&
 !f.HasAttribute("NDepend.Attributes.CannotDecreaseVisibilityAttribute".AllowNoMatch()) &&
 !f.HasAttribute("NDepend.Attributes.IsNotDeadCodeAttribute".AllowNoMatch()) &&
  // If you don't want to link NDepend.API.dll, you can use your own attributes
  // and adapt the source code of this rule.
  
  // XML serialized fields must remain public.
 !f.HasAttribute("System.Xml.Serialization.XmlElementAttribute".AllowNoMatch()) && 
 !f.HasAttribute("System.Xml.Serialization.XmlAttributeAttribute".AllowNoMatch()) 
  
select new { 
   f, 
   f.Visibility , 
   CouldBeDeclared = f.OptimalVisibility,
   f.MethodsUsingMe
}

//<Description>
// This rule warns about fields that can be declared with a lower visibility
// without provoking any compilation error.
// For example *private* is a visibility lower than *internal* 
// which is lower than *public*.
//
// **Narrowing visibility** is a good practice because doing so **promotes encapsulation**.
// The scope from which fields can be consumed is then reduced to a minimum. 
//
// Notice that fields tagged with one of the attribute
// *NDepend.Attributes.CannotDecreaseVisibilityAttribute* or
// *NDepend.Attributes.IsNotDeadCodeAttribute*, found in *NDepend.API.dll*
// are not matched. If you don't want to link *NDepend.API.dll* but still
// wish to rely on this facility, you can declare these attributes in your code.
//</Description>

//<HowToFix>
// Declare each matched field with the specified *optimal visibility*
// in the *CouldBeDeclared* rule result column.
//
// By default, this rule matches *public fields*. If you are publishing an API
// some public fields matched should remain public. In such situation,
// you can opt for the *coarse solution* to this problem by adding in the 
// rule source code *&& !m.IsPubliclyVisible* or you can prefer the 
// *finer solution* by tagging eah concerned field with 
// *CannotDecreaseVisibilityAttribute*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types that could be declared as private, nested in a parent type</Name>

warnif count > 0 
from t in Application.Types
where !t.IsGeneratedByCompiler &&
      !t.IsNested &&
      !t.IsPubliclyVisible &&
      !t.IsEnumeration &&
       // Only one type user…
       t.TypesUsingMe.Count() == 1 
let couldBeNestedIn = t.TypesUsingMe.Single()
where !couldBeNestedIn.IsGeneratedByCompiler &&
       // …declared in the same namespace
       couldBeNestedIn.ParentNamespace == t.ParentNamespace
select new { 
   t, 
   couldBeNestedIn 
}

//<Description>
// This rule matches types that can be potentially 
// *nested* and declared *private* into another type.
//
// The conditions for a type to be potentially nested 
// into a *parent type* are:
//
// • the *parent type* is the only type consuming it,
//
// • the type and the *parent type* are declared in the same namespace.
//
// Declaring a type as private into a parent type **promotes encapsulation**.
// The scope from which the type can be consumed is then reduced to a minimum. 
//</Description>

//<HowToFix>
// Nest each matched *type* into the specified *parent type* and
// declare it as private.
//
// However *nested private types* are hardly testable. Hence this rule  
// might not be applied to types consumed directly by tests.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid publicly visible constant fields</Name>
warnif count > 0 
from f in Application.Fields
where f.IsLiteral && 
      f.IsPubliclyVisible && 
     !f.IsEnumValue
select f

//<Description>
// This rule warns about constant fields that are visible outside their 
// parent assembly. Such field, when used from outside its parent assembly,
// has its constant value *hard-coded* into the client assembly.
// Hence, when changing the field's value, it is *mandatory* to recompile 
// all assemblies that consume the field, else the program will run
// with different constant values in-memory. Certainly in such situation
// bugs are lurking.
//</Description>

//<HowToFix>
// Declare matched fields as **static readonly** instead of **constant**. 
// This way, the field value is *safely changeable* without the need to 
// recompile client assemblies.
//
// Notice that enumeration value fields suffer from the same *potential
// pitfall*. But enumeration values cannot be declared as 
// *static readonly* hence the rule comes with the condition
// **&& !f.IsEnumValue** to avoid matching these. Unless you decide
// to banish public enumerations, just let the rule *as is*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Fields should be declared as private</Name>
warnif count > 0 from f in Application.Fields where 
 !f.IsPrivate && 

 // These conditions filter cases where fields 
 // doesn't represent state that should be encapsulated. 
 !f.IsGeneratedByCompiler && 
 !f.IsSpecialName && 
 !f.IsInitOnly && 
 !f.IsLiteral && 
 !f.IsEnumValue

// A non-private field assigned from outside its class,
// usually leads to complicated field state management.
let outsideMethodsAssigningMe = 
   f.MethodsAssigningMe.Where(m => m.ParentType != f.ParentType)

select new { 
   f, 
   f.Visibility, 
   outsideMethodsAssigningMe 
}

//<Description>
// This rule matches **non-private and mutable fields**.
// *Mutable* means that the field value can be modified.
// Typically mutable fields are *non-constant*, 
// *non-readonly* fields.
//
// Fields should be considered as **implementation details**
// and as a consequence they should be declared as private.
//
// If something goes wrong with a *non-private field*, 
// the culprit can be anywhere, and so in order to track down 
// the bug, you may have to look at quite a lot of code.
//
// A private field, by contrast, can only be assigned from 
// inside the same class, so if something goes wrong with that, 
// there is usually only one source file to look at. 
//</Description>

//<HowToFix>
// Declare a matched mutable field as *private*, or declare it 
// as *readonly*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[//<Name>Constructors of abstract classes should be declared as protected or private</Name>
warnif count > 0
from t in Application.Types where 
  t.IsClass && 
  t.IsAbstract
let ctors = t.Constructors.Where(c => !c.IsProtected && !c.IsPrivate)
where ctors.Count() > 0
select new { t, ctors }

//<Description>
// Constructors of abstract classes can only be called from derived 
// classes.
// 
// Because a public constructor is creating instances of its class, 
// and it is forbidden to create instances of an *abstract* type, 
// as a consequence an abstract class with a public constructor is 
// wrong design.
//</Description>

//<HowToFix>
// To fix a violation of this rule, 
// either declare the constructor as *protected*, 
// or do not declare the type as *abstract*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[//<Name>Avoid public methods not publicly visible</Name>

warnif count > 0
from m in JustMyCode.Methods where 
   !m.IsPubliclyVisible && m.IsPublic &&

   // Eliminate virtual methods
   !m.IsVirtual &&
   // Eliminate interface and delegate types
   !m.ParentType.IsInterface &&
   !m.ParentType.IsDelegate &&
   // Eliminate default constructors
   !(m.IsConstructor && m.NbParameters == 0) &&
   // Eliminate operators that must be declared public
   !m.IsOperator &&
   // Eliminate methods generated by compiler
   !m.IsGeneratedByCompiler 

let calledOutsideParentType = 
    m.MethodsCallingMe.FirstOrDefault(mCaller => mCaller.ParentType != m.ParentType) != null

select new { 
  m, 
  parentTypeVisibility = m.ParentType.Visibility,
  declareMethodAs = (Visibility) (calledOutsideParentType ? Visibility.Internal : Visibility.Private),
  methodsCaller = m.MethodsCallingMe 
}

//<Description>
// This rule warns about methods declared as *public*
// whose parent type is not declared as *public*.
//
// In such situation *public* means, *can be accessed
// from anywhere my parent type is visible*. Some 
// developers think this is an elegant language construct, 
// some others find it misleading.
//
// This rule can be deactivated if you don't agree with it.
// Read the whole debate here:
// http://ericlippert.com/2014/09/15/internal-or-public/
//</Description>

//<HowToFix>
// Declare the method as *internal* if it is used outside of 
// its type, else declare it as *private*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods that should be declared as 'public' in C#, 'Public' in VB.NET</Name>
from m in Application.Methods where 
  m.ShouldBePublic
let usedInAssemblies = m.MethodsCallingMe.ParentAssemblies().Except(m.ParentAssembly)
select new { m, m.ParentAssembly,  usedInAssemblies, m.MethodsCallingMe }

//<Description>
// This code query lists methods that *should* be declared
// as *public*. Such method is actually declared as *internal*
// and is consumed from outside its parent assembly
// thanks to the attribute 
// *System.Runtime.CompilerServices.InternalsVisibleToAttribute*.
//
// This query relies on the property
// *NDepend.CodeModel.IMember.ShouldBePublic*
// http://www.ndepend.com/api/webframe.html?NDepend.API~NDepend.CodeModel.IMember~ShouldBePublic.html 
//
// This is just a code query, it is not intended to advise
// you to declare the method as *public*, but to inform you
// that the code actually relies on the peculiar behavior
// of the attribute *InternalsVisibleToAttribute*.
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Wrong usage of CannotDecreaseVisibilityAttribute</Name>
warnif count == 1

let tAttr = Types.WithFullName("NDepend.Attributes.CannotDecreaseVisibilityAttribute").FirstOrDefault()
where tAttr != null

// Get types that do a wrong usage of CannotDecreaseVisibilityAttribute
let types = from t in Application.Types where 
   t.HasAttribute("NDepend.Attributes.CannotDecreaseVisibilityAttribute".AllowNoMatch()) &&
   ( t.Visibility == t.OptimalVisibility ||

     // Static types that define only const fields cannot be seen as used in IL code.
     // They don't need to be tagged with CannotDecreaseVisibilityAttribute.
     (t.IsStatic && t.NbMethods == 0 && !t.Fields.Any(f => !f.IsLiteral))
   )
   select t

// Get methods that do a wrong usage of CannotDecreaseVisibilityAttribute
let methods = from m in Application.Methods where 
   m.HasAttribute("NDepend.Attributes.CannotDecreaseVisibilityAttribute".AllowNoMatch()) &&
   m.Visibility == m.OptimalVisibility
   select m

// Get fields that do a wrong usage of CannotDecreaseVisibilityAttribute
let fields = from f in Application.Fields where 
   f.HasAttribute("NDepend.Attributes.CannotDecreaseVisibilityAttribute".AllowNoMatch()) &&
   f.Visibility == f.OptimalVisibility
   select f

where types.Count() > 0 || methods.Count() > 0 || fields.Count() > 0
select new { 
   tAttr, 
   types , 
   methods, 
   fields
}

//<Description>
// The attribute **NDepend.Attributes.CannotDecreaseVisibilityAttribute**
// is defined in *NDepend.API.dll*. If you don't want to reference
// *NDepend.API.dll* you can declare it in your code.
//
// Usage of this attribute means that a code element visibility is not 
// optimal (it can be lowered like for example from *public* to *internal*) 
// but shouldn’t be modified anyway. Typical reasons to do so include:
//
// • Public code elements consumed through reflection, through a mocking
// framework, through XML or binary serialization, through designer, 
// COM interfaces…
//
// • Non-private code element invoked by test code, that would be difficult
// to reach from test if it was declared as *private*.
//
// In such situation *CannotDecreaseVisibilityAttribute* is used to avoid
// that default rules about not-optimal visibility warn. Using this 
// attribute can be seen as an extra burden, but it can also be seen as 
// an opportunity to express in code: **Don't change the visibility else
// something will be broken** 
//
// In this context, this code rule matches code elements 
// (types, methods, fields) that are tagged with this attribute,
// but still already have an optimal visibility.
//</Description>

//<HowToFix>
// Just remove *CannotDecreaseVisibilityAttribute* tagging of
// types, methods and fields matched by this rule
// because this tag is not useful anymore.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Event handler methods should be declared private</Name>
warnif count > 0
from m in Application.Methods where 
  !m.IsPrivate &&
  !m.IsGeneratedByCompiler &&

   // A method is considered as an event handler if…
   m.NbParameters == 2 &&          // … it has two parameters …
   m.Name.Contains("Object") &&    // … of types Object …
   m.Name.Contains("EventArgs") && // … and EventArgs
   
   // Discard special cases
  !m.ParentType.IsDelegate &&
  !m.IsGeneratedByCompiler

select new { m,m.Visibility }

//<Description>
// Think of a event handler like for example *OnClickButton()*.
// Typically such method must be declared as private
// and shouldn't be invoked in other context than event firing.
//</Description>

//<HowToFix>
// If you have the need that event handler method should be called
// from another class, then find a code structure that more 
// closely matches the concept of what you're trying to do. 
// Certainly you don't want the other class to click a button; you 
// want your other class to do something that clicking a button  
// also do. 
//</HowToFix>]]></Query>
    </Group>
    <Group Name="Immutability" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Fields should be marked as ReadOnly when possible</Name>
warnif count > 0 
from f in JustMyCode.Fields where 
   f.IsImmutable && 
  !f.IsInitOnly && // The condition IsInitOnly matches fields that 
                   // are marked with the C# readonly keyword 
                   // (ReadOnly in VB.NET).
  !f.IsGeneratedByCompiler &&
  !f.IsEventDelegateObject
select new { f, f.MethodsReadingMeButNotAssigningMe, f.MethodsAssigningMe } 

//<Description>
// This rule warns about instance and static fields that
// can be declared as **readonly**.
//
// This source code of this rule is based on the conditon 
// *IField.IsImmutable*.
// http://www.ndepend.com/api/webframe.html?NDepend.API~NDepend.CodeModel.IField~IsImmutable.html
//
// A field that matches the condition *IsImmutable* 
// is a field that is assigned only by constructors 
// of its class.
//
// For an *instance field*, this means its value 
// will remain constant through the lifetime 
// of the object.
//
// For a *static field*, this means its value will 
// remain constant through the lifetime of the 
// program.
//</Description>

//<HowToFix>
// Declare the  field with the C# *readonly* keyword 
// (*ReadOnly* in VB.NET). This way the intention
// that the field value shouldn't change is made
// explicit.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Structures should be immutable</Name>
warnif count > 0 from t in Application.Types where 
   t.IsStructure && 
  !t.IsImmutable

let mutableFields = t.Fields.Where(f => !f.IsImmutable)

select new { t, t.NbLinesOfCode, mutableFields }

//<Description>
// An object is immutable if its state doesn’t change once the 
// object has been created. Consequently, a structure or a class 
// is immutable if its instances fields are only assigned inline
// or from constructor(s).
//
// But for structure it is a bit different. **Structures are value
// types** which means instances of structures are copied when they are 
// passed around (like through a method argument).
//
// So if you change a copy you are changing only that copy, not the  
// original and not any other copies which might be around. Such 
// situation is very different than what happen with instances of 
// classes. Hence developers are not used to work with modified values
// and doing so introduces *confusion* and is *error-prone*. 
//</Description>

//<HowToFix>
// Make sure matched structures are immutable. This way, all 
// automatic copies of an original instance, resulting from being 
// *passed by value* will hold the same values and there will be 
// no surprises.
//
// If your structure is immutable then if you want to change 
// a value, you have to consciously do it by creating a new instance 
// of the structure with the modified data.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Property Getters should be immutable</Name>
warnif count > 0 from m in Application.Methods where
 !m.IsGeneratedByCompiler &&
  m.IsPropertyGetter &&
  ( ( !m.IsStatic && m.ChangesObjectState) ||
    (  m.IsStatic && m.ChangesTypeState) )

let fieldsAssigned = m.FieldsAssigned

select new { m, m.NbLinesOfCode, fieldsAssigned  }

//<Description>
// It is not expected that a state gets modified when 
// accessing a property getter. Hence doing so create
// confusion and property getters should be pure methods, 
// they shouldn't assign any field.
//</Description>

//<HowToFix>
// Make sure that matched property getters don't assign any
// field.
//
// Notice the case of an object *lazy-initialized* when 
// the property getter is accessed the first time. In such
// situation the getter assigns a field, but it is only once
// and from the client point of view, lazy initialization
// is an invisible implementation detail. If you are using
// a lot lazy initalization but still want to use the 
// present rule, an option is to create a 
// *LazyInitializerAttribute* that tags concerned property
// getters, and modify the present rule to avoid matching them.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid static fields with a mutable field type</Name>
warnif count > 0
from f in Application.Fields
where f.IsStatic && 
     !f.IsEnumValue && 
     !f.IsGeneratedByCompiler 
     && !f.IsLiteral
let fieldType = f.FieldType
where fieldType != null && 
     !fieldType.IsThirdParty && 
     !fieldType.IsInterface && 
     !fieldType.IsImmutable
select new { 
   f, 
   mutableFieldType = fieldType , 
   isFieldImmutable = f.IsImmutable, 
   isFieldIsReadOnly = f.IsInitOnly }

//<Description>
// This rule warns about static fields that can be assigned
// (i.e they are not declared as *readonly*). This rule
// also warns about *readonly* static fields whose field type
// is mutable. In both cases, each matched static field is 
// holding a state that can be modified.
//
// In *Object-Oriented-Programming* the natural artifact 
// to hold states that can be modified is **instance fields**.
// Hence such static fields create *confusion* at runtime.
//
// More discussion on the topic can be found here:
// http://codebetter.com/patricksmacchia/2011/05/04/back-to-basics-usage-of-static-members/
//</Description>

//<HowToFix>
// If the *static* field is just assigned once in the program
// lifetime, make sure to declare it as *readonly* and assign 
// it inline, or from the static constructor.
//
// Else, to fix violations of this rule, make sure to
// hold mutable states through objects that are passed
// **explicitly** everywhere they need to be consumed, in 
// opposition to mutable object hold by a static field that 
// makes it modifiable from a bit everywhere in the program. 
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>A field must not be assigned from outside its parent hierarchy types</Name>
        
warnif count > 0
from f in JustMyCode.Fields.Where(f => 
      (f.IsInternal || f.IsPublic) && 
      !f.IsGeneratedByCompiler && 
      !f.IsImmutable && 
      !f.IsEnumValue)

let methodsAssignerOutsideOfMyType = f.MethodsAssigningMe.Where(
     m =>!m.IsGeneratedByCompiler &&
          m.ParentType != f.ParentType && 
         !m.ParentType.DeriveFrom(f.ParentType) )

where methodsAssignerOutsideOfMyType.Count() > 0
select new { 
   f, 
   methodsAssignerOutsideOfMyType
}

//<Description>
// This rule is related to the rule *Fields should be declared as 
// private*. It matches any **public or internal, mutable field** 
// that is assigned from outside its parent class and subclasses.
//
// Fields should be considered as **implementation details**
// and as a consequence they should be declared as private.
//
// If something goes wrong with a *non-private field*, 
// the culprit can be anywhere, and so in order to track down 
// the bug, you may have to look at quite a lot of code.
//
// A private field, by contrast, can only be assigned from 
// inside the same class, so if something goes wrong with that, 
// there is usually only one source file to look at. 
//</Description>

//<HowToFix>
// Matched fields must be declared as *protected* and even better
// as *private*. Alternatively, if the field can reference
// immutable states, it can remain visible from the outside, 
// but then must be declared as *readonly*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Don't assign a field from many methods</Name>
                
warnif count > 0 
from f in JustMyCode.Fields where 
  !f.IsEnumValue &&
  !f.IsImmutable && 
  !f.IsInitOnly &&
  !f.IsGeneratedByCompiler &&
  !f.IsEventDelegateObject

let methodsAssigningMe = f.MethodsAssigningMe.Where(m => !m.IsConstructor)

// The threshold 4 is arbitrary and it should avoid matching too many fields.
// Threshold is even lower for static fields because this reveals situations even more complex.
where methodsAssigningMe.Count() >= (!f.IsStatic ? 4 : 2)
select new { 
   f, 
   methodsAssigningMe, 
   f.MethodsReadingMeButNotAssigningMe, 
   f.MethodsUsingMe
} 

//<Description>
// A field assigned from many methods is a symptom of **bug-prone code**.
// Notice that:
//
// • For an instance field, constructor(s) of its class that assign the field are not counted.
//
// • For a static field, the class constructor that assigns the field is not counted.
//
// The default threshold for *instance fields* is *assigned by more than 4
// methods*. Such situation makes harder to anticipate the field state during
// runtime. The code is then complicated to read, hard to debug and hard to
// maintain. Hard-to-solve bugs due to corrupted state are often the 
// consequence of fields *anarchically assigned*.
//
// The situation is even more complex if the field is *static*.
// Indeed, such situation potentially involves global random accesses from
// various parts of the application. This is why this rule provides a lower 
// threshold equals to *assigned by more than 2 methods* for static fields.
// 
// If the object containing such field is meant to be used from multiple threads, 
// there are **alarming chances** that the code is unmaintainable and bugged.
// When multiple threads are involved, the rule of thumb is to use immutable objects.
//
// If the field type is a reference type (interfaces, classes, strings, delegates) 
// corrupted state might result in a *NullReferenceException*.
// If the field type is a value type (number, boolean, structure) 
// corrupted state might result in wrong result not even signaled by an exception 
// thrown.
//</Description>

//<HowToFix>
// There is no straight advice to refactor the number of methods responsible 
// for assigning a field. Solutions often involve rethinking and then rewriting 
// a complex algorithm. Such field can sometime become just a variable accessed 
// locally by a method or a *closure*. Sometime, just rethinking the life-time 
// and the role of the parent object allows the field to become immutable 
// (i.e assigned only by the constructor).
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Do not declare read only mutable reference types</Name>
        
warnif count > 0 from f in JustMyCode.Fields where 
   f.IsInitOnly && 
  !f.ParentType.IsPrivate &&
  !f.IsPrivate &&
   f.FieldType != null &&
   f.FieldType.IsClass &&
  !f.FieldType.IsThirdParty &&
  !f.FieldType.IsImmutable
select new { 
   f, 
   f.FieldType, 
   FieldVisibility = f.Visibility 
}

//<Description>
// This rule is violated when a *public* or *internal*  
// type contains a *public* or *internal* read-only field 
// whose field type is a mutable reference type.
//
// This situation provides the wrong impression that the 
// value can't change, when actually it's only the field 
// value that can't change, but the object state 
// can still change. 
//</Description>

//<HowToFix>
// To fix a violation of this rule, 
// replace the field type with an immutable type,
// or declare the field as *private*.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Array fields should not be read only</Name>

warnif count > 0 from f in Application.Fields where 
   f.IsInitOnly && 
   f.IsPubliclyVisible &&
   f.FieldType != null &&
   f.FieldType.FullName == "System.Array"
select new { 
   f, 
   FieldVisibility = f.Visibility 
}

//<Description>
// This rule is violated when a publicly visible field
// that holds an array, is declared read-only.
//
// This situation represents a *security vulnerability*.
// Because the field is read-only it cannot be changed to refer
// to a different array. However, the elements of the array 
// that are stored in a read-only field can be changed. 
// Code that makes decisions or performs operations that are 
// based on the elements of a read-only array that can be publicly 
// accessed might contain an exploitable security vulnerability.
//</Description>

//<HowToFix>
// To fix the security vulnerability that is identified by
// this rule do not rely on the contents of a read-only array 
// that can be publicly accessed. It is strongly recommended 
// that you use one of the following procedures:
//
// • Replace the array with a strongly typed collection 
// that cannot be changed. See for example: 
// *System.Collections.Generic.IReadOnlyList<T>* ;
// *System.Collections.Generic.IReadOnlyCollection<T>* ;
// *System.Collections.ReadOnlyCollectionBase*
//
// • Or replace the public field with a method that returns a clone 
// of a private array. Because your code does not rely on 
// the clone, there is no danger if the elements are modified. 
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types tagged with ImmutableAttribute must be immutable</Name>
warnif count > 0 
from t in Application.Types where 
   t.HasAttribute ("NDepend.Attributes.ImmutableAttribute".AllowNoMatch()) && 
  !t.IsImmutable
let culpritFields = t.Fields.Where(f => !f.IsStatic && !f.IsImmutable)
select new { 
   t, 
   culpritFields 
}

//<Description>
// An object is immutable if its state doesn’t change once the 
// object has been created. Consequently, a structure or a class 
// is immutable if its instances fields are only assigned inline
// or from constructor(s).
//
// An attribute **NDepend.Attributes.ImmutableAttribute** can be 
// used to express in code that a type is immutable. In such 
// situation, the present code rule checks continuously that the 
// type remains immutable whatever the modification done.
//
// This rule warns when a type that is tagged with
// *ImmutableAttribute* is actually not immutable anymore.
//
// Notice that *FullCoveredAttribute* is defined in *NDepend.API.dll*
// and if you don't want to link this assembly, you can create your
// own  *FullCoveredAttribute* and adapt the rule.
//</Description>

//<HowToFix>
// First understand which modification broke the type immutability.
// The list of *culpritFields* provided in this rule result can help.
// Then try to refactor the type to bring it back to immutability. 
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types immutable should be tagged with ImmutableAttribute</Name>
from t in Application.Types where 
  !t.HasAttribute ("NDepend.Attributes.ImmutableAttribute".AllowNoMatch()) && 
   t.IsImmutable
select new { t, t.NbLinesOfCode }

//<Description>
// An object is immutable if its state doesn’t change once the 
// object has been created. Consequently, a structure or a class 
// is immutable if its instances fields are only assigned inline
// or from constructor(s).
//
// This code query lists immutable type that are not tagged with
// an **ImmutableAttribute**. By using such attribute, you can express
// in source code the intention that a class is immutable, and 
// should remain immutable in the future. Benefits of using 
// an **ImmutableAttribute** are twofold:
//
// • Not only the intention is expressed in source code,
//
// • but it is also continuously checked by the rule 
// *Types tagged with ImmutableAttribute must be immutable*.
//</Description>

//<HowToFix>
// Just tag types matched by this code query with **ImmutableAttribute**
// that can be found in *NDepend.API.dll*,
// or by an attribute of yours defined in your own code 
// (in which case this code query must be adapted).
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods tagged with PureAttribute must be pure</Name>

warnif count > 0 from m in Application.Methods where 
  ( m.HasAttribute ("NDepend.Attributes.PureAttribute".AllowNoMatch()) || 
    m.HasAttribute ("System.Diagnostics.Contract.PureAttribute".AllowNoMatch()) ) &&
  ( m.ChangesObjectState || m.ChangesTypeState ) &&
    m.NbLinesOfCode > 0

let fieldsAssigned = m.FieldsAssigned

select new { m, m.NbLinesOfCode, fieldsAssigned }

//<Description>
// A method is pure if its execution doesn’t change 
// the value of any instance or static field. 
// Pure methods naturally simplify code by **limiting 
// side-effects**.
//
// An attribute **PureAttribute** can be 
// used to express in code that a method is pure. In such 
// situation, the present code rule checks continuously that the 
// method remains pure whatever the modification done.
//
// This rule warns when a method that is tagged with
// *PureAttribute* is actually not pure anymore.
//
// Notice that *NDepend.Attributes.PureAttribute* is defined 
// in *NDepend.API.dll* and if you don't want to link this 
// assembly, you can also use 
// *System.Diagnostics.Contract.PureAttribute*
// or create your own *PureAttribute* and adapt the rule.
// 
// Notice that *System.Diagnostics.Contract.PureAttribute* is 
// taken account by the compiler only when the VS project has 
// Microsoft Code Contract enabled. 
//</Description>

//<HowToFix>
// First understand which modification broke the method purity.
// Then refactor the method to bring it back to purity. 
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Pure methods should be tagged with PureAttribute</Name>
// warnif count > 0   <-- not a cod rule per default

from m in Application.Methods where 
  !m.IsGeneratedByCompiler &&
  !m.HasAttribute ("NDepend.Attributes.PureAttribute".AllowNoMatch()) && 
  !m.HasAttribute ("System.Diagnostics.Contract.PureAttribute".AllowNoMatch()) &&
  !m.ChangesObjectState && !m.ChangesTypeState &&
   m.NbLinesOfCode > 0
select new { m, m.NbLinesOfCode }

//<Description>
// A method is pure if its execution doesn’t change 
// the value of any instance or static field. 
// Pure methods naturally simplify code by **limiting 
// side-effects**.
//
// This code query lists pure methods that are not tagged with
// a **PureAttribute**. By using such attribute, you can express
// in source code the intention that a method is pure, and 
// should remain pure in the future. Benefits of using 
// a **PureAttribute** are twofold:
//
// • Not only the intention is expressed in source code,
//
// • but it is also continuously checked by the rule 
// *Methods tagged with PureAttribute must be pure*.
//
// This code query is not by default defined as a code rule
// because certainly many of the methods of the code base 
// are matched. Hence fixing all matches and then
// maintaining the rule unviolated might require a lot of
// work. This may *counter-balance* such rule benefits.
//</Description>

//<HowToFix>
// Just tag methods matched by this code query with
// *NDepend.Attributes.PureAttribute*
// that can be found in *NDepend.API.dll*,
// or with *System.Diagnostics.Contract.PureAttribute*,
// or with an attribute of yours defined in your own code 
// (in which case this code query must be adapted).
//
// Notice that *System.Diagnostics.Contract.PureAttribute* is 
// taken account by the compiler only when the VS project has 
// Microsoft Code Contract enabled. 
//</HowToFix>]]></Query>
    </Group>
    <Group Name="Naming Conventions" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Instance fields should be prefixed with a 'm_'</Name>
warnif count > 0 from f in Application.Fields where 
  !f.NameLike(@"^m_") && 
  !f.IsStatic && 
  !f.IsLiteral && 
  !f.IsGeneratedByCompiler  && 
  !f.IsSpecialName && 
  !f.IsEventDelegateObject
select new { f, f.SizeOfInst } 

//<Description>
// In terms of behavior, a *static field* is something completely different
// than an *instance field*, so it is interesting to differentiate them at 
// a glance through a naming convetion.
//
// The present rule enforces **m_** prefix for *instance fields* names.
// To do so, the rule relies on a **f.NameLike(@"^m_")** *regular expression*.
// You can easily adapt the *regular expression* to your own naming convention.
//
// Related discussion:
// http://codebetter.com/patricksmacchia/2013/09/04/on-hungarian-notation-for-instance-vs-static-fields-naming/
//</Description>

//<HowToFix>
// Once the rule has been adapted to your own naming convention
// make sure to name all matched instance fields adequately.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Static fields should be prefixed with a 's_'</Name>
warnif count > 0 from f in Application.Fields where 
  !f.NameLike (@"^s_") && 
   f.IsStatic && 
  !f.IsLiteral && 
  !f.IsGeneratedByCompiler && 
  !f.IsSpecialName && 
  !f.IsEventDelegateObject
select new { f, f.SizeOfInst }  

//<Description>
// In terms of behavior, a *static field* is something completely different
// than an *instance field*, so it is interesting to differentiate them at 
// a glance through a naming convetion.
//
// The present rule enforces **s_** prefix for *static fields* names.
// To do so, the rule relies on a **f.NameLike(@"^s_")** *regular expression*.
// You can easily adapt the *regular expression* to your own naming convention.
//
// Related discussion:
// http://codebetter.com/patricksmacchia/2013/09/04/on-hungarian-notation-for-instance-vs-static-fields-naming/
//</Description>

//<HowToFix>
// Once the rule has been adapted to your own naming convention
// make sure to name all matched static fields adequately.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Interface name should begin with a 'I'</Name>
   
warnif count > 0 from t in Application.Types where 
   t.IsInterface  &&
   // Don't apply this rule for COM interfaces.
  !t.HasAttribute("System.Runtime.InteropServices.ComVisibleAttribute".AllowNoMatch())

// Discard outter type(s) name prefix for nested types
let name = !t.IsNested  ? 
   t.Name : 
   t.Name.Substring(t.Name.LastIndexOf('+') + 1, t.Name.Length - t.Name.LastIndexOf('+') - 1) 

where name[0] != 'I'
select t

//<Description>
// In the .NET world, interfaces names are commonly prefixed
// with an upper case **I**. This rule warns about interfaces
// whose names don't follow this convention. Because this 
// naming convention is widely used and accepted, we 
// recommend abiding by this rule.
//
// Typically COM interfaces names don't follow this rule.
// Hence this code rule doesn't take care of interfaces tagged
// with *ComVisibleAttribute*.
//</Description>

//<HowToFix>
// Make sure that matched interfaces names are prefixed with
// an upper **I**.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Abstract base class should be suffixed with 'Base'</Name>
        
warnif count > 0 from t in Application.Types where 
  t.IsAbstract && 
  t.IsClass &&

  t.BaseClass != null &&
  t.BaseClass.FullName == "System.Object" &&

  ((!t.IsGeneric && !t.NameLike (@"Base$")) ||
   ( t.IsGeneric && !t.NameLike (@"Base<")))
select t

//<Description>
// This rule warns about *abstract classes* whose names are not 
// suffixed with **Base**. It is a common practice in the .NET 
// world to suffix base classes names with **Base**.
//
// Notice that this rule doesn't match
// abstract classes that are in a middle of a hierarchy chain.
// Only base classes that derive directly from *System.Object* 
// are matched.
//</Description>

//<HowToFix>
// Suffix the names of matched base classes with **Base**.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Exception class name should be suffixed with 'Exception'</Name>
warnif count > 0 from t in Application.Types where 
  t.IsExceptionClass &&
  
  // We use SimpleName, because in case of generic Exception type
  // SimpleName suppresses the generic suffix (like <T>).
 !t.SimpleNameLike(@"Exception$") &&
 !t.SimpleNameLike(@"ExceptionBase$") // Allow the second suffix Base
                                      // for base exception classes.
select t

//<Description>
// This rule warns about *exception classes* whose names are not 
// suffixed with **Exception**. It is a common practice in the .NET 
// world to suffix exception classes names with **Exception**.
//
// For exception base classes, the suffix **ExceptionBase**
// is also accepted.
//</Description>

//<HowToFix>
// Suffix the names of matched exception classes with **Exception**.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Attribute class name should be suffixed with 'Attribute'</Name>
warnif count > 0 from t in Application.Types where 
   t.IsAttributeClass && 
  !t.NameLike (@"Attribute$") 
select t

//<Description>
// This rule warns about *attribute classes* whose names are not 
// suffixed with **Attribute**. It is a common practice in the .NET 
// world to suffix attribute classes names with **Attribute**.
//</Description>

//<HowToFix>
// Suffix the names of matched attribute classes with **Attribute**.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types name should begin with an Upper character</Name>
        
warnif count > 0 from t in JustMyCode.Types where 
  // The name of a type should begin with an Upper letter.
  !t.SimpleNameLike (@"^[A-Z]") &&     

  // Except if it is generated by compiler.
  !t.IsSpecialName &&
  !t.IsGeneratedByCompiler

select new { 
   t,
   // We show the type simple name
   // that doesn't include the parent type name
   // for nested types. 
   t.SimpleName }

//<Description>
// This rule warns about *types* whose names don't start
// with an Upper character. It is a common practice in the .NET 
// world to use **Pascal Casing Style** to name types.
//
// **Pascal Casing Style** : The first letter in the identifier 
// and the first letter of each subsequent concatenated word 
// are capitalized. For example:  *BackColor*
//</Description>

//<HowToFix>
// *Pascal Case* the names of matched types.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods name should begin with an Upper character</Name>
                
warnif count > 0 from m in JustMyCode.Methods where 
  !m.NameLike (@"^[A-Z]") && 
  !m.IsSpecialName && 
  !m.IsGeneratedByCompiler
select m

//<Description>
// This rule warns about *methods* whose names don't start
// with an Upper character. It is a common practice in the .NET 
// world to use **Pascal Casing Style** to name methods.
//
// **Pascal Casing Style** : The first letter in the identifier 
// and the first letter of each subsequent concatenated word 
// are capitalized. For example:  *ComputeSize*
//</Description>

//<HowToFix>
// *Pascal Case* the names of matched methods.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Do not name enum values 'Reserved'</Name>
        
warnif count > 0 from f in Application.Fields where 
  f.IsEnumValue && 
  f.NameLike (@"Reserved")
select f

//<Description>
// This rule assumes that an enumeration member 
// with a name that contains **"Reserved"** 
// is not currently used but is a placeholder to 
// be renamed or removed in a future version.
// Renaming or removing a member is a breaking 
// change. You should not expect users to ignore
// a member just because its name contains 
// **"Reserved"** nor can you rely on users to read or 
// abide by documentation. Furthermore, because 
// reserved members appear in object browsers 
// and smart integrated development environments, 
// they can cause confusion as to which members 
// are actually being used.
//
// Instead of using a reserved member, add a 
// new member to the enumeration in the future 
// version.
//
// In most cases, the addition of the new 
// member is not a breaking change, as long as the 
// addition does not cause the values of the 
// original members to change.
//</Description>

//<HowToFix>
// To fix a violation of this rule, remove or 
// rename the member.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid types with name too long</Name>
     
warnif count > 0 from t in Application.Types 
where !t.IsGeneratedByCompiler

where t.SimpleName.Length > 35 
select new { t, t.SimpleName }

//<Description>
// Types with a name too long tend to decrease code readability.
// This might also be an indication that a type is doing too much.
//
// This rule matches types with names with more than 35 characters.
//</Description>

//<HowToFix>
// To fix a violation of this rule, rename the type with a shortest name
// or eventually split the type in several more fine-grained types.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid methods with name too long</Name>
warnif count > 0 from m in Application.Methods where 

 // Explicit Interface Implementation methods are 
 // discarded because their names are prefixed 
 // with the interface name.
 !m.IsExplicitInterfaceImpl &&
 !m.IsGeneratedByCompiler &&
 ((!m.IsSpecialName && m.SimpleName.Length > 35) ||
   // Property getter/setter are prefixed with "get_" "set_" of length 4.
  ( m.IsSpecialName && m.SimpleName.Length - 4 > 35))

select new { m, m.SimpleName }

//<Description>
// Methods with a name too long tend to decrease code readability.
// This might also be an indication that a method is doing too much.
//
// This rule matches methods with names with more than 35 characters.
//</Description>

//<HowToFix>
// To fix a violation of this rule, rename the method with a shortest name
// that equally conveys the behavior of the method.
// Or eventually split the method into several smaller methods.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid fields with name too long</Name>
warnif count > 0 from f in Application.Fields where
 !f.IsGeneratedByCompiler &&
  f.Name.Length > 35
select f

//<Description>
// Fields with a name too long tend to decrease code readability.
//
// This rule matches fields with names with more than 35 characters.
//</Description>

//<HowToFix>
// To fix a violation of this rule, rename the field with a shortest name
// that equally conveys the same information.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Avoid having different types with same name</Name>
warnif count > 0

// This rule matches also collisions between 
// application and third-party types sharing a same name.
let groups = JustMyCode.Types.Union(ThirdParty.Types)
                 // Discard nested types, whose name is 
                 // prefixed with the parent type name.
                 .Where(t => !t.IsNested)
                 
                 // Group types by name.
                 .GroupBy(t => t.Name)

from @group in groups 
   where @group.Count() > 1

   // Let's see if types with the same name are declared
   // in different namespaces.
   // (t.FullName is {namespaceName}.{typeName} )
   let groupsFullName = @group.GroupBy(t => t.FullName)
   where groupsFullName.Count() > 1

   // If several types with same name are declared in different namespaces
   // eliminate the case where all types are declared in third-party assemblies.
   let types= groupsFullName.SelectMany(g => g)
   where types.Any(t => !t.IsThirdParty)
        // Uncomment this line, to only gets naming collision involving
        // both application and third-party types.
        //         && types.Any(t => t.IsThirdParty)

orderby types.Count() descending 

select new { 
   t = types.First(),
   
   // In the 'types' column, make sure to group matched types 
   // by parent assemblies and parent namespaces, to get a result
   // more readable.
   types
}

//<Description>
// This rule warns about multiple types with same name,
// that are defined in different *application* or  
// *third-party* namespaces or assemblies.
//
// Such practice create confusion and also naming collision
// in source files that use different types with same name.
//</Description>

//<HowToFix>
// To fix a violation of this rule, rename concerned types.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid prefixing type name with parent namespace name</Name>
warnif count > 0

from n in Application.Namespaces
where n.Name.Length > 0

from t in n.ChildTypes
where 
  !t.IsGeneratedByCompiler &&
  !t.IsNested &&
   t.Name.IndexOf(n.SimpleName) == 0
select new { 
   t, 
   namespaceName = n.SimpleName 
}

//<Description>
// This rule warns about situations where the parent namespace name
// is used as the prefix of a contained type.
//
// For example a type named "RuntimeEnvironment"
// declared in a namespace named "Foo.Runtime"
// should be named "Environment".
//
// Such situation creates naming redundancy with no readability gain.
//</Description>

//<HowToFix>
// To fix a violation of this rule, remove the prefix from the type name.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid naming types and namespaces with the same identifier</Name>
warnif count > 0
let hashsetShortNames = Namespaces.Where(n => n.Name.Length > 0).Select(n => n.SimpleName).ToHashSet()

from t in JustMyCode.Types
where hashsetShortNames.Contains(t.Name)
select new { 
   t, 
   namespaces = Namespaces.Where(n => n.SimpleName == t.Name) 
}

//<Description>
// This rule warns when a type and a namespace have the same name.
//
// For example when a type is named *Environment*
// and a namespace is named *Foo.Environment*.
//
// Such situation provokes tedious compiler resolution collision,
// and makes the code less readable because concepts are not 
// concisely identified.
//</Description>

//<HowToFix>
// To fix a violation of this rule, renamed the concerned type or namespace.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Don't call your method Dispose</Name>
warnif count > 0
from m in JustMyCode.Methods.WithSimpleName("Dispose")
where !m.ParentType.Implement("System.IDisposable".AllowNoMatch()) &&
       m.OverriddensBase.Count() == 0    // Can't change the name of an override
select m

//<Description>
// In .NET programming, the identifier *Dispose()* should be kept 
// only for implementations of *System.IDisposable*.
//
// This rule warns when a method is named *Dispose()*,
// but the parent type doesn't implement *System.IDisposable*.
//</Description>

//<HowToFix>
// To fix a violation of this rule,
// either make the parent type implements *System.IDisposable*,
// or rename the *Dispose()* method with another identifier:
// *Close() Terminate() Finish() Quit() Exit() Unlock() ShutDown()*…
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods prefixed with 'Try' should return a boolean</Name>
warnif count > 0
from m in Application.Methods where
  m.SimpleNameLike("^Try") &&
  m.ReturnType != null &&
  m.ReturnType.FullName != "System.Boolean"
select new { 
   m, 
   m.ReturnType 
}

//<Description>
// When a method has a name prefixed with **Try**, it is expected that
// it returns a *boolean*, that reflects the method execution status,
// *success* or *failure*.
//
// Such method usually returns a result through an *out parameter*.
// For example:  *System.Int32.TryParse(int,out string):bool*
//</Description>

//<HowToFix>
// To fix a violation of this rule,
// Rename the method, or transform it into an operation that can fail.
//</HowToFix>]]></Query>
    </Group>
    <Group Name="Source Files Organization" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid referencing source file out of Visual Studio project directory</Name>
warnif count > 0 

from a in Application.Assemblies
where a.VisualStudioProjectFilePath != null
let vsProjDirPathLower = a.VisualStudioProjectFilePath.ParentDirectoryPath.ToString().ToLower()

from t in a.ChildTypes
where JustMyCode.Contains(t) && t.SourceFileDeclAvailable

from decl in t.SourceDecls
let sourceFilePathLower = decl.SourceFile.FilePath.ToString().ToLower()
where sourceFilePathLower.IndexOf(vsProjDirPathLower) != 0
select new { 
   t, 
   sourceFilePathLower, 
   projectFilePath = a.VisualStudioProjectFilePath.ToString() 
}

//<Description>
// A source file located outside of the VS project directory can be added through:
// *> Add > Existing Items… > Add As Link*
//
// Doing so can be used to share types definitions across several assemblies.
// This provokes type duplication at binary level.
// Hence maintainability is degraded and subtle versioning bug can appear.
//
// This rule matches types whose source files are not declared under the 
// directory that contains the related Visual Studio project file, or under
// any sub-directory of this directory.
//
// This practice can be tolerated for certain types shared across executable assemblies.
// Such type can be responsible for startup related concerns, 
// such as registering custom assembly resolving handlers or 
// checking the .NET Framework version before loading any custom library.
//</Description>

//<HowToFix>
// To fix a violation of this rule, prefer referencing from a VS project
// only source files defined in sub-directories of the VS project file location.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid duplicating a type definition across assemblies</Name>
warnif count > 0

let groups = Application.Types
             .Where(t => !t.IsGeneratedByCompiler)
             .GroupBy(t => t.FullName)
from @group in groups
where @group.Count() > 1

select new { 
   t = @group.First(),
   // In the 'types' column, make sure to group matched types by parent assemblies.
   typesDefs = @group.ToArray() 
}

//<Description>
// A source file located outside of the VS project directory can be added through:
// *> Add > Existing Items… > Add As Link*
//
// This rule warns about using this feature to share code across several assemblies.
// This provokes type duplication at binary level.
// Hence maintainability is degraded and subtle versioning bug can appear.
//
// This practice can be tolerated for certain types shared across executable assemblies.
// Such type can be responsible for startup related concerns, 
// such as registering custom assembly resolving handlers or 
// checking the .NET Framework version before loading any custom library.
//</Description>

//<HowToFix>
// To fix a violation of this rule, prefer sharing types through DLLs.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Avoid defining multiple types in a source file</Name>
warnif count > 0 

// Build a lookup indexed by source files, values being a sequence of types defined in the source file.
let lookup = Application.Types.Where(t => 
                                t.SourceFileDeclAvailable && 
                               // except nested types and types generated by compilers!
                               !t.IsGeneratedByCompiler &&                               
                               !t.IsNested)                                
                         // It could make sense to not apply this rule for enumerations.
                         // && !t.IsEnumeration)

            // We use multi-key, since a type can be declared in multiple source files.
           .ToMultiKeyLookup(t => t.SourceDecls.Select(d => d.SourceFile))
 
from @group in lookup where @group.Count() > 1
   let sourceFile = @group.Key

   // CQLinq doesn't let indexing result with sourceFile 
   // so we choose a typeIndex in types, 
   // preferably the type that has the file name.
   let typeWithSourceFileName = @group.FirstOrDefault(t => t.SimpleName == sourceFile.FileNameWithoutExtension)
   let typeIndex = typeWithSourceFileName ?? @group.First()

select new { 
   typeIndex, 
   TypesInSourceFile = @group as IEnumerable<IType>, 
   SourceFilePathString = sourceFile.FilePathString
}

//<Description>
// Defining multiple types in a single source file decreases code readability,
// because developers are used to see all types in a namespace,
// when expanding a folder in the *Visual Studio Solution Explorer*.
// Also doing so, leads to source files with too many lines.
//
// Each match of this rule is a source file that contains several types
// definitions, indexed by one of those types, preferably the one with
// the same name than the source file name without file extension, if any.
//</Description>

//<HowToFix>
// To fix a violation of this rule, create a source file for each type.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Namespace name should correspond to file location</Name>

warnif count > 0
from n in Application.Namespaces 

// Replace dots by spaces in namespace name
let dirCorresponding = n.Name.Replace('.', ' ')

// Look at source file decl of JustMyCode type's declared in n
from t in n.ChildTypes
where JustMyCode.Contains(t) && t.SourceFileDeclAvailable
from decl in t.SourceDecls
let sourceFilePath = decl.SourceFile.FilePath.ToString()

// Replace dots and path separators by spaces in source files names
where !sourceFilePath.Replace('.',' ').Replace('\\',' ').Contains(dirCorresponding)

select new { 
   t, 
   dirCorresponding , 
   sourceFilePath  
} 

//<Description>
// For a solid code structure and organization, 
// do mirror the namespaces hierarchy and the directories hierarchy containing source files.
//
// Doing so is a widely accepted convention, and not respecting this convention 
// will lead to less maintainable and less browsable source code.
//
// This rule matches all types in such source file, whose location doesn't correspond
// to the type parent namespace. If a source file contains several such types (that
// are not necessarily in the same namespace) each type will result in a violation.
//</Description>

//<HowToFix>
// To fix a violation of this rule, make sure that the type parent namespace and 
// the directory sub-paths that contains the type source file, are mirrored.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types with source files stored in the same directory, should be declared in the same namespace</Name>
warnif count > 0 

// Group JustMyCode types in a lookup 
// where groups are keyed with directories that contain the types' source file(s).
// Note that a type can be contained in several groups 
// if it is declared in several source files stored in different directories.
let lookup = JustMyCode.Types.Where(t => t.SourceFileDeclAvailable)
            .ToMultiKeyLookup(
               t => t.SourceDecls.Select(
                          decl => decl.SourceFile.FilePath.ParentDirectoryPath).Distinct()
            )

from groupOfTypes in lookup
let parentNamespaces = groupOfTypes.ParentNamespaces()

// Select group of types (with source files stored in the same directory) …
// … but contained in several namespaces
where parentNamespaces.Count() > 1

// mainNamespaces is the namespace that contains many types 
// declared in the directory groupOfTypes .key
let mainNamespace  = groupOfTypes
                     .ToLookup(t => t.ParentNamespace)
                     .OrderByDescending(g => g.Count()).First().Key

// Select types with source files stored in the same directory,
// but contained in namespaces different than mainNamespace.
let typesOutOfMainNamespace = groupOfTypes
                              .Where(t => t.ParentNamespace != mainNamespace &&
                                          t.ParentAssembly == mainNamespace.ParentAssembly)

                              // Filter types declared on several source files that contain generated methods 
                              // because typically such type contains one or several partial definitions generated.
                              // These partially generated types would be false positive for the present rule.
                              .Where(t => t.SourceDecls.Count() == 1 ||
                                          t.Methods.Count(m => JustMyCode.Contains(m)) == 0)
where typesOutOfMainNamespace.Count() > 0

let typesInMainNamespace = groupOfTypes.Where(t => t.ParentNamespace == mainNamespace)

select new { 
    mainNamespace, 
    typesOutOfMainNamespace,
    typesInMainNamespace  }

//<Description>
// For a solid code structure and organization, do mirror the namespaces 
// hierarchy and the directories hierarchy containing source files.
//
// Doing so is a widely accepted convention, and not respecting this convention 
// will lead to less maintainable and less browsable code.
//
// Respecting this convention means that types with source files stored in the same directory, 
// should be declared in the same namespace.
//
// For each directory that contains several source files, where most types are declared 
// in a namespace (what we call the **main namespace**) and a few types are declared 
// out of the *main namespace*, this code rule matches:
//
// • The *main namespace*
//
// • **typesOutOfMainNamespace**: Types declared in source files in the *main namespace*'s directory
// but that are not in the *main namespace*.
//
// • *typesInMainNamespace*: And for informational purposes, types declared in source files in the 
// *main namespace*'s directory, and that are in the *main namespace*.
//</Description>

//<HowToFix>
// Violations of this rule are types in the *typesOutOfMainNamespace* column.
// Typically such type …
//
// •  … is contained in the wrong namespace but its source file is stored in the right directory.
//    In such situation the type should be contained in *main namespace*.
//
// •  … is contained in the right namespace but its source file is stored in the wrong directory
//    In such situation the source file of the type must be moved to the proper parent namespace directory.
//
// •  … is declared in multiple source files, stored in different directories.
//    In such situation it is preferable that all source files are stored in a single directory.
//</HowToFix>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types declared in the same namespace, should have their source files stored in the same directory</Name>
        
warnif count > 0 
from @namespace in Application.Namespaces

// Group types of @namespace in a lookup 
// where groups are keyed with directories that contain the types' source file(s).
// Note that a type can be contained in several groups 
// if it is declared in several source files stored in different directories.
let lookup = @namespace.ChildTypes.Where(t => t.SourceFileDeclAvailable && JustMyCode.Contains(t))
            .ToMultiKeyLookup(
               t => t.SourceDecls.Select(
                          decl => decl.SourceFile.FilePath.ParentDirectoryPath).Distinct()
            )

// Are types of @namespaces declared in more than one directory?
where lookup.Count > 1

// Infer the main folder, preferably the one that has the same name as the namespace.
let dirs = lookup.Select(types => types.Key)
let mainDirNullable = dirs.Where(d => d.DirectoryName == @namespace.SimpleName).FirstOrDefault()
let mainDir = mainDirNullable ?? dirs.First()

// Types declared out of mainDir, are types in group of types declared in a directory different than mainDir!
let typesDeclaredOutOfMainDir = 
   lookup.Where(types => types.Key != mainDir)
         .SelectMany(types => types)
                                
         // Filter types declared on several source files that contain generated methods 
         // because typically such type contains one or several partial definitions generated.
         // These partially generated types would be false positive for the present rule.
         .Where(t => t.SourceDecls.Count() == 1 ||
                     t.Methods.Count(m => JustMyCode.Contains(m)) == 0)

where typesDeclaredOutOfMainDir.Count() > 0

let typesDeclaredInMainDir = 
   lookup.Where(types => types.Key == mainDir)
         .SelectMany(types => types)

select new { 
    @namespace, 
    typesDeclaredOutOfMainDir , 
    mainDir = mainDir.ToString(),
    typesDeclaredInMainDir 
}

//<Description>
// For a solid code structure and organization, 
// do mirror the namespaces hierarchy and the directories hierarchy containing source files.
//
// Doing so is a widely accepted convention, and not respecting this convention 
// will lead to less maintainable and less browsable code.
//
// Respecting this convention means that types declared in the same namespace,
// should have their source files stored in the same directory.
//
// For each namespace that contains types whose source files
// are declared in several directories, infer the **main directory**,
// the directory that naturally hosts source files of types,
// preferably the directory whose name corresponds with the namespace 
// name. In this context, this code rule matches:
//
// • The namespace
//
// • **typesDeclaredOutOfMainDir**: types in the namespace whose source files 
// are stored out of the *main directory*.
//
// • The *main directory*
//  
// • *typesDeclaredInMainDir*: for informational purposes, types declared 
// in the namespace, whose source files are stored in the *main directory*.
//</Description>

//<HowToFix>
// Violations of this rule are types in the **typesDeclaredOutOfMainDir** column.
// Typically such type…
//
// •  … is contained in the wrong namespace but its source file is stored in the right directory.
//    In such situation the type should be contained in the namespace corresponding to
//    the parent directory.
//
// •  … is contained in the right namespace but its source file is stored in the wrong directory.
//    In such situation the source file of the type must be moved to the *main directory*.
//
// •  … is declared in multiple source files, stored in different directories.
//    In such situation it is preferable that all source files are stored in a single directory.
//</HowToFix>]]></Query>
    </Group>
    <Group Name=".NET Framework Usage" Active="True" ShownInReport="False">
      <Group Name="System" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Mark ISerializable types with SerializableAttribute</Name>
warnif count > 0
          
from t in Application.Types where 
  t.IsPublic && 
 !t.IsDelegate &&
 !t.IsExceptionClass && // Don't match exceptions, since the Exception class
                        // implements ISerializable, this would generate
                        // too many false positives.
  t.Implement ("System.Runtime.Serialization.ISerializable".AllowNoMatch()) && 
 !t.HasAttribute ("System.SerializableAttribute".AllowNoMatch())

select new { t, t.NbLinesOfCode }

//<Description>
// To be recognized by the CLR as serializable, 
// types must be marked with the *SerializableAttribute* 
// attribute even if the type uses a custom 
// serialization routine through implementation of 
// the *ISerializable* interface.
//
// This rule matches types that implement *ISerializable* and 
// that are not tagged with *SerializableAttribute*.
//</Description>

//<HowToFix>
// To fix a violation of this rule, tag the matched type
// with *SerializableAttribute* .
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Mark assemblies with assembly version</Name>
warnif count > 0 from a in Application.Assemblies where 
  !a.HasAttribute ("System.Reflection.AssemblyVersionAttribute".AllowNoMatch())
select a

//<Description>
// The identity of an assembly is composed of the following information:
//
// • Assembly name
//
// • Version number
//
// • Culture
//
// • Public key (for strong-named assemblies).
//
// The .NET Framework uses the version number to uniquely identify an 
// assembly, and to bind to types in strong-named assemblies. The 
// version number is used together with version and publisher policy. 
// By default, applications run only with the assembly version with 
// which they were built.
//
// This rule matches assemblies that are not tagged with
// **System.Reflection.AssemblyVersionAttribute**.
//</Description>

//<HowToFix>
// To fix a violation of this rule, add a version number to the assembly 
// by using the *System.Reflection.AssemblyVersionAttribute* attribute.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Mark assemblies with CLSCompliant</Name>
warnif count > 0 from a in Application.Assemblies where 
  !a.HasAttribute ("System.CLSCompliantAttribute".AllowNoMatch())
select a

//<Description>
// The *Common Language Specification* (CLS) defines naming restrictions, 
// data types, and rules to which assemblies must conform if they are to 
// be used across programming languages. Good design dictates that all 
// assemblies explicitly indicate CLS compliance with **CLSCompliantAttribute**. 
// If the attribute is not present on an assembly, the assembly is not compliant.
//
// Notice that it is possible for a CLS-compliant assembly to contain types or 
// type members that are not compliant.
//
// This rule matches assemblies that are not tagged with
// **System.CLSCompliantAttribute**.
//</Description>

//<HowToFix>
// To fix a violation of this rule, tag the assembly with *CLSCompliantAttribute*.
//
// Instead of marking the whole assembly as non-compliant, you should determine  
// which type or type members are not compliant and mark these elements as such. 
// If possible, you should provide a CLS-compliant alternative for non-compliant 
// members so that the widest possible audience can access all the functionality 
// of your assembly.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Mark assemblies with ComVisible</Name>
warnif count > 0 from a in Application.Assemblies where 
  !a.HasAttribute ("System.Runtime.InteropServices.ComVisibleAttribute".AllowNoMatch())
select a

//<Description>
// The **ComVisibleAttribute** attribute determines how COM clients access 
// managed code. Good design dictates that assemblies explicitly indicate 
// COM visibility. COM visibility can be set for a whole assembly and then 
// overridden for individual types and type members. If the attribute is not 
// present, the contents of the assembly are visible to COM clients.
//
// This rule matches assemblies that are not tagged with
// **System.Runtime.InteropServices.ComVisibleAttribute**.
//</Description>

//<HowToFix>
// To fix a violation of this rule, tag the assembly with *ComVisibleAttribute*.
//
// If you do not want the assembly to be visible to COM clients, set the
// attribute value to **false**.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Mark attributes with AttributeUsageAttribute</Name>
warnif count > 0 from t in Application.Types where 
   t.DeriveFrom ("System.Attribute".AllowNoMatch()) &&
  !t.HasAttribute ("System.AttributeUsageAttribute".AllowNoMatch())
select t

//<Description>
// When you define a custom attribute, mark it by using **AttributeUsageAttribute**
// to indicate where in the source code the custom attribute can be applied. The 
// meaning and intended usage of an attribute will determine its valid locations 
// in code. For example, you might define an attribute that identifies the person 
// who is responsible for maintaining and enhancing each type in a library, and 
// that responsibility is always assigned at the type level. In this case, compilers 
// should enable the attribute on classes, enumerations, and interfaces, but should 
// not enable it on methods, events, or properties. Organizational policies and 
// procedures would dictate whether the attribute should be enabled on assemblies.
//
// The **System.AttributeTargets** enumeration defines the targets that you can 
// specify for a custom attribute. If you omit *AttributeUsageAttribute*, your 
// custom attribute will be valid for all targets, as defined by the **All** value of 
// *AttributeTargets* enumeration.
//
// This rule matches attribute classes that are not tagged with
// **System.AttributeUsageAttribute**.
//</Description>

//<HowToFix>
// To fix a violation of this rule, specify targets for the attribute by using 
// *AttributeUsageAttribute*.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Remove calls to GC.Collect()</Name>
warnif count > 0 

let gcCollectMethods = ThirdParty.Methods.WithFullNameWildcardMatch(
   "System.GC.Collect(*)").ToHashSet()

from m in Application.Methods.UsingAny(gcCollectMethods)
select new { 
   m, 
   gcCollectMethodCalled = m.MethodsCalled.Intersect(gcCollectMethods)
}

//<Description>
// It is preferable to avoid calling **GC.Collect()** 
// explicitly in order to avoid some performance pitfall.
//
// More in information on this here:
// http://blogs.msdn.com/ricom/archive/2004/11/29/271829.aspx
//
// This rule matches application methods that call an
// overload of the method *GC.Collect()*.
//</Description>

//<HowToFix>
// Remove matched calls to *GC.Collect()*.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Don't call GC.Collect() without calling GC.WaitForPendingFinalizers()</Name>
warnif count > 0 

let gcCollectMethods = ThirdParty.Methods.WithFullNameWildcardMatch(
   "System.GC.Collect(*)").ToHashSet()

from m in Application.Methods.UsingAny(gcCollectMethods) where
  !m.IsUsing ("System.GC.WaitForPendingFinalizers()".AllowNoMatch())
select new { 
   m, 
   gcCollectMethodCalled = m.MethodsCalled.Intersect(gcCollectMethods)
}

//<Description>
// It is preferable to avoid calling **GC.Collect()** 
// explicitly in order to avoid some performance 
// pitfall. This situation is checked through the 
// default rules: *Remove calls to GC.Collect()*
//
// But if you wish to call *GC.Collect()* anyway, 
// you must do it this way:
//
//   GC.Collect();
//
//   GC.WaitForPendingFinalizers();
//
//   GC.Collect();
//
// To make sure that finalizer got executed, and 
// object with finalizer got cleaned properly.
//
// This rule matches application methods that call an
// overload of the method *GC.Collect()*, without calling
// *GC.WaitForPendingFinalizers()*.
//</Description>

//<HowToFix>
// To fix a violation of this rule, if you really
// need to call *GC.Collect()*, make sure to call
// *GC.WaitForPendingFinalizers()* properly.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Enum Storage should be Int32</Name>
warnif count > 0 from f in Fields where 
   f.Name == @"value__" && 
  !f.FieldTypeIs ("System.Int32".AllowNoMatch()) &&
  !f.IsThirdParty
select new { f, f.SizeOfInst, f.FieldType }

//<Description>
// An enumeration is a value type that defines a set of related named constants. 
// By default, the **System.Int32** data type is used to store the constant value.
//
// Even though you can change this underlying type, it is not necessary or 
// recommended for most scenarios. Note that *no significant performance gain* is 
// achieved by using a data type that is smaller than *Int32*. If you cannot use 
// the default data type, you should use one of the Common Language System 
// (CLS)-compliant integral types, *Byte*, *Int16*, *Int32*, or *Int64* to make 
// sure that all values of the enumeration can be represented in CLS-compliant 
// programming languages.
//
// This rule matches enumerations whose underlying type used to store
// values is not *System.Int32*.
//</Description>

//<HowToFix>
// To fix a violation of this rule, unless size or compatibility issues exist, 
// use *Int32*. For situations where *Int32* is not large enough to hold the values, 
// use *Int64*. If backward compatibility requires a smaller data type, use 
// *Byte* or *Int16*.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Do not raise too general exception types</Name>
                    
warnif count > 0 from m in Application.Methods where
  // Test for non-constructor, else this rule 
  // would warn on ctor of classes that derive 
  // from these exception types.
 !m.IsConstructor && (

    m.CreateA("System.Exception".AllowNoMatch()) ||
    m.CreateA("System.ApplicationException".AllowNoMatch()) ||
    m.CreateA("System.SystemException".AllowNoMatch()) )
select m

//<Description>
// The following exception types are too general 
// to provide sufficient information to the user: 
//
// • System.Exception
//
// • System.ApplicationException
//
// • System.SystemException
//
// If you throw such a general exception type in a library or framework, 
// it forces consumers to catch all exceptions, 
// including unknown exceptions that they do not know how to handle.
//
// This rule matches methods that create an instance of
// such general exception class.
//</Description>

//<HowToFix>
// To fix a violation of this rule, change the type of the thrown exception 
// to either a more derived type that already exists in the framework, 
// or create your own type that derives from *System.Exception*.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Do not raise reserved exception types</Name> 
warnif count > 0 

let reservedExceptions = ThirdParty.Types.WithFullNameIn(   
   "System.ExecutionEngineException",
   "System.IndexOutOfRangeException",
   "System.NullReferenceException",
   "System.OutOfMemoryException",
   "System.StackOverflowException",
   "System.InvalidProgramException",
   "System.AccessViolationException",
   "System.CannotUnloadAppDomainException",
   "System.BadImageFormatException",
   "System.DataMisalignedException")

from m in Application.Methods.ThatCreateAny(reservedExceptions)
let reservedExceptionsCreated = reservedExceptions.Where(t => m.IsUsing(t))
select new { m, reservedExceptionsCreated }

//<Description>
// The following exception types are reserved
// and should be thrown only by the Common Language Runtime:
//
// • System.ExecutionEngineException
//
// • System.IndexOutOfRangeException
//
// • System.NullReferenceException
//
// • System.OutOfMemoryException
//
// • System.StackOverflowException
//
// • System.InvalidProgramException
//
// • System.AccessViolationException
//
// • System.CannotUnloadAppDomainException
//
// • System.BadImageFormatException
//
// • System.DataMisalignedException
//
// Do not throw an exception of such reserved type.
//
// This rule matches methods that create an instance of
// such reserved exception class.
//</Description>

//<HowToFix>
// To fix a violation of this rule, change the type of the 
// thrown exception to a specific type that is not one of 
// the reserved types.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Use integral or string argument for indexers</Name>
warnif count > 0
from m in Application.Methods where 
  m.IsIndexerGetter && 
 !( (m.Name == @"get_Item(String)") || 
     m.NameLike (@"get_Item\(Int") || 
     m.NameLike (@"get_Item\(Byte") ||
     m.NameLike (@"get_Item\(SByte") )
select m

//<Description>
// Indexers, that is, indexed properties, should use *integer* or *string*
// types for the index. These types are typically used for indexing data 
// structures and increase the usability of the library. Use of the *Object*
// type should be restricted to those cases where the specific *integer* or 
// *string* type cannot be specified at design time. If the design requires 
// other types for the index, reconsider whether the type represents a 
// logical data store. If it does not represent a logical data store, 
// use a method.
//
// This rule matches indexer getter methods that whose index type
// is not *string*, *int*, *byte* or *sbyte*.
//</Description>

//<HowToFix>
// To fix a violation of this rule, change the index to an *integer* or *string*
// type, or use a method instead of the indexer.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Uri fields should be of type System.Uri</Name>          
warnif count > 0 from f in Application.Fields where 
  (f.NameLike (@"Uri$") || 
   f.NameLike (@"Url$")) && 
  !f.FieldTypeIs ("System.Uri".AllowNoMatch())
select new { 
   f, 
   f.FieldType
}

//<Description>
// A field with the name ending with *'Uri'* or *'Url'* is deemed 
// to represent a *Uniform Resource Identifier or Locator*.
// Such field should be of type **System.Uri**.
//
// This rule matches fields with the name ending with *'Uri'* or 
// *'Url'* that are not typed with *System.Uri*.
//</Description>

//<HowToFix>
// Rename the field, or change the field type to *System.Uri*.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types should not extend System.ApplicationException</Name>          
warnif count > 0 from t in Application.Types where
  t.DeriveFrom("System.ApplicationException".AllowNoMatch())
select t

//<Description>
// At .NET Framework version 1 time, it was 
// recommended to derive new exceptions from 
// *ApplicationException*. 
//
// The recommendation has changed and new 
// exceptions should derive from **System.Exception**
// or one of its subclasses in the *System* namespace.
//
// This rule matches application exception classes
// that derive from *ApplicationException*.
//</Description>

//<HowToFix>
// Make sure that matched exception types, 
// derive from **System.Exception** or one of its 
// subclasses in the *System* namespace.
//</HowToFix>]]></Query>
      </Group>
      <Group Name="System.Collection" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Collection properties should be read only</Name>
warnif count > 0

// First find collectionTypes 
let collectionInterfaces = ThirdParty.Types.WithFullNameIn(
      "System.Collections.ICollection", 
      "System.Collections.Generic.ICollection<T>")
where collectionInterfaces.Count() > 0
let collectionTypes = Types.ThatImplementAny(collectionInterfaces)
                           .Union(collectionInterfaces)
                           .ToHashSet()

// Then find all property setters that have an associated 
// getter that returns a collection type.
from propGetter in Application.Methods.Where(
   m => m.IsPropertyGetter && 
        m.ReturnType != null &&
        collectionTypes.Contains(m.ReturnType))

let propSetter = propGetter.ParentType.Methods.WithSimpleName(
      propGetter.SimpleName.Replace("get_","set_")
   ).FirstOrDefault()

where  propSetter != null &&
      !propSetter.IsPrivate &&
      !propSetter.ParentType.IsPrivate  // ignore setters of private types

select new { 
   propSetter, 
   CollectionType = propGetter.ReturnType 
}

//<Description>
// A writable collection property allows a user to replace the collection with 
// a completely different collection. A read-only property stops the collection 
// from being replaced but still allows the individual members to be set. If 
// replacing the collection is a goal, the preferred *design pattern* is to include
// a method to remove all the elements from the collection and a method to 
// re-populate the collection. See the *Clear()* and *AddRange()* methods of the 
// *System.Collections.Generic.List<T>* class for an example of this pattern.
// 
// Both binary and XML serialization support read-only properties that are 
// collections. The *System.Xml.Serialization.XmlSerializer* class has specific 
// requirements for types that implement *ICollection* and *System.Collections.IEnumerable*
// in order to be serializable.
//
// This rule matches property setter methods that assign a collection object.
//</Description>

//<HowToFix>
// To fix a violation of this rule, make the property read-only and, if 
// the design requires it, add methods to clear and re-populate the collection.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Don't use .NET 1.x HashTable and ArrayList</Name>
warnif count > 0 
let forbiddenTypes = ThirdParty.Types.WithFullNameIn(
   "System.Collections.HashTable", 
   "System.Collections.ArrayList",
   "System.Collections.Queue",
   "System.Collections.Stack",
   "System.Collections.SortedList")
where forbiddenTypes.Count() > 0
from m in Application.Methods.ThatCreateAny(forbiddenTypes)
select m

//<Description>
// This rule warns about application methods that use a non-generic 
// collection class, including **ArrayList**, **HashTable**, **Queue**, 
// **Stack** or **SortedList**.
//</Description>

//<HowToFix>
// **List<T>** should be preferred over **ArrayList**.
// It is generic hence you get strongly typed elements.
// Also, it is faster with *T* as a value types since it avoids boxing.
//
// For the same reasons:
//
// • **Dictionary<K,V>** should be prevered over **HashTable**.
//
// • **Queue<T>** should be prevered over **Queue**.
//
// • **Stack<T>** should be prevered over **Stack**.
//
// • **SortedDictionary<K,V>** or **SortedList<K,V>** should be prevered over **SortedList**.
//
// You can be forced to use *non generic* collections
// because you are using third party code that requires 
// working with these classes or because you are 
// coding with .NET 1.x, but nowadays this situation should
// question about using newer updates of .NET.
// .NET 1.x is an immature platform conpared to newer .NET
// updates.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Caution with List.Contains()</Name>
let containsMethods = ThirdParty.Methods.WithFullNameIn(
   "System.Collections.Generic.List<T>.Contains(T)",
   "System.Collections.Generic.IList<T>.Contains(T)",
   "System.Collections.ArrayList.Contains(Object)")

from m in Application.Methods.UsingAny(containsMethods) 
select m

//<Description>
// This code query matches calls to *List<T>.Contains()* method.
//
// The cost of checking if a list contains an object is proportional 
// to the size of the list. In other words it is a *O(N)* operation. 
// For large lists and/or frequent calls to *Contains()*, prefer using  
// the *System.Collections.Generic.HashSet<T>* class 
// where calls to *Contains()* take a constant 
// time (*O(0)* operation).
//
// This code query is not a code rule, because more often than not, 
// calling *O(N) Contains()* is not a mistake. This code query
// aims at pointing out this potential performance pitfall.
//</Description>]]></Query>
        <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Prefer return collection abstraction instead of implementation</Name>
let implTypes = ThirdParty.Types.WithFullNameIn(
   "System.Collections.Generic.List<T>",
   "System.Collections.Generic.HashSet<T>",
   "System.Collections.Generic.Dictionary<TKey,TValue>")

from m in Application.Methods.WithReturnTypeIn(implTypes) 
select new { m, m.ReturnType }

//<Description>
// This code query matches methods that return a 
// collection implementation, such as *List<T>*
// *HashSet<T>* or *Dictionary<TKey,TValue>*.
//
// Most often than not, clients of a method don't 
// need to know the exact implementation of the 
// collection returned. It is preferable to return 
// a collection interface such as *IList<T>*, 
// *ICollection<T>*, *IEnumerable<T>* or
// *IDictionary<TKey,TValue>*.
//
// Using the collection interface instead of the 
// implementation shouldn't applies to all cases, 
// hence this code query is not code rule.
//</Description>]]></Query>
      </Group>
      <Group Name="System.Runtime.InteropServices" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>P/Invokes should be static and not be visible</Name>
warnif count > 0 from m in Application.Methods where
  !m.IsThirdParty &&
  (m.HasAttribute ("System.Runtime.InteropServices.DllImportAttribute".AllowNoMatch())) &&
  ( m.IsPublic || 
   !m.IsStatic)
select new { m, m.Visibility, m.IsStatic }

//<Description>
// Methods that are marked with the **DllImportAttribute** attribute 
// (or methods that are defined by using the **Declare** keyword in Visual Basic) 
// use **Platform Invocation Services** to access unmanaged code.
//
// Such methods should not be exposed. By keeping these methods *private* or *internal*,
// you make sure that your library cannot be used to breach security by allowing 
// callers access to unmanaged APIs that they could not call otherwise.
//
// This rule matches methods tagged with *DllImportAttribute* attribute
// that are declared as *public* or declared as *non-static*.
//</Description>

//<HowToFix>
// To fix a violation of this rule, change the access level of the method
// and/or declare it as static.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Move P/Invokes to NativeMethods class</Name>
warnif count > 0 from m in Application.Methods where
   m.HasAttribute ("System.Runtime.InteropServices.DllImportAttribute".AllowNoMatch()) &&
   m.ParentType.SimpleName != "NativeMethods"
select m

//<Description>
// **Platform Invocation methods**, such as those that are marked by using the 
// **System.Runtime.InteropServices.DllImportAttribute** attribute, or methods 
// that are defined by using the **Declare** keyword in Visual Basic, access 
// unmanaged code. These methods should be in one of the following classes:
//
// • **NativeMethods** - This class does not suppress stack walks for unmanaged 
// code permission. (*System.Security.SuppressUnmanagedCodeSecurityAttribute*
// must not be applied to this class.) This class is for methods that can be 
// used anywhere because a stack walk will be performed.
//
// • **SafeNativeMethods** - This class suppresses stack walks for unmanaged 
// code permission. (*System.Security.SuppressUnmanagedCodeSecurityAttribute*
//is applied to this class.) This class is for methods that are safe for anyone 
// to call. Callers of these methods are not required to perform a full security 
// review to make sure that the usage is secure because the methods are harmless 
// for any caller.
//
// • **UnsafeNativeMethods** - This class suppresses stack walks for unmanaged 
// code permission. (*System.Security.SuppressUnmanagedCodeSecurityAttribute*
// is applied to this class.) This class is for methods that are potentially 
// dangerous. Any caller of these methods must perform a full security review 
// to make sure that the usage is secure because no stack walk will be performed.
//
// These classes are declared as *static internal*. The methods in these 
// classes are *static* and *internal*.
//
// This rule matches *P/Invoke* methods not declared in such *NativeMethods*
// class.
//</Description>

//<HowToFix>
// To fix a violation of this rule, move the method to the appropriate 
// **NativeMethods** class. For most applications, moving P/Invokes to a new 
// class that is named **NativeMethods** is enough.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>NativeMethods class should be static and internal</Name>
warnif count > 0 from t in Application.Types.WithNameIn(
   @"NativeMethods", "SafeNativeMethods", "UnsafeNativeMethods") where
   t.IsPublic || !t.IsStatic
select new { t, t.Visibility, t.IsStatic }

//<Description>
// In the description of the default rule *Move P/Invokes to NativeMethods class*
// it is explained that *NativeMethods* classes that host *P/Invoke* methods,
// should be declared as *static* and *internal*.
//
// This code rule warns about *NativeMethods* classes that are not declared
// *static* and *internal*.
//</Description>

//<HowToFix>
// Matched *NativeMethods* classes must be declared as *static* and *internal*.
//</HowToFix>]]></Query>
      </Group>
      <Group Name="System.Threading" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Method non-synchronized that read mutable states</Name>
from m in Application.Methods where 
 (m.ReadsMutableObjectState || m.ReadsMutableTypeState) && 
 !m.IsUsing ("System.Threading.Monitor".AllowNoMatch()) && 
 !m.IsUsing ("System.Threading.ReaderWriterLock".AllowNoMatch())
select new {
   m, 
   mutableFieldsUsed = m.FieldsUsed.Where(f => !f.IsImmutable)
}

//<Description>
// Mutable object states are instance fields that 
// can be modified through the lifetime of the object.
//
// Mutable type states are static fields that can be 
// modified through the lifetime of the program.
//
// This query lists methods that read mutable state 
// without synchronizing access. In the case of 
// multi-threaded program, doing so can lead to 
// state corruption.
//
// This code query is not a code rule because more often
// than not, a match of this query is not an issue.
//</Description>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Don't create threads explicitly</Name>
warnif count > 0 from m in Application.Methods where 
  m.CreateA ("System.Threading.Thread".AllowNoMatch())
select m

//<Description>
// This code rule warns about methods that create *threads* explicitly
// by creating an instance of the class *System.Threading.Thread*.
//
// Prefer using the thread pool instead of creating manually your 
// own threads. Threads are costly objects. They take approximately 
// 200,000 cycles to create and about 100,000 cycles to destroy.  
// By default they reserve 1 Mega Bytes of virtual memory for its 
// stack and use 2,000-8,000 cycles for each context switch.
//
// As a consequence, it is preferable to let the thread pool 
// recycle threads.
//</Description>

//<HowToFix>
// Instead of creating explicitly threads, use the **Task Parralel 
// Library** *(TPL)* that relies on the CLR thread pool.
// 
// Introduction to TPL: https://msdn.microsoft.com/en-us/library/dd460717(v=vs.110).aspx
//
// TPL and the CLR v4 thread pool:
// http://www.danielmoth.com/Blog/New-And-Improved-CLR-4-Thread-Pool-Engine.aspx
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Don't use dangerous threading methods</Name>
warnif count > 0 

let wrongMethods = ThirdParty.Methods.WithFullNameIn(

  "System.Threading.Thread.Abort()",
  "System.Threading.Thread.Abort(Object)",
     
  "System.Threading.Thread.Sleep(Int32)",

  "System.Threading.Thread.Suspend()",
  "System.Threading.Thread.Resume()")

from m in Application.Methods.UsingAny(wrongMethods)
select new { 
   m, 
   suppressCallsTo = m.MethodsCalled.Intersect(wrongMethods) 
}

//<Description>
// This rule warns about using the methods
// *Abort()*, *Sleep()*, *Suspend()* or *Resume()*
// declared by the *Thread* class.
//
// • Usage of *Thread.Abort()* is dangerous.
// More information on this here:
// http://www.interact-sw.co.uk/iangblog/2004/11/12/cancellation
//
// • Usage of *Thread.Sleep()* is a sign of 
// flawed design. More information on this here:
// http://msmvps.com/blogs/peterritchie/archive/2007/04/26/thread-sleep-is-a-sign-of-a-poorly-designed-program.aspx
//
// • *Suspend()* and *Resume()* are dangerous threading methods, marked as obsolete.
// More information on workaround here:
// http://stackoverflow.com/questions/382173/what-are-alternative-ways-to-suspend-and-resume-a-thread  
//</Description>

//<HowToFix>
// Suppress calls to *Thread* methods exposed in the 
// *suppressCallsTo* column in the rule result.
//
// Use instead facilities offered by the **Task Parralel 
// Library** *(TPL)* :
// https://msdn.microsoft.com/en-us/library/dd460717(v=vs.110).aspx
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Monitor TryEnter/Exit must be both called within the same method</Name>
warnif count > 0 

let enterMethods = ThirdParty.Methods.WithFullNameWildcardMatchIn(
   "System.Threading.Monitor.Enter(*",
   "System.Threading.Monitor.TryEnter(*")

from m in Application.Methods.UsingAny(enterMethods) where
 !m.IsUsing ("System.Threading.Monitor.Exit(Object)".AllowNoMatch())
select new { 
   m, 
   enterMethodsCalled = m.MethodsCalled.Intersect(enterMethods) 
}

//<Description>
// This rule warns when **System.Threading.Monitor** *Enter()* 
// (or *TryEnter()*) and *Exit() methods are not called within 
// the same method.
//
// Doing so makes the code *less readable*, because it gets harder
// to locate when **critical sections** begin and end.
//
// Also, you expose yourself to complex and error-prone scenarios.
//</Description>

//<HowToFix>
// Refactor matched methods to make sure that *Monitor critical 
// sections* begin and end within the same method. Basics scenarios 
// can be handled through the C# **lock** keyword. Using explicitly 
// the class *Monitor* should be left for advanced situations, 
// that require calls to methods like *Wait()* and *Pulse()*.
//
// More information on using the *Monitor* class can be found here:
// http://www.codeproject.com/Articles/13453/Practical-NET-and-C-Chapter
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>ReaderWriterLock AcquireLock/ReleaseLock must be both called within the same method</Name>
warnif count > 0 

let acquireLockMethods = ThirdParty.Methods.WithFullNameWildcardMatch(
    "System.Threading.ReaderWriterLock.Acquire*Lock(*")

let releaseLockMethods = ThirdParty.Methods.WithFullNameWildcardMatch(
    "System.Threading.ReaderWriterLock.Release*Lock(*")

from m in Application.Methods.UsingAny(acquireLockMethods)
  .Except(Application.Methods.UsingAny(releaseLockMethods))
select new { 
   m, 
   acquireLockMethods = m.MethodsCalled.Intersect(acquireLockMethods) 
}

//<Description>
// This rule warns when **System.Threading.ReaderWriterLock** 
// acquire and release, reader or writer locks methods are not called 
// within the same method.
//
// Doing so makes the code *less readable*, because it gets harder
// to locate when **critical sections** begin and end.
//
// Also, you expose yourself to complex and error-prone scenarios.
//</Description>

//<HowToFix>
// Refactor matched methods to make sure that *ReaderWriterLock 
// read or write critical sections* begin and end within the 
// same method.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="True"><![CDATA[// <Name>Don't tag instance fields with ThreadStaticAttribute</Name>
warnif count > 0
from f in Application.Fields 
where !f.IsStatic && 
       f.HasAttribute ("System.ThreadStaticAttribute".AllowNoMatch())
select f

//<Description>
// This rule warns when the attribute **System.ThreadStaticAttribute**
// is tagging *instance* fields. As explained in documentation, this attribute
// is designed to tag only *static* fields.
// https://msdn.microsoft.com/en-us/library/system.threadstaticattribute
//</Description>

//<HowToFix>
// Refactor the code to make sure that all fields tagged with 
// *ThreadStaticAttribute* are *static*.
//</HowToFix>]]></Query>
      </Group>
      <Group Name="System.Xml" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Method should not return concrete XmlNode</Name>
warnif count > 0 

let concreteXmlTypes = ThirdParty.Types.ThatDeriveFromAny(
                       ThirdParty.Types.WithFullName("System.Xml.XmlNode"))

from m in Application.Methods.WithReturnTypeIn(concreteXmlTypes)
select new { m, m.ReturnType }

//<Description>
// This rule warns about method whose return type is
// **System.Xml.XmlNode** or any type derived from *XmlNode*.
//
// *XmlNode* implements the interface **System.Xml.Xpath.IXPathNavigable**.
// In most situation, returning this interface instead of the concrete
// type is a better *design* choice that will abstract client code
// from implementation details.
//</Description>

//<HowToFix>
// To fix a violation of this rule, change the concrete returned type 
// to the suggested interface *IXPathNavigable*.
//</HowToFix>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types should not extend System.Xml.XmlDocument</Name>
warnif count > 0 from t in Application.Types where
  t.DeriveFrom("System.Xml.XmlDocument".AllowNoMatch())
select t

//<Description>
// This rule warns aboud subclasses of **System.Xml.XmlDocument**.
//
// Do not create a subclass of *XmlDocument* if you want to 
// create an XML view of an underlying object model or data source.
//</Description>

//<HowToFix>
// Instead of subclassing *XmlDocument*, you can use the interface 
// **System.Xml.XPath.IXPathNavigable** implemented by the class 
// *XmlDocument*.
//
// An alternative of using *XmlDocument*, is to use 
// **System.Xml.Linq.XDocument**, aka **LINQ2XML**. 
// More information on this can be found here: 
// http://stackoverflow.com/questions/1542073/xdocument-or-xmldocument
//</HowToFix>]]></Query>
      </Group>
      <Group Name="System.Globalization" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Float and Date Parsing must be culture aware</Name>
warnif count > 0 
from m in ThirdParty.Types.WithFullNameIn( 
             "System.DateTime", 
             "System.Single", 
             "System.Double",
             "System.Decimal").ChildMethods()
  where  m.NbParameters > 0 &&
        (m.SimpleName.EqualsAny(
           "Parse", "TryParse", "ToString")) &&
        !m.Name.Contains("IFormatProvider")
select new { 
   m, 
   m.MethodsCallingMe 
}

//<Description>
// Globalization is the design and development of applications that support 
// localized user interfaces and regional data for users in multiple cultures.
//
// This rule warns about the usage of *non-globalized overloads* of
// the methods **Parse()**, **TryParse()** and **ToString()**, 
// of the types **DateTime**, **float**, **double** and **decimal**.
// This is the symptom that your application is *at least partially* 
// not globalized.
//
// *Non-globalized overloads* of these methods are the overloads
// that don't take a parameter of type **IFormatProvider**.
//</Description>

//<HowToFix>
// Globalize your applicaton and make sure to use the globalized overloads 
// of these methods. In the column **MethodsCallingMe** of this rule result
// are listed the methods of your application that call the 
// *non-globalized overloads*.
//
// More information on **Creating Globally Aware Applications** here:
// https://msdn.microsoft.com/en-us/library/cc853414(VS.95).aspx
//</HowToFix>]]></Query>
      </Group>
      <Group Name="Microsoft.Contracts" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Public methods returning a reference needs a contract to ensure that a non-null reference is returned</Name>
warnif count > 0
let ensureMethods = Application.Methods.WithFullName(
   "System.Diagnostics.Contracts.__ContractsRuntime.Ensures(Boolean,String,String)")

from ensureMethod in ensureMethods
from m in ensureMethod.ParentAssembly.ChildMethods where 
  m.IsPubliclyVisible &&
 !m.IsAbstract &&
  m.ReturnType != null &&
  // Identify that the return type is a reference type
  (m.ReturnType.IsClass || m.ReturnType.IsInterface) &&
 !m.IsUsing(ensureMethod) &&

  // Don't match method not implemented yet!
 !m.CreateA("System.NotImplementedException".AllowNoMatch())

select new { 
   m, 
   ReturnTypeReference = m.ReturnType 
}

//<Description>
// **Code Contracts** are useful to decrease ambiguity between callers and callees.
// Not ensuring that a reference returned by a method is *non-null* leaves ambiguity 
// for the caller. This rule matches methods returning an instance of a reference type 
// (class or interface) that don't use a **Contract.Ensure()** method.
//
// *Contract.Ensure()* is defined in the **Microsoft Code Contracts for .NET** 
// library, and is typically used to write a code contract on returned reference:
// *Contract.Ensures(Contract.Result<ReturnType>() != null, "returned reference is not null");*
// https://visualstudiogallery.msdn.microsoft.com/1ec7db13-3363-46c9-851f-1ce455f66970
//</Description>

//<HowToFix>
// Use *Microsoft Code Contracts for .NET* on the public surface of your API,
// to remove most ambiguity presented to your client. Most of such ambiguities
// are about *null* or *not null* references.
//
// Don't use *null* reference if you need to express that a method might not 
// return a result. Use instead the **TryXXX()** pattern exposed for example 
// in the *System.Int32.TryParse()* method.
//</HowToFix>]]></Query>
      </Group>
      <Group Name="Third-Party Code Elements Used" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third-Party Assemblies Used</Name>
from a in ThirdParty.Assemblies
select new { a, a.AssembliesUsingMe }

//<Description>
// This code query lists *third-party assemblies* used
// by the application analyzed.
//
// For each third-party assembly matched, the column
// *AssembliesUsingMe* of the query result contains
// application assemblies using the assembly.
//</Description>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third-Party Namespaces Used</Name>
from n in ThirdParty.Namespaces
select new { n, n.NamespacesUsingMe }

//<Description>
// This code query lists *third-party namespaces* used
// by the application analyzed.
//
// For each third-party namespace matched, the column
// *NamespacesUsingMe* of the query result contains
// application namespaces using the namespace.
//</Description>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third-Party Types Used</Name>
from t in ThirdParty.Types
select new { t, t.TypesUsingMe, t.DerivedTypes, t.TypesThatImplementMe }

//<Description>
// This code query lists *third-party types* used
// by the application analyzed.
//
// For each third-party type matched:
//
// • The column *TypesUsingMe* of the query result contains
// application types using the third-party type.
//
// • The column *DerivedTypes* of the query result contains
// application sub-classes of the third-party class.
//
// • The column *TypesThatImplementMe* of the query result 
// contains application classes that implement the third-party interface.
//</Description>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third-Party Methods Used</Name>
from m in ThirdParty.Methods
select new { m, m.MethodsCallingMe }

//<Description>
// This code query lists *third-party methods* called
// by the application analyzed.
//
// For each third-party method matched, the column
// *MethodsCallingMe* of the query result contains
// application methods that call the method.
//</Description>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Third-Party Fields Used</Name>
from f in ThirdParty.Fields
where !f.ParentType.IsEnumeration
select new { f, f.MethodsReadingMeButNotAssigningMe, f.MethodsAssigningMe  }

//<Description>
// This code query lists *third-party fields* called
// by the application analyzed.
//
// For each third-party field matched, the column
// *MethodsReadingMeButNotAssigningMe* and *MethodsAssigningMe* 
// of the query result contains application methods that read 
// or assign the field.
//</Description>]]></Query>
      </Group>
    </Group>
    <Group Name="Trend Metrics" Active="True" ShownInReport="False">
      <Group Name="Code Size" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Code" Unit="LoC" />  
Application.Assemblies.Sum(a => a.NbLinesOfCode)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Code (JustMyCode)" Unit="LoC" />
JustMyCode.Methods.Sum(m => m.NbLinesOfCode)

// JustMyCode is defined by code queries prefixed with 'notmycode' 
// in the group 'Defining JustMyCode'.
]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Code (NotMyCode)" Unit="LoC" />
Application.Methods.Where(m => !JustMyCode.Contains(m))
                   .Sum(m => m.NbLinesOfCode)

// JustMyCode is defined by code queries prefixed with 'notmycode' 
// in the group 'Defining JustMyCode'.
]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Code Added since the Baseline" Unit="LoC" />  
( from a in Application.Assemblies
  let nbLocAdded = !a.IsPresentInBothBuilds()
                   ? a.NbLinesOfCode
                   : (a.NbLinesOfCode != null && a.OlderVersion().NbLinesOfCode != null)
                   ? a.NbLinesOfCode - (int)a.OlderVersion().NbLinesOfCode 
                   : 0
  select nbLocAdded)
.Sum(loc => loc)

// A value is computed by this Trend Metric query
// only if a Baseline for Comparison is provided.
// See Project Properties > Analysis > Baseline for Comparison
]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Source Files" Unit="Source Files" />
Application.Assemblies.SelectMany(
  a => a.SourceDecls.Select(sd => sd.SourceFile.FilePathString.ToLower()))
.Distinct()
.Count()

// If a value 0 is obtained, it means that at analysis time,
// assemblies PDB files were not available.
// http://www.ndepend.com/docs/ndepend-analysis-inputs-explanation
]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# IL Instructions" Unit="IL Instructions" />
Application.Assemblies.Sum(a => a.NbILInstructions)
]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# IL Instructions (NotMyCode)" Unit="IL Instructions" />
Application.Methods.Where(m => !JustMyCode.Contains(m))
                   .Sum(m => m.NbILInstructions)

// JustMyCode is defined by code queries prefixed with 'notmycode' 
// in the group 'Defining JustMyCode'.
]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Comments" Unit="Lines" />  
Application.Assemblies.Sum(a => a.NbLinesOfComment)

// So far comments are only extracted from C# source code.
]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Assemblies" Unit="Assemblies" />
Application.Assemblies.Count()]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Namespaces" Unit="Namespaces" />
Application.Namespaces.Count()]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Types" Unit="Types" />
Application.Types.Count(t => !t.IsGeneratedByCompiler)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Public Types" Unit="Types" />
Application.Types.Where(t => t.IsPubliclyVisible && !t.IsGeneratedByCompiler).Count()]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Classes" Unit="Types" />
Application.Types.Count(t => t.IsClass && !t.IsGeneratedByCompiler)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Abstract Classes" Unit="Types" />
Application.Types.Count(t => t.IsClass && t.IsAbstract && !t.IsGeneratedByCompiler)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Interfaces" Unit="Types" />
Application.Types.Count(t => t.IsInterface)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Structures" Unit="Types" />
Application.Types.Count(t => t.IsStructure && !t.IsGeneratedByCompiler)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Methods" Unit="Methods" />
Application.Methods.Count(m => !m.IsGeneratedByCompiler)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Abstract Methods" Unit="Methods" />
Application.Methods.Count(m => m.IsAbstract)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Concrete Methods" Unit="Methods" />
Application.Methods.Count(m => !m.IsAbstract && !m.IsGeneratedByCompiler)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Fields" Unit="Fields" />
Application.Fields.Count(f => 
   !f.IsEnumValue && 
   !f.IsGeneratedByCompiler && 
   !f.IsLiteral &&
   !f.ParentType.IsEnumeration)]]></Query>
      </Group>
      <Group Name="Maximum and Average" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Max # Lines of Code for Methods (JustMyCode)" Unit="LoC" />
JustMyCode.Methods
          .Max(m => m.NbLinesOfCode)
          .ToEnumerable().Sum(loc => loc)

// Here is the code query to get the (JustMyCode) method with largest # Lines of Code
// JustMyCode.Methods.OrderByDescending(m => m.NbLinesOfCode).Take(1).Select(m => new {m, m.NbLinesOfCode})]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average # Lines of Code for Methods" Unit="LoC" />
Application.Methods.Where(m => m.NbLinesOfCode > 0)
                   .Average(m => m.NbLinesOfCode)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average # Lines of Code for Methods with at least 3 Lines of Code" Unit="LoC" />
Application.Methods.Where(m => m.NbLinesOfCode >= 3)
                   .Average(m => m.NbLinesOfCode)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Max # Lines of Code for Types (JustMyCode)" Unit="LoC" />
JustMyCode.Types
          .Max(t => t.NbLinesOfCode)
          .ToEnumerable().Sum(loc => loc)

// Here is the code query to get the (JustMyCode) type with largest # Lines of Code
// JustMyCode.Types.OrderByDescending(t => t.NbLinesOfCode).Take(1).Select(t => new {t, t.NbLinesOfCode})]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average # Lines of Code for Types" Unit="LoC" />
Application.Types.Where(t => t.NbLinesOfCode > 0)
                 .Average(t => t.NbLinesOfCode)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Max Cyclomatic Complexity for Methods" Unit="Paths" />
Application.Methods
          .Max(m => m.CyclomaticComplexity)
          .ToEnumerable().Sum(loc => loc)

// Here is the code query to get the most complex method, according to Cyclomatic Complexity
// Application.Methods.OrderByDescending(m => m.CyclomaticComplexity).Take(1).Select(m => new {m, m.CyclomaticComplexity})]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average Cyclomatic Complexity for Methods" Unit="Paths" />
Application.Methods.Where(m => m.NbLinesOfCode> 0)
                   .Average(m => m.CyclomaticComplexity)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Max IL Cyclomatic Complexity for Methods" Unit="Paths" />
Application.Methods
          .Max(m => m.ILCyclomaticComplexity)
          .ToEnumerable().Sum(loc => loc)

// Here is the code query to get the most complex method, according to Cyclomatic Complexity computed from IL code.
// Application.Methods.OrderByDescending(m => m.ILCyclomaticComplexity).Take(1).Select(m => new {m, m.CyclomaticComplexity})]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average IL Cyclomatic Complexity for Methods" Unit="Paths" />
Application.Methods.Where(m => m.NbILInstructions> 0)
                   .Average(m => m.ILCyclomaticComplexity)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Max IL Nesting Depth for Methods" Unit="Scopes" />
Application.Methods
          .Max(m => m.ILNestingDepth)
          .ToEnumerable().Sum(loc => loc)

// Here is the code query to get the method with highest ILNestingDepth.
// Application.Methods.OrderByDescending(m => m.ILNestingDepth).Take(1).Select(m => new {m, m.ILNestingDepth})]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average IL Nesting Depth for Methods" Unit="Scopes" />
Application.Methods.Where(m => m.NbILInstructions> 0)
                   .Average(m => m.ILNestingDepth)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Max # of Methods for Types" Unit="Methods" />
Application.Types
           .Max(t => t.NbMethods) 
           .ToEnumerable().Sum(loc => loc)

// Here is the code query to get the (JustMyCode) type with largest # of Methods
// JustMyCode.Types.OrderByDescending(t => t.NbMethods).Take(1).Select(t => new {t, t.Methods})]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average # Methods for Types" Unit="Methods" />
Application.Types.Average(t => t.NbMethods)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Max # of Methods for Interfaces" Unit="Methods" />
Application.Types.Where(t => t.IsInterface)
           .Max(t => t.NbMethods) 
           .ToEnumerable().Sum(loc => loc)

// Here is the code query to get the (JustMyCode) type with largest # of Methods
// JustMyCode.Types.OrderByDescending(t => t.NbMethods).Take(1).Select(t => new {t, t.Methods})]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average # Methods for Interfaces" Unit="Methods" />
JustMyCode.Types.Where(t => t.IsInterface)
                .Average(t => t.NbMethods)]]></Query>
      </Group>
      <Group Name="Code Coverage" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Percentage Code Coverage" Unit="%" />
((float)Application.Assemblies.Sum(a => a.NbLinesOfCodeCovered) /
        Application.Assemblies.Sum(a => a.NbLinesOfCode)
 * 100f)
.ToEnumerable().Sum()]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Code Covered" Unit="LoC" />
Application.Assemblies.Sum(a => a.NbLinesOfCodeCovered)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Code Not Covered" Unit="LoC" />
Application.Assemblies.Sum(a => a.NbLinesOfCodeNotCovered)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Code in Types 100% Covered" Unit="LoC" />
Application.Types.Where(t => t.PercentageCoverage == 100)
           .Sum(t => t.NbLinesOfCodeCovered)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Lines of Code in Methods 100% Covered" Unit="LoC" />
Application.Methods.Where(m => m.PercentageCoverage == 100)
           .Sum(m => m.NbLinesOfCodeCovered)]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Max C.R.A.P Score" />

(from m in JustMyCode.Methods

// Don't match too short methods
where m.NbLinesOfCode > 10

let CC = m.CyclomaticComplexity
let uncov = (100 - m.PercentageCoverage) / 100f
let CRAP = (CC * CC * uncov * uncov * uncov) + CC
where CRAP != null && CRAP > 30 select CRAP)
.Max(CRAP => CRAP)

//<Description>
// **Change Risk Analyzer and Predictor** (i.e. CRAP) is a code metric
// that helps in pinpointing overly complex and untested code.
// Is has been first defined here: 
// http://www.artima.com/weblogs/viewpost.jsp?thread=215899
//
// The Formula is:  **CRAP(m) = CC(m)^2 * (1 – cov(m)/100)^3 + CC(m)**
//
// • where *CC(m)* is the *cyclomatic complexity* of the method *m*
//
// • and *cov(m)* is the *percentage coverage* by tests of the method *m*
//
// Matched methods cumulates two highly *error prone* code smells:
//
// • A complex method, difficult to develop and maintain.
//
// • Non 100% covered code, difficult to refactor without any regression bug.
//
// The highest the CRAP score, the more painful to maintain and error prone is the method.
//
// An arbitrary threshold of 30 is fixed for this code rule as suggested by inventors.
//
// Notice that no amount of testing will keep methods with a Cyclomatic Complexity
// highest than 30, out of CRAP territory.
//
// Notice that CRAP score is not computed for too short methods
// with less than 10 lines of code.
//
// To list methods with highest C.R.A.P scores, please refer to the default rule:
//   *Test and Code Coverage* > *C.R.A.P method code metric*
//</Description>]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="Average C.R.A.P Score" />

(from m in JustMyCode.Methods

// Don't match too short methods
where m.NbLinesOfCode > 10

let CC = m.CyclomaticComplexity
let uncov = (100 - m.PercentageCoverage) / 100f
let CRAP = (CC * CC * uncov * uncov * uncov) + CC
where CRAP != null && CRAP > 30 select CRAP)
.Average(CRAP => CRAP)

//<Description>
// **Change Risk Analyzer and Predictor** (i.e. CRAP) is a code metric
// that helps in pinpointing overly complex and untested code.
// Is has been first defined here: 
// http://www.artima.com/weblogs/viewpost.jsp?thread=215899
//
// The Formula is:  **CRAP(m) = CC(m)^2 * (1 – cov(m)/100)^3 + CC(m)**
//
// • where *CC(m)* is the *cyclomatic complexity* of the method *m*
//
// • and *cov(m)* is the *percentage coverage* by tests of the method *m*
//
// Matched methods cumulates two highly *error prone* code smells:
//
// • A complex method, difficult to develop and maintain.
//
// • Non 100% covered code, difficult to refactor without any regression bug.
//
// The highest the CRAP score, the more painful to maintain and error prone is the method.
//
// An arbitrary threshold of 30 is fixed for this code rule as suggested by inventors.
//
// Notice that no amount of testing will keep methods with a Cyclomatic Complexity
// highest than 30, out of CRAP territory.
//
// Notice that CRAP score is not computed for too short methods
// with less than 10 lines of code.
//
// To list methods with highest C.R.A.P scores, please refer to the default rule:
//   *Test and Code Coverage* > *C.R.A.P method code metric*
//</Description>]]></Query>
      </Group>
      <Group Name="Third-Party Usage" Active="True" ShownInReport="False">
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Third-Party Assemblies Used" Unit="Assemblies" />
ThirdParty.Assemblies.Count()]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Third-Party Namespaces Used" Unit="Namespaces" />
ThirdParty.Namespaces.Count()]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Third-Party Types Used" Unit="Types" />
ThirdParty.Types.Count()]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Third-Party Methods Used" Unit="Methods" />
ThirdParty.Methods.Count()]]></Query>
        <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <TrendMetric Name="# Third-Party Fields Used" Unit="Fields" />
ThirdParty.Fields.Count()]]></Query>
      </Group>
    </Group>
    <Group Name="Defining JustMyCode" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Discard generated Assemblies from JustMyCode</Name>
notmycode
from a in Application.Assemblies where 
// Assemblies generated for Xsl IL compilation for example are tagged with this attribute
a.HasAttribute ("System.CodeDom.Compiler.GeneratedCodeAttribute".AllowNoMatch())
select a

//<Description>
// This code query is prefixed with **notmycode**.
// This means that all application assemblies matched by this 
// code query are removed from the *code base view* **JustMyCode.Assemblies**.
// It also means that all *namespaces*, *types*, *methods* and 
// *fields* contained in a matched assembly are removed from
// the code base view *JustMyCode*.
// The code base view *JustMyCode* is used by most default code queries 
// and rules.
//
// So far this query only matches application assemblies tagged
// with *System.CodeDom.Compiler.GeneratedCodeAttribute*.
// Make sure to make this query richer to discard your generated 
// assemblies from the NDepend rules results.
//
// *notmycode* queries are executed before running others
// queries and rules. Also modifying a *notmycode* query
// provokes re-run of queries and rules that rely 
// on the *JustMyCode* code base view.
//
// Several *notmycode* queries can be written to match *assemblies*,
// in which case this results in cumulative effect.
//
// Online documentation:
// http://www.ndepend.com/docs/cqlinq-syntax#NotMyCode
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Discard generated Types from JustMyCode</Name>             
notmycode

from t in Application.Types where

  // Resources, Settings, or typed DataSet generated types for example, are tagged with this attribute
  t.HasAttribute ("System.CodeDom.Compiler.GeneratedCodeAttribute".AllowNoMatch()) ||

  // This attributes identifies a type or member that is not part of the user code for an application.
  t.HasAttribute ("System.Diagnostics.DebuggerNonUserCodeAttribute".AllowNoMatch()) ||

  // Delegate types are always generated
  t.IsDelegate ||

  // Discard ASP.NET page types generated by aspnet_compiler.exe
  // See: http://www.ndepend.com/FAQ.aspx#ASPNET
  t.ParentNamespace.Name.EqualsAny("ASP", "__ASP") ||

  // Discard types generated for code contract
  t.FullName.StartsWith("System.Diagnostics.Contracts.__ContractsRuntime") ||
  t.FullName == "System.Diagnostics.Contracts.RuntimeContractsAttribute" ||

  // Discard all types declared in a folder path containing the word "generated"
  (t.SourceFileDeclAvailable &&
   t.SourceDecls.All(s => s.SourceFile.FilePath.ParentDirectoryPath.ToString().ToLower().Contains("generated")))

select t

//<Description>
// This code query is prefixed with **notmycode**.
// This means that all application types matched by this 
// code query are removed from the *code base view* **JustMyCode.Types**.
// It also means that all *methods* and *fields* contained in a 
// matched type are removed from the code base view *JustMyCode*.
// The code base view *JustMyCode* is used by most default code queries 
// and rules.
//
// So far this query matches several well-identified generated
// types, like the ones tagged with *System.CodeDom.Compiler.GeneratedCodeAttribute*.
// Make sure to make this query richer to discard your generated 
// types from the NDepend rules results.
//
// *notmycode* queries are executed before running others
// queries and rules. Also modifying a *notmycode* query
// provokes re-run of queries and rules that rely 
// on the *JustMyCode* code base view.
//
// Several *notmycode* queries can be written to match *types*,
// in which case this results in cumulative effect.
//
// Online documentation:
// http://www.ndepend.com/docs/cqlinq-syntax#NotMyCode
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Discard generated and designer Methods from JustMyCode</Name>
notmycode 

//
// First define source files paths to discard
//
from a in Application.Assemblies 
where a.SourceFileDeclAvailable 
let asmSourceFilesPaths = a.SourceDecls.Select(s => s.SourceFile.FilePath)

let sourceFilesPathsToDiscard = (
    from filePath in asmSourceFilesPaths 
    let filePathLower= filePath.ToString().ToLower()
    where     
      filePathLower.EndsWithAny(
        ".g.cs",        // Popular pattern to name generated files.
        ".g.vb",
        ".xaml",        // notmycode WPF xaml code
        ".designer.cs", // notmycode C# Windows Forms designer code
        ".designer.vb") // notmycode VB.NET Windows Forms designer code
       ||
       // notmycode methods in source files in a directory containing generated
       filePathLower.Contains("generated")
  select filePath
).ToHashSet() 
  
//
// Second: discard methods in sourceFilesPathsToDiscard 
//
from m in a.ChildMethods
where (m.SourceFileDeclAvailable && 
       sourceFilesPathsToDiscard.Contains(m.SourceDecls.First().SourceFile.FilePath)) ||
      // Generated methods might be tagged with this attribute
      m.HasAttribute ("System.CodeDom.Compiler.GeneratedCodeAttribute".AllowNoMatch()) ||

      // This attributes identifies a type or member that is not part of the user code for an application.
      m.HasAttribute ("System.Diagnostics.DebuggerNonUserCodeAttribute".AllowNoMatch())

select new { m, m.NbLinesOfCode }

//<Description>
// This code query is prefixed with **notmycode**.
// This means that all application methods matched by this 
// code query are removed from the *code base view* **JustMyCode.Methods**.
// The code base view *JustMyCode* is used by most default code queries 
// and rules.
//
// So far this query matches several well-identified generated
// methods, like the ones tagged with *System.CodeDom.Compiler.GeneratedCodeAttribute*,
// or the ones declared in a source file suffixed with *.designer.cs*. 
// Make sure to make this query richer to discard your generated 
// methods from the NDepend rules results.
//
// *notmycode* queries are executed before running others
// queries and rules. Also modifying a *notmycode* query
// provokes re-run of queries and rules that rely 
// on the *JustMyCode* code base view.
//
// Several *notmycode* queries can be written to match *methods*,
// in which case this results in cumulative effect.
//
// Online documentation:
// http://www.ndepend.com/docs/cqlinq-syntax#NotMyCode
//</Description>]]></Query>
      <Query Active="True" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Discard generated Fields from JustMyCode</Name>
notmycode
from f in Application.Fields where 
  f.HasAttribute ("System.CodeDom.Compiler.GeneratedCodeAttribute".AllowNoMatch()) ||

  // Eliminate "components" generated in Windows Form Control context
  f.Name == "components" && f.ParentType.DeriveFrom("System.Windows.Forms.Control".AllowNoMatch())
select f

//<Description>
// This code query is prefixed with **notmycode**.
// This means that all application fields matched by this 
// code query are removed from the *code base view* **JustMyCode.Fields**.
// The code base view *JustMyCode* is used by most default code queries 
// and rules.
//
// So far this query only matches application fields tagged
// with *System.CodeDom.Compiler.GeneratedCodeAttribute*, and 
// *Windows Form* generated fields named *components*.
// Make sure to make this query richer to discard your generated 
// fields from the NDepend rules results.
//
// *notmycode* queries are executed before running others
// queries and rules. Also modifying a *notmycode* query
// provokes re-run of queries and rules that rely 
// on the *JustMyCode* code base view.
//
// Several *notmycode* queries can be written to match *fields*,
// in which case this results in cumulative effect.
//
// Online documentation:
// http://www.ndepend.com/docs/cqlinq-syntax#NotMyCode
//</Description>]]></Query>
    </Group>
    <Group Name="Statistics" Active="True" ShownInReport="False">
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Most used types (Rank)</Name>
(from t in Application.Types 
 where !t.IsGeneratedByCompiler
 orderby t.Rank descending
 select new { t, t.Rank, t.TypesUsingMe }).Take(100)

//<Description>
// **TypeRank** values are computed by applying 
// the **Google PageRank** algorithm on the 
// graph of types' dependencies. Types with 
// high *Rank* are the most used ones. Not necessarily
// the ones with the most users types, but the ones
// used by many types, themselves having a lot of 
// types users.
//
// See the definition of the TypeRank metric here: 
// http://www.ndepend.com/docs/code-metrics#TypeRank
//
// This code query lists the 100 application types 
// with the highest rank.
//
// The main consequence of being used a lot for a 
// type is that each change (both *syntax change* 
// and *behavior change*) will result in potentially
// a lot of **pain** since most types clients will be 
// **impacted**.
//
// Hence it is preferable that types with highest 
// *TypeRank*, are **interfaces**, that are typically  
// less subject changes.
//
// Also interfaces avoid clients relying on  
// implementations details. Hence, when the behavior of 
// classes implementing an interface changes, this 
// shouldn't impact clients of the interface.
// This is *in essence* the 
// **Liskov Substitution Principle**.
// http://en.wikipedia.org/wiki/Liskov_substitution_principle
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Most used methods (Rank)</Name>
(from m in Application.Methods 
 where !m.IsGeneratedByCompiler
 orderby m.Rank descending
 select new { m, m.Rank, m.MethodsCallingMe }).Take(100)

//<Description>
// **MethodRank** values are computed by applying 
// the **Google PageRank** algorithm on the 
// graph of methods' dependencies. Methods with 
// high *Rank* are the most used ones. Not necessarily
// the ones with the most callers methods, but the ones
// called by many methods, themselves having a lot 
// of callers.
//
// See the definition of the MethodRank metric here: 
// http://www.ndepend.com/docs/code-metrics#MethodRank
//
// This code query lists the 100 application methods 
// with the highest rank.
//
// The main consequence of being used a lot for a 
// method is that each change (both *signature change* 
// and *behavior change*) will result in potentially
// a lot of **pain** since most methods callers will be 
// **impacted**.
//
// Hence it is preferable that methods with highest 
// *MethodRank*, are **abstract methods**, that are 
// typically less subject to signature changes.
//
// Also abstract methods avoid callers relying on  
// implementations details. Hence, when the code
// of a method implementing an abstract method changes, 
// this shouldn't impact callers of the abstract method.
// This is *in essence* the 
// **Liskov Substitution Principle**.
// http://en.wikipedia.org/wiki/Liskov_substitution_principle
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Most used assemblies (#AssembliesUsingMe)</Name>
(from a in Assemblies orderby a.AssembliesUsingMe.Count() descending
 select new { a, a.AssembliesUsingMe }).Take(100)
 
//<Description>
// This code query lists the 100 *application* and *third-party* 
// assemblies, with the highest number of assemblies users.  
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Most used namespaces (#NamespacesUsingMe )</Name>
(from n in Namespaces orderby n.NbNamespacesUsingMe descending
 select new { n, n.NamespacesUsingMe }).Take(100)
 
//<Description>
// This code query lists the 100 *application* and *third-party* 
// namespaces, with the highest number of namespaces users.  
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Most used types (#TypesUsingMe )</Name>
(from t in Types orderby t.NbTypesUsingMe descending
 where !t.IsGeneratedByCompiler
 select new { t, t.TypesUsingMe }).Take(100)
 
//<Description>
// This code query lists the 100 *application* and *third-party* 
// types, with the highest number of types users.  
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Most used methods (#MethodsCallingMe )</Name>
(from m in Methods orderby m.NbMethodsCallingMe 
 where !m.IsGeneratedByCompiler
 select new { m, m.MethodsCallingMe }).Take(100)

//<Description>
// This code query lists the 100 *application* and *third-party* 
// methods, with the highest number of methods callers.  
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Namespaces that use many other namespaces (#NamespacesUsed )</Name>
(from n in Application.Namespaces orderby n.NbNamespacesUsed descending
 select new { n, n.NamespacesUsed }).Take(100)
 
//<Description>
// This code query lists the 100 *application* namespaces 
// with the highest number of namespaces used.  
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Types that use many other types (#TypesUsed )</Name>
(from t in Application.Types orderby t.NbTypesUsed descending
 select new { t, t.TypesUsed, isMyCode = JustMyCode.Contains(t) }).Take(100)
 
//<Description>
// This code query lists the 100 *application* types 
// with the highest number of types used.  
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Methods that use many other methods (#MethodsCalled )</Name>
(from m in Application.Methods orderby m.NbMethodsCalled descending
 select new { m, m.MethodsCalled, isMyCode = JustMyCode.Contains(m) }).Take(100)

//<Description>
// This code query lists the 100 *application* methods 
// with the highest number of methods called.  
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>High-level to low-level assemblies (Level)</Name>
from a in Application.Assemblies orderby a.Level descending
select new { a, a.Level }

//<Description>
// This code query lists assemblies ordered by **Level** values.
// See the definition of the *AssemblyLevel* metric here:
// http://www.ndepend.com/docs/code-metrics#Level
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>High-level to low-level namespaces (Level)</Name>
from n in Application.Namespaces orderby n.Level descending
select new { n, n.Level }

//<Description>
// This code query lists namespaces ordered by **Level** values.
// See the definition of the *NamespaceLevel* metric here:
// http://www.ndepend.com/docs/code-metrics#Level
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>High-level to low-level types (Level)</Name>
from t in Application.Types orderby t.Level descending
select new { t, t.Level }

//<Description>
// This code query lists types ordered by **Level** values.
// See the definition of the *TypeLevel* metric here:
// http://www.ndepend.com/docs/code-metrics#Level
//</Description>]]></Query>
      <Query Active="True" DisplayList="False" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>High-level to low-level methods (Level)</Name>
from m in Application.Methods orderby m.Level descending
select new { m, m.Level }

//<Description>
// This code query lists methods ordered by **Level** values.
// See the definition of the *MethodLevel* metric here:
// http://www.ndepend.com/docs/code-metrics#Level
//</Description>]]></Query>
    </Group>
    <Group Name="Samples of Custom rules" Active="False" ShownInReport="False">
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that the assembly Asm1 is not using the assembly Asm2</Name>
warnif count > 0 from a in Application.Assemblies where 
  a.IsUsing ("Asm2".AllowNoMatch().MatchAssembly()) &&
  (a.Name == @"Asm1")
select a

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to be warned if a particular assembly is using
// another particular assembly.
//
// Such rule can be generated for assemblies **A** and **B**:
//
// • by right clicking the cell in the *Dependency Matrix* 
// with **B** in row and **A** in column,
//
// • or by right-clicking the concerned arrow in the *Dependency 
// Graph* from **A** to **B**,
//
// and in both cases, click the menu
// **Generate a code rule that warns if this dependency exists**
//
// The generated rule will look like this one.
// It is now up to you to adapt this rule to check exactly 
// your needs.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that the namespace N1.N2 is not using the namespace N3.N4.N5</Name>
warnif count > 0 from n in Application.Namespaces where 
  n.IsUsing ("N3.N4.N5".AllowNoMatch().MatchNamespace()) &&
  (n.Name == @"N1.N2")
select n

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to be warned if a particular namespace is using
// another particular namespace.
//
// Such rule can be generated for namespaces **A** and **B**:
//
// • by right clicking the cell in the *Dependency Matrix* 
// with **B** in row and **A** in column,
//
// • or by right-clicking the concerned arrow in the *Dependency 
// Graph* from **A** to **B**,
//
// and in both cases, click the menu
// **Generate a code rule that warns if this dependency exists**
//
// The generated rule will look like this one.
// It is now up to you to adapt this rule to check exactly 
// your needs.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that the assembly Asm1 is only using the assemblies Asm2, Asm3 or mscorlib</Name>
warnif count > 0 from a in Application.Assemblies where 
  ( !a.IsUsing ("Asm2".AllowNoMatch().MatchAssembly()) ||
    !a.IsUsing ("Asm3".AllowNoMatch().MatchAssembly()) ||
    !a.IsUsing ("mscorlib".MatchAssembly()) ||
     a.AssembliesUsed.Count() != 3) // Must not be used more than 3 assemblies 
&& 
  (a.Name == @"Asm1")
select new { a, a.AssembliesUsed }

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that a particular assembly
// is only using a particular set of assemblies.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that the namespace N1.N2 is only using the namespaces N3.N4, N5 or System</Name>
warnif count > 0 from n in Application.Namespaces where 
  ( !n.IsUsing("N3.N4".AllowNoMatch().MatchNamespace()) ||
    !n.IsUsing("N5".AllowNoMatch().MatchNamespace()) ||
    !n.IsUsing("System".MatchNamespace()) ||
     n.NamespacesUsed.Count() != 3) // Must not be used more than 3 assemblies 
                // AsmCe = Efferent Coupling for assembly
&& 
  (n.Name == @"N1.N2")
select new { n, n.NamespacesUsed }

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that a particular namespace
// **is only using** a particular set of namespaces.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that AsmDrawing is the only assembly that is using System.Drawing</Name>
warnif count> 0 from a in Application.Assemblies where 
   a.IsUsing ("System.Drawing".AllowNoMatch().MatchAssembly()) &&
  !(a.Name == @"AsmDrawing")
select a

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that a particular assembly
// is **only used by** another particular assembly.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that only 3 assemblies are using System.Drawing</Name>
warnif count != 3 from a in Application.Assemblies where 
  a.IsUsing ("System.Drawing".AllowNoMatch().MatchAssembly())
select a

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that a particular assembly
// is **only used by** 3 any others assemblies.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that all methods that call Foo.Fct1() also call Foo.Fct2(Int32)</Name>
warnif count > 0 from m in Application.Methods where 
   m.IsUsing ("Foo.Fct1()".AllowNoMatch()) &&
  !m.IsUsing ("Foo.Fct2(Int32)".AllowNoMatch())
select m

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that if a method calls a particular method,
// it must call another particular method.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that all types that derive from Foo, also implement IFoo</Name>
warnif count > 0 from t in Application.Types where 
   t.DeriveFrom ("Foo".AllowNoMatch().MatchType()) &&
  !t.Implement ("IFoo".AllowNoMatch().MatchType())
select t

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that all classes that derive from a particular base class,
// also implement a particular interface.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that all types that has the attribute FooAttribute are declared in the namespace N1.N2*</Name>
warnif count > 0 from t in 
  Application.Namespaces.WithNameWildcardMatchNotIn("N1.N2*").ChildTypes() 
  where 
    t.HasAttribute ("FooAttribute".AllowNoMatch())
select t

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that all types that are tagged
// with a particular attribute, are declared in a 
// particular namespace.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that all synchronization objects are only used from the namespaces under MyNamespace.Sync</Name>
warnif count > 0 from n in Application.Namespaces 
  where 
    (n.IsUsing ("System.Threading.Monitor".AllowNoMatch()) ||
     n.IsUsing ("System.Threading.ReaderWriterLock".AllowNoMatch()) ||
     n.IsUsing ("System.Threading.Mutex".AllowNoMatch()) ||
     n.IsUsing ("System.Threading.EventWaitHandle".AllowNoMatch()) ||
     n.IsUsing ("System.Threading.Semaphore".AllowNoMatch()) ||
     n.IsUsing ("System.Threading.Interlocked".AllowNoMatch())) 
  && !n.NameLike (@"^MyNamespace.Sync")
select n

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that all synchronization objects
// are used from a particular namespace.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      <Group Name="Check Coverage on particular Code Elements" Active="False" ShownInReport="False">
        <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that the assembly Asm is 100% covered by tests</Name>
warnif count > 0 from a in Application.Assemblies where 
  (a.Name == @"Asm") && 
   a.PercentageCoverage < 100
select new { a, a.PercentageCoverage }

//<Description>
// This is a sample rule that shows how to check 
// if a particular assembly is 100% covered by tests.
// Both the string **@"Asm"** and the threshold **100** can be adapted to your own needs.
//
// To execute this sample rule, coverage data must be imported.
// More info here: http://www.ndepend.com/docs/code-coverage
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
        <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that the namespace N1.N2 is 100% covered by tests</Name>
warnif count > 0 from n in Application.Namespaces where 
  (n.Name == @"N1.N2") && 
   n.PercentageCoverage < 100
select new { n, n.PercentageCoverage }

//<Description>
// This is a sample rule that shows how to check 
// if a particular namespace is 100% covered by tests.
// Both the string **@"N1.N2"** and the threshold **100** can be adapted to your own needs.
//
// To execute this sample rule, coverage data must be imported.
// More info here: http://www.ndepend.com/docs/code-coverage
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
        <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that the class Namespace.Foo is 100% covered by tests</Name>
warnif count > 0 from t in Application.Types where 
  (t.FullName == @"Namespace.Foo") && 
   t.PercentageCoverage < 100
select new { t, t.PercentageCoverage }

//<Description>
// This is a sample rule that shows how to check 
// if a particular class is 100% covered by tests.
// Both the string **@"Namespace.Foo"** and the threshold **100** 
// can be adapted to your own needs.
//
// To execute this sample rule, coverage data must be imported.
// More info here: http://www.ndepend.com/docs/code-coverage
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
        <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that the class Namespace.Foo.Method(Int32) is 100% covered by tests</Name>
warnif count > 0 from t in Application.Types where 
  (t.FullName == @"Namespace.Foo.Method(Int32)") && 
   t.PercentageCoverage < 100
select new { t, t.PercentageCoverage }


//<Description>
// This is a sample rule that shows how to check 
// if a particular method is 100% covered by tests.
// Both the string **@"Namespace.Foo.Method(Int32)"** and the threshold **100** 
// can be adapted to your own needs.
//
// To execute this sample rule, coverage data must be imported.
// More info here: http://www.ndepend.com/docs/code-coverage
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
      </Group>
      <Group Name="Custom Naming Conventions" Active="False" ShownInReport="False">
        <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that all types that derive from Foo, has a name that ends up with Foo</Name>
warnif count > 0 from t in Application.Types where 
   t.DeriveFrom ("Foo".AllowNoMatch().MatchType()) &&
  !t.NameLike (@"Foo$")
select new { t, t.NbLinesOfCode }

//<Description>
// This rule is a *sample rule that can be adapted to your need*.
//
// It shows how to enforce that all classes that derive from
// a particular class, are named with a particular suffix.
//</Description>

//<HowToFix>
// This is a *sample rule* there is nothing to fix *as is*. 
//</HowToFix>]]></Query>
        <Query Active="False" DisplayList="True" DisplayStat="False" DisplaySelectionView="False" IsCriticalRule="False"><![CDATA[// <Name>Check that all namespaces begins with CompanyName.ProductName</Name>
warnif count > 0 from n in Application.Namespaces where 
  !n.NameLike (@"^CompanyName.ProductName")
select new { n, n.NbLinesOfCode } 

//<Description>
// A practice widely adopted is that, in a product source code,
// all namespaces start with "CompanyName.ProductName".
//
// This rule must be adapted with your own **"CompanyName.ProductName"**.
//</Description>

//<HowToFix>
// Update all namespaces definitions in source code to satisfy this rule.
//</HowToFix>]]></Query>
      </Group>
    </Group>
  </Queries>
  <WarnFilter />
</NDepend>