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funcdata.hh
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funcdata.hh
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/* ###
* IP: GHIDRA
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef __FUNCDATA_HH__
#define __FUNCDATA_HH__
/// \file funcdata.hh
/// \brief Utilities for processing data structures associated with a single function
#include "architecture.hh"
#include "override.hh"
#include "heritage.hh"
#include "merge.hh"
#include "dynamic.hh"
#include "unionresolve.hh"
namespace ghidra {
class FlowInfo;
extern AttributeId ATTRIB_NOCODE; ///< Marshaling attribute "nocode"
extern ElementId ELEM_AST; ///< Marshaling element \<ast>
extern ElementId ELEM_FUNCTION; ///< Marshaling element \<function>
extern ElementId ELEM_HIGHLIST; ///< Marshaling element \<highlist>
extern ElementId ELEM_JUMPTABLELIST; ///< Marshaling element \<jumptablelist>
extern ElementId ELEM_VARNODES; ///< Marshaling element \<varnodes>
/// \brief Container for data structures associated with a single function
///
/// This class holds the primary data structures for decompiling a function. In particular it holds
/// control-flow, data-flow, and prototype information, plus class instances to help with constructing
/// SSA form, structure control-flow, recover jump-tables, recover parameters, and merge Varnodes. In
/// most cases it acts as the main API for querying and accessing these structures.
///
/// Some important groups of public methods include:
/// - PcodeOp manipulation (mostly starting with 'op')
/// - PcodeOp search and traversal ('beginOp*' and 'endOp*')
/// - Varnode creation ('new*' methods)
/// - Varnode search and traversal ('beginLoc' 'endLoc' 'beginDef' and 'endDef')
/// - Basic block access and block structuring
/// - Access to subfunction prototypes
/// - Access to jump-tables (within the body of the function)
class Funcdata {
enum {
highlevel_on = 1, ///< Set if Varnodes have HighVariables assigned
blocks_generated = 2, ///< Set if Basic blocks have been generated
blocks_unreachable = 4, ///< Set if at least one basic block is currently unreachable
processing_started = 8, ///< Set if processing has started
processing_complete = 0x10, ///< Set if processing completed
typerecovery_on = 0x20, ///< Set if data-type analysis will be performed
typerecovery_start = 0x40, ///< Set if data-type recovery is started
no_code = 0x80, ///< Set if there is no code available for this function
jumptablerecovery_on = 0x100, ///< Set if \b this Funcdata object is dedicated to jump-table recovery
jumptablerecovery_dont = 0x200, ///< Don't try to recover jump-tables, always truncate
restart_pending = 0x400, ///< Analysis must be restarted (because of new override info)
unimplemented_present = 0x800, ///< Set if function contains unimplemented instructions
baddata_present = 0x1000, ///< Set if function flowed into bad data
double_precis_on = 0x2000 ///< Set if we are performing double precision recovery
};
uint4 flags; ///< Boolean properties associated with \b this function
uint4 clean_up_index; ///< Creation index of first Varnode created after start of cleanup
uint4 high_level_index; ///< Creation index of first Varnode created after HighVariables are created
uint4 cast_phase_index; ///< Creation index of first Varnode created after ActionSetCasts
uint4 minLanedSize; ///< Minimum Varnode size to check as LanedRegister
int4 size; ///< Number of bytes of binary data in function body
Architecture *glb; ///< Global configuration data
FunctionSymbol *functionSymbol; ///< The symbol representing \b this function
string name; ///< Name of function
string displayName; ///< Name to display in output
Address baseaddr; ///< Starting code address of binary data
FuncProto funcp; ///< Prototype of this function
ScopeLocal *localmap; ///< Local variables (symbols in the function scope)
vector<FuncCallSpecs *> qlst; ///< List of calls this function makes
vector<JumpTable *> jumpvec; ///< List of jump-tables for this function
VarnodeBank vbank; ///< Container of Varnode objects for \b this function
PcodeOpBank obank; ///< Container of PcodeOp objects for \b this function
BlockGraph bblocks; ///< Unstructured basic blocks
BlockGraph sblocks; ///< Structured block hierarchy (on top of basic blocks)
Heritage heritage; ///< Manager for maintaining SSA form
Merge covermerge; ///< Variable range intersection algorithms
ParamActive *activeoutput; ///< Data for assessing which parameters are passed to \b this function
Override localoverride; ///< Overrides of data-flow, prototypes, etc. that are local to \b this function
map<VarnodeData,const LanedRegister *> lanedMap; ///< Current storage locations which may be laned registers
map<ResolveEdge,ResolvedUnion> unionMap; ///< A map from data-flow edges to the resolved field of TypeUnion being accessed
// Low level Varnode functions
void setVarnodeProperties(Varnode *vn) const; ///< Look-up boolean properties and data-type information
HighVariable *assignHigh(Varnode *vn); ///< Assign a new HighVariable to a Varnode
Symbol *handleSymbolConflict(SymbolEntry *entry,Varnode *vn); ///< Handle two variables with matching storage
bool syncVarnodesWithSymbol(VarnodeLocSet::const_iterator &iter,uint4 fl,Datatype *ct);
bool descend2Undef(Varnode *vn); ///< Transform all reads of the given Varnode to a special \b undefined constant
void splitUses(Varnode *vn); ///< Make all reads of the given Varnode unique
Varnode *cloneVarnode(const Varnode *vn); ///< Clone a Varnode (between copies of the function)
void destroyVarnode(Varnode *vn); ///< Delete the given Varnode from \b this function
void coverVarnodes(SymbolEntry *entry,vector<Varnode *> &list);
bool applyUnionFacet(SymbolEntry *entry,DynamicHash &dhash);
// Low level op functions
void opZeroMulti(PcodeOp *op); ///< Transform trivial CPUI_MULTIEQUAL to CPUI_COPY
// Low level block functions
void blockRemoveInternal(BlockBasic *bb,bool unreachable);
void branchRemoveInternal(BlockBasic *bb,int4 num);
void pushMultiequals(BlockBasic *bb); ///< Push MULTIEQUAL Varnodes of the given block into the output block
void clearBlocks(void); ///< Clear all basic blocks
void structureReset(void); ///< Calculate initial basic block structures (after a control-flow change)
JumpTable::RecoveryMode stageJumpTable(Funcdata &partial,JumpTable *jt,PcodeOp *op,FlowInfo *flow);
void switchOverJumpTables(const FlowInfo &flow); ///< Convert jump-table addresses to basic block indices
void clearJumpTables(void); ///< Clear any jump-table information
void sortCallSpecs(void); ///< Sort calls using a dominance based order
void deleteCallSpecs(PcodeOp *op); ///< Remove the specification for a particular call
void clearCallSpecs(void); ///< Remove all call specifications
BlockBasic *nodeSplitBlockEdge(BlockBasic *b,int4 inedge);
PcodeOp *nodeSplitCloneOp(PcodeOp *op);
void nodeSplitCloneVarnode(PcodeOp *op,PcodeOp *newop);
void nodeSplitRawDuplicate(BlockBasic *b,BlockBasic *bprime);
void nodeSplitInputPatch(BlockBasic *b,BlockBasic *bprime,int4 inedge);
static bool descendantsOutside(Varnode *vn);
static void encodeVarnode(Encoder &encoder,VarnodeLocSet::const_iterator iter,VarnodeLocSet::const_iterator enditer);
static bool checkIndirectUse(Varnode *vn);
static PcodeOp *findPrimaryBranch(PcodeOpTree::const_iterator iter,PcodeOpTree::const_iterator enditer,
bool findbranch,bool findcall,bool findreturn);
public:
Funcdata(const string &nm,const string &disp,Scope *conf,const Address &addr,FunctionSymbol *sym,int4 sz=0); ///< Constructor
~Funcdata(void); ///< Destructor
const string &getName(void) const { return name; } ///< Get the function's local symbol name
const string &getDisplayName(void) const { return displayName; } ///< Get the name to display in output
const Address &getAddress(void) const { return baseaddr; } ///< Get the entry point address
int4 getSize(void) const { return size; } ///< Get the function body size in bytes
Architecture *getArch(void) const { return glb; } ///< Get the program/architecture owning \b this function
FunctionSymbol *getSymbol(void) const { return functionSymbol; } ///< Return the symbol associated with \b this function
bool isHighOn(void) const { return ((flags&highlevel_on)!=0); } ///< Are high-level variables assigned to Varnodes
bool isProcStarted(void) const { return ((flags&processing_started)!=0); } ///< Has processing of the function started
bool isProcComplete(void) const { return ((flags&processing_complete)!=0); } ///< Is processing of the function complete
bool hasUnreachableBlocks(void) const { return ((flags&blocks_unreachable)!=0); } ///< Did this function exhibit unreachable code
bool isTypeRecoveryOn(void) const { return ((flags&typerecovery_on)!=0); } ///< Will data-type analysis be performed
bool hasTypeRecoveryStarted(void) const { return ((flags&typerecovery_start)!=0); } ///< Has data-type recovery processes started
bool hasNoCode(void) const { return ((flags & no_code)!=0); } ///< Return \b true if \b this function has no code body
void setNoCode(bool val) { if (val) flags |= no_code; else flags &= ~no_code; } ///< Toggle whether \b this has a body
void setLanedRegGenerated(void) { minLanedSize = 1000000; } ///< Mark that laned registers have been collected
/// \brief Toggle whether \b this is being used for jump-table recovery
///
/// \param val is \b true to indicate a jump-table is being recovered
void setJumptableRecovery(bool val) { if (val) flags &= ~jumptablerecovery_dont; else flags |= jumptablerecovery_dont; }
bool isJumptableRecoveryOn(void) const { return ((flags & jumptablerecovery_on)!=0); } ///< Is \b this used for jump-table recovery
/// \brief Toggle whether double precision analysis is used
///
/// \param val is \b true if double precision analysis is enabled
void setDoublePrecisRecovery(bool val) { if (val) flags |= double_precis_on; else flags &= ~double_precis_on; }
bool isDoublePrecisOn(void) const { return ((flags & double_precis_on)!=0); } ///< Is double precision analysis enabled
bool hasNoStructBlocks(void) const { return (sblocks.getSize() == 0); } ///< Return \b true if no block structuring was performed
void clear(void); ///< Clear out old disassembly
void warning(const string &txt,const Address &ad) const; ///< Add a warning comment in the function body
void warningHeader(const string &txt) const; ///< Add a warning comment as part of the function header
void startProcessing(void); ///< Start processing for this function
void stopProcessing(void); ///< Mark that processing has completed for this function
bool startTypeRecovery(void); ///< Mark that data-type analysis has started
/// \brief Toggle whether data-type recovery will be performed on \b this function
///
/// \param val is \b true if data-type analysis is enabled
void setTypeRecovery(bool val) { flags = val ? (flags | typerecovery_on) : (flags & ~typerecovery_on); }
void startCastPhase(void) { cast_phase_index = vbank.getCreateIndex(); } ///< Start the \b cast insertion phase
uint4 getCastPhaseIndex(void) const { return cast_phase_index; } ///< Get creation index at the start of \b cast insertion
uint4 getHighLevelIndex(void) const { return high_level_index; } ///< Get creation index at the start of HighVariable creation
void startCleanUp(void) { clean_up_index = vbank.getCreateIndex(); } ///< Start \e clean-up phase
uint4 getCleanUpIndex(void) const { return clean_up_index; } ///< Get creation index at the start of \b clean-up phase
void followFlow(const Address &baddr,const Address &eadddr);
void truncatedFlow(const Funcdata *fd,const FlowInfo *flow);
bool inlineFlow(Funcdata *inlinefd,FlowInfo &flow,PcodeOp *callop);
void overrideFlow(const Address &addr,uint4 type);
void doLiveInject(InjectPayload *payload,const Address &addr,BlockBasic *bl,list<PcodeOp *>::iterator pos);
void printRaw(ostream &s) const; ///< Print raw p-code op descriptions to a stream
void printVarnodeTree(ostream &s) const; ///< Print a description of all Varnodes to a stream
void printBlockTree(ostream &s) const; ///< Print a description of control-flow structuring to a stream
void printLocalRange(ostream &s) const; ///< Print description of memory ranges associated with local scopes
void encode(Encoder &encoder,uint8 id,bool savetree) const; ///< Encode a description of \b this function to stream
uint8 decode(Decoder &decoder); ///< Restore the state of \b this function from a stream
void encodeJumpTable(Encoder &encoder) const; ///< Encode a description of jump-tables to stream
void decodeJumpTable(Decoder &decoder); ///< Decode jump-tables from a stream
void encodeTree(Encoder &encoder) const; ///< Encode a description of the p-code tree to stream
void encodeHigh(Encoder &encoder) const; ///< Encode a description of all HighVariables to stream
Override &getOverride(void) { return localoverride; } ///< Get the Override object for \b this function
/// \brief Toggle whether analysis needs to be restarted for \b this function
///
/// \param val is \b true if a reset is required
void setRestartPending(bool val) { flags = val ? (flags|restart_pending) : (flags & ~((uint4)restart_pending)); }
/// \brief Does \b this function need to restart its analysis
///
/// \return \b true if analysis should be restarted
bool hasRestartPending(void) const { return ((flags&restart_pending)!=0); }
/// \brief Does \b this function have instructions marked as \e unimplemented
///
/// \return \b true if the function's body contains at least one unimplemented instruction
bool hasUnimplemented(void) const { return ((flags&unimplemented_present)!=0); }
bool hasBadData(void) const { return ((flags&baddata_present)!=0); } ///< Does \b this function flow into bad data
void spacebase(void); ///< Mark registers that map to a virtual address space
Varnode *newSpacebasePtr(AddrSpace *id); ///< Construct a new \e spacebase register for a given address space
Varnode *findSpacebaseInput(AddrSpace *id) const;
void spacebaseConstant(PcodeOp *op,int4 slot,SymbolEntry *entry,const Address &rampoint,uintb origval,int4 origsize);
int4 getHeritagePass(void) const { return heritage.getPass(); } ///< Get overall count of heritage passes
/// \brief Get the number of heritage passes performed for the given address space
///
/// \param spc is the address space
/// \return the number of passes performed
int4 numHeritagePasses(AddrSpace *spc) { return heritage.numHeritagePasses(spc); }
/// \brief Mark that dead Varnodes have been seen in a specific address space
///
/// \param spc is the address space to mark
void seenDeadcode(AddrSpace *spc) { heritage.seenDeadCode(spc); }
/// \brief Set a delay before removing dead code for a specific address space
///
/// \param spc is the specific address space
/// \param delay is the number of passes to delay
void setDeadCodeDelay(AddrSpace *spc,int4 delay) { heritage.setDeadCodeDelay(spc,delay); }
/// \brief Check if dead code removal is allowed for a specific address space
///
/// \param spc is the specific address space
/// \return \b true if dead code removal is allowed
bool deadRemovalAllowed(AddrSpace *spc) const { return heritage.deadRemovalAllowed(spc); }
/// \brief Check if dead Varnodes have been removed for a specific address space
///
/// \param spc is the specific address space
/// \return \b true if dead code removal has happened in the space
bool deadRemovalAllowedSeen(AddrSpace *spc) { return heritage.deadRemovalAllowedSeen(spc); }
/// \brief Check if a specific Varnode has been linked in fully to the syntax tree (SSA)
///
/// \param vn is the specific Varnode
/// \return \b true if the Varnode is fully linked
bool isHeritaged(Varnode *vn) { return (heritage.heritagePass(vn->getAddr())>=0); }
const list<LoadGuard> &getLoadGuards(void) const { return heritage.getLoadGuards(); } ///< Get the list of guarded LOADs
const list<LoadGuard> &getStoreGuards(void) const { return heritage.getStoreGuards(); } ///< Get the list of guarded STOREs
const LoadGuard *getStoreGuard(PcodeOp *op) const { return heritage.getStoreGuard(op); } ///< Get LoadGuard associated with STORE op
// Function prototype and call specification routines
int4 numCalls(void) const { return qlst.size(); } ///< Get the number of calls made by \b this function
FuncCallSpecs *getCallSpecs(int4 i) const { return qlst[i]; } ///< Get the i-th call specification
FuncCallSpecs *getCallSpecs(const PcodeOp *op) const; ///< Get the call specification associated with a CALL op
int4 fillinExtrapop(void); ///< Recover and return the \e extrapop for this function
// Varnode routines
int4 numVarnodes(void) const { return vbank.numVarnodes(); } ///< Get the total number of Varnodes
Varnode *newVarnodeOut(int4 s,const Address &m,PcodeOp *op); ///< Create a new output Varnode
Varnode *newUniqueOut(int4 s,PcodeOp *op); ///< Create a new \e temporary output Varnode
Varnode *newVarnode(int4 s,const Address &m,Datatype *ct=(Datatype *)0);
Varnode *newConstant(int4 s,uintb constant_val); ///< Create a new \e constant Varnode
Varnode *newVarnode(int4 s,AddrSpace *base,uintb off); ///< Create a new Varnode given an address space and offset
Varnode *newVarnodeIop(PcodeOp *op); ///< Create a PcodeOp \e annotation Varnode
Varnode *newVarnodeSpace(AddrSpace *spc); ///< Create a constant Varnode referring to an address space
Varnode *newVarnodeCallSpecs(FuncCallSpecs *fc); ///< Create a call specification \e annotation Varnode
Varnode *newUnique(int4 s,Datatype *ct=(Datatype *)0); ///< Create a new \e temporary Varnode
Varnode *newCodeRef(const Address &m); ///< Create a code address \e annotation Varnode
Varnode *setInputVarnode(Varnode *vn); ///< Mark a Varnode as an input to the function
Varnode *newExtendedConstant(int4 s,uint8 *val,PcodeOp *op); ///< Create extended precision constant
void adjustInputVarnodes(const Address &addr,int4 sz);
void deleteVarnode(Varnode *vn) { vbank.destroy(vn); } ///< Delete the given varnode
Address findDisjointCover(Varnode *vn,int4 &sz); ///< Find range covering given Varnode and any intersecting Varnodes
/// \brief Find the first input Varnode covered by the given range
///
/// \param s is the size of the range in bytes
/// \param loc is the starting address of the range
/// \return the matching Varnode or NULL
Varnode *findCoveredInput(int4 s,const Address &loc) const { return vbank.findCoveredInput(s,loc); }
/// \brief Find the input Varnode that contains the given range
///
/// \param s is the size of the range in bytes
/// \param loc is the starting address of the range
/// \return the matching Varnode or NULL
Varnode *findCoveringInput(int4 s,const Address &loc) const { return vbank.findCoveringInput(s,loc); }
/// \brief Find the input Varnode with the given size and storage address
///
/// \param s is the size in bytes
/// \param loc is the storage address
/// \return the matching Varnode or NULL
Varnode *findVarnodeInput(int4 s,const Address &loc) const { return vbank.findInput(s,loc); }
/// \brief Find a defined Varnode via its storage address and its definition address
///
/// \param s is the size in bytes
/// \param loc is the storage address
/// \param pc is the address where the Varnode is defined
/// \param uniq is an (optional) sequence number to match
/// \return the matching Varnode or NULL
Varnode *findVarnodeWritten(int4 s,const Address &loc,const Address &pc,uintm uniq=~((uintm)0)) const {
return vbank.find(s,loc,pc,uniq); }
/// \brief Start of all Varnodes sorted by storage
VarnodeLocSet::const_iterator beginLoc(void) const { return vbank.beginLoc(); }
/// \brief End of all Varnodes sorted by storage
VarnodeLocSet::const_iterator endLoc(void) const { return vbank.endLoc(); }
/// \brief Start of Varnodes stored in a given address space
VarnodeLocSet::const_iterator beginLoc(AddrSpace *spaceid) const { return vbank.beginLoc(spaceid); }
/// \brief End of Varnodes stored in a given address space
VarnodeLocSet::const_iterator endLoc(AddrSpace *spaceid) const { return vbank.endLoc(spaceid); }
/// \brief Start of Varnodes at a storage address
VarnodeLocSet::const_iterator beginLoc(const Address &addr) const { return vbank.beginLoc(addr); }
/// \brief End of Varnodes at a storage address
VarnodeLocSet::const_iterator endLoc(const Address &addr) const { return vbank.endLoc(addr); }
/// \brief Start of Varnodes with given storage
VarnodeLocSet::const_iterator beginLoc(int4 s,const Address &addr) const { return vbank.beginLoc(s,addr); }
/// \brief End of Varnodes with given storage
VarnodeLocSet::const_iterator endLoc(int4 s,const Address &addr) const { return vbank.endLoc(s,addr); }
/// \brief Start of Varnodes matching storage and properties
VarnodeLocSet::const_iterator beginLoc(int4 s,const Address &addr,uint4 fl) const { return vbank.beginLoc(s,addr,fl); }
/// \brief End of Varnodes matching storage and properties
VarnodeLocSet::const_iterator endLoc(int4 s,const Address &addr,uint4 fl) const { return vbank.endLoc(s,addr,fl); }
/// \brief Start of Varnodes matching storage and definition address
VarnodeLocSet::const_iterator beginLoc(int4 s,const Address &addr,const Address &pc,uintm uniq=~((uintm)0)) const {
return vbank.beginLoc(s,addr,pc,uniq); }
/// \brief End of Varnodes matching storage and definition address
VarnodeLocSet::const_iterator endLoc(int4 s,const Address &addr,const Address &pc,uintm uniq=~((uintm)0)) const {
return vbank.endLoc(s,addr,pc,uniq); }
/// \brief Given start, return maximal range of overlapping Varnodes
uint4 overlapLoc(VarnodeLocSet::const_iterator iter,vector<VarnodeLocSet::const_iterator> &bounds) const {
return vbank.overlapLoc(iter,bounds); }
/// \brief Start of all Varnodes sorted by definition address
VarnodeDefSet::const_iterator beginDef(void) const { return vbank.beginDef(); }
/// \brief End of all Varnodes sorted by definition address
VarnodeDefSet::const_iterator endDef(void) const { return vbank.endDef(); }
/// \brief Start of Varnodes with a given definition property
VarnodeDefSet::const_iterator beginDef(uint4 fl) const { return vbank.beginDef(fl); }
/// \brief End of Varnodes with a given definition property
VarnodeDefSet::const_iterator endDef(uint4 fl) const { return vbank.endDef(fl); }
/// \brief Start of (input or free) Varnodes at a given storage address
VarnodeDefSet::const_iterator beginDef(uint4 fl,const Address &addr) const { return vbank.beginDef(fl,addr); }
/// \brief End of (input or free) Varnodes at a given storage address
VarnodeDefSet::const_iterator endDef(uint4 fl,const Address &addr) const { return vbank.endDef(fl,addr); }
void checkForLanedRegister(int4 sz,const Address &addr); ///< Check for a potential laned register
map<VarnodeData,const LanedRegister *>::const_iterator beginLaneAccess(void) const { return lanedMap.begin(); } ///< Beginning iterator over laned accesses
map<VarnodeData,const LanedRegister *>::const_iterator endLaneAccess(void) const { return lanedMap.end(); } ///< Ending iterator over laned accesses
void clearLanedAccessMap(void) { lanedMap.clear(); } ///< Clear records from the laned access list
HighVariable *findHigh(const string &nm) const; ///< Find a high-level variable by name
void mapGlobals(void); ///< Make sure there is a Symbol entry for all global Varnodes
void prepareThisPointer(void); ///< Prepare for recovery of the "this" pointer
bool checkCallDoubleUse(const PcodeOp *opmatch,const PcodeOp *op,const Varnode *vn,uint4 fl,const ParamTrial &trial) const;
bool onlyOpUse(const Varnode *invn,const PcodeOp *opmatch,const ParamTrial &trial,uint4 mainFlags) const;
bool ancestorOpUse(int4 maxlevel,const Varnode *invn,const PcodeOp *op,ParamTrial &trial,int4 offset,uint4 mainFlags) const;
bool syncVarnodesWithSymbols(const ScopeLocal *lm,bool updateDatatypes,bool unmappedAliasCheck);
void transferVarnodeProperties(Varnode *vn,Varnode *newVn,int4 lsbOffset);
bool fillinReadOnly(Varnode *vn); ///< Replace the given Varnode with its (constant) value in the load image
bool replaceVolatile(Varnode *vn); ///< Replace accesses of the given Varnode with \e volatile operations
void markIndirectOnly(void); ///< Mark \e illegal \e input Varnodes used only in INDIRECTs
void totalReplace(Varnode *vn,Varnode *newvn);
void totalReplaceConstant(Varnode *vn,uintb val);
ScopeLocal *getScopeLocal(void) { return localmap; } ///< Get the local function scope
const ScopeLocal *getScopeLocal(void) const { return localmap; } ///< Get the local function scope
FuncProto &getFuncProto(void) { return funcp; } ///< Get the function's prototype object
const FuncProto &getFuncProto(void) const { return funcp; } ///< Get the function's prototype object
void initActiveOutput(void); ///< Initialize \e return prototype recovery analysis
/// \brief Clear any analysis of the function's \e return prototype
void clearActiveOutput(void) {
if (activeoutput != (ParamActive *)0) delete activeoutput;
activeoutput = (ParamActive *)0;
}
ParamActive *getActiveOutput(void) const { return activeoutput; } ///< Get the \e return prototype recovery object
void setHighLevel(void); ///< Turn on HighVariable objects for all Varnodes
void clearDeadVarnodes(void); ///< Delete any dead Varnodes
void calcNZMask(void); ///< Calculate \e non-zero masks for all Varnodes
void clearDeadOps(void) { obank.destroyDead(); } ///< Delete any dead PcodeOps
void remapVarnode(Varnode *vn,Symbol *sym,const Address &usepoint);
void remapDynamicVarnode(Varnode *vn,Symbol *sym,const Address &usepoint,uint8 hash);
void linkProtoPartial(Varnode *vn); ///< Find or create Symbol and a partial mapping
Symbol *linkSymbol(Varnode *vn); ///< Find or create Symbol associated with given Varnode
Symbol *linkSymbolReference(Varnode *vn); ///< Discover and attach Symbol to a constant reference
Varnode *findLinkedVarnode(SymbolEntry *entry) const; ///< Find a Varnode matching the given Symbol mapping
void findLinkedVarnodes(SymbolEntry *entry,vector<Varnode *> &res) const; ///< Find Varnodes that map to the given SymbolEntry
void buildDynamicSymbol(Varnode *vn); ///< Build a \e dynamic Symbol associated with the given Varnode
bool testForReturnAddress(Varnode *vn); ///< Test if the given Varnode is (derived from) the return address
bool attemptDynamicMapping(SymbolEntry *entry,DynamicHash &dhash);
bool attemptDynamicMappingLate(SymbolEntry *entry,DynamicHash &dhash);
Merge &getMerge(void) { return covermerge; } ///< Get the Merge object for \b this function
// op routines
PcodeOp *newOp(int4 inputs,const Address &pc); /// Allocate a new PcodeOp with Address
PcodeOp *newOp(int4 inputs,const SeqNum &sq); /// Allocate a new PcodeOp with sequence number
PcodeOp *newOpBefore(PcodeOp *follow,OpCode opc,Varnode *in1,Varnode *in2,Varnode *in3=(Varnode *)0);
PcodeOp *cloneOp(const PcodeOp *op,const SeqNum &seq); /// Clone a PcodeOp into \b this function
PcodeOp *getFirstReturnOp(void) const; /// Find a representative CPUI_RETURN op for \b this function
PcodeOp *newIndirectOp(PcodeOp *indeffect,const Address &addr,int4 sz,uint4 extraFlags);
PcodeOp *newIndirectCreation(PcodeOp *indeffect,const Address &addr,int4 sz,bool possibleout);
void markIndirectCreation(PcodeOp *indop,bool possibleOutput); ///< Convert CPUI_INDIRECT into an \e indirect \e creation
PcodeOp *findOp(const SeqNum &sq) { return obank.findOp(sq); } ///< Find PcodeOp with given sequence number
void opInsertBefore(PcodeOp *op,PcodeOp *follow); ///< Insert given PcodeOp before a specific op
void opInsertAfter(PcodeOp *op,PcodeOp *prev); ///< Insert given PcodeOp after a specific op
void opInsertBegin(PcodeOp *op,BlockBasic *bl); ///< Insert given PcodeOp at the beginning of a basic block
void opInsertEnd(PcodeOp *op,BlockBasic *bl); ///< Insert given PcodeOp at the end of a basic block
/// \brief Moved given PcodeOp to specified point in the \e dead list
void opDeadInsertAfter(PcodeOp *op,PcodeOp *prev) { obank.insertAfterDead(op,prev); }
void opHeritage(void) { heritage.heritage(); } ///< Perform an entire heritage pass linking Varnode reads to writes
void opSetOpcode(PcodeOp *op,OpCode opc); ///< Set the op-code for a specific PcodeOp
void opMarkHalt(PcodeOp *op,uint4 flag); ///< Mark given CPUI_RETURN op as a \e special halt
void opSetOutput(PcodeOp *op,Varnode *vn); ///< Set a specific output Varnode for the given PcodeOp
void opUnsetOutput(PcodeOp *op); ///< Remove output Varnode from the given PcodeOp
void opSetInput(PcodeOp *op,Varnode *vn,int4 slot); ///< Set a specific input operand for the given PcodeOp
void opSwapInput(PcodeOp *op,int4 slot1,int4 slot2); ///< Swap two input operands in the given PcodeOp
void opUnsetInput(PcodeOp *op,int4 slot); ///< Clear an input operand slot for the given PcodeOp
void opInsert(PcodeOp *op,BlockBasic *bl,list<PcodeOp *>::iterator iter);
void opUninsert(PcodeOp *op); ///< Remove the given PcodeOp from its basic block
void opUnlink(PcodeOp *op); ///< Unset inputs/output and remove given PcodeOP from its basic block
void opDestroy(PcodeOp *op); ///< Remove given PcodeOp and destroy its Varnode operands
void opDestroyRaw(PcodeOp *op); ///< Remove the given \e raw PcodeOp
void opDeadAndGone(PcodeOp *op) { obank.destroy(op); } ///< Free resources for the given \e dead PcodeOp
void opSetAllInput(PcodeOp *op,const vector<Varnode *> &vvec); ///< Set all input Varnodes for the given PcodeOp simultaneously
void opRemoveInput(PcodeOp *op,int4 slot); ///< Remove a specific input slot for the given PcodeOp
void opInsertInput(PcodeOp *op,Varnode *vn,int4 slot); ///< Insert a new Varnode into the operand list for the given PcodeOp
void opMarkStartBasic(PcodeOp *op) { op->setFlag(PcodeOp::startbasic); } ///< Mark PcodeOp as starting a basic block
void opMarkStartInstruction(PcodeOp *op) { op->setFlag(PcodeOp::startmark); } ///< Mark PcodeOp as starting its instruction
void opMarkNonPrinting(PcodeOp *op) { op->setFlag(PcodeOp::nonprinting); } ///< Mark PcodeOp as not being printed
void opMarkSpecialPrint(PcodeOp *op) { op->setAdditionalFlag(PcodeOp::special_print); } ///< Mark PcodeOp as needing special printing
void opMarkNoCollapse(PcodeOp *op) { op->setFlag(PcodeOp::nocollapse); } ///< Mark PcodeOp as not collapsible
void opMarkCpoolTransformed(PcodeOp *op) { op->setAdditionalFlag(PcodeOp::is_cpool_transformed); } ///< Mark cpool record was visited
void opMarkCalculatedBool(PcodeOp *op) { op->setFlag(PcodeOp::calculated_bool); } ///< Mark PcodeOp as having boolean output
void opMarkSpacebasePtr(PcodeOp *op) { op->setFlag(PcodeOp::spacebase_ptr); } ///< Mark PcodeOp as LOAD/STORE from spacebase ptr
void opClearSpacebasePtr(PcodeOp *op) { op->clearFlag(PcodeOp::spacebase_ptr); } ///< Unmark PcodeOp as using spacebase ptr
void opFlipCondition(PcodeOp *op) { op->flipFlag(PcodeOp::boolean_flip); } ///< Flip output condition of given CBRANCH
PcodeOp *target(const Address &addr) const { return obank.target(addr); } ///< Look up a PcodeOp by an instruction Address
Varnode *createStackRef(AddrSpace *spc,uintb off,PcodeOp *op,Varnode *stackptr,bool insertafter);
Varnode *opStackLoad(AddrSpace *spc,uintb off,uint4 sz,PcodeOp *op,Varnode *stackptr,bool insertafter);
PcodeOp *opStackStore(AddrSpace *spc,uintb off,PcodeOp *op,bool insertafter);
void opUndoPtradd(PcodeOp *op,bool finalize); ///< Convert a CPUI_PTRADD back into a CPUI_INT_ADD
/// \brief Start of PcodeOp objects with the given op-code
list<PcodeOp *>::const_iterator beginOp(OpCode opc) const { return obank.begin(opc); }
/// \brief End of PcodeOp objects with the given op-code
list<PcodeOp *>::const_iterator endOp(OpCode opc) const { return obank.end(opc); }
/// \brief Start of PcodeOp objects in the \e alive list
list<PcodeOp *>::const_iterator beginOpAlive(void) const { return obank.beginAlive(); }
/// \brief End of PcodeOp objects in the \e alive list
list<PcodeOp *>::const_iterator endOpAlive(void) const { return obank.endAlive(); }
/// \brief Start of PcodeOp objects in the \e dead list
list<PcodeOp *>::const_iterator beginOpDead(void) const { return obank.beginDead(); }
/// \brief End of PcodeOp objects in the \e dead list
list<PcodeOp *>::const_iterator endOpDead(void) const { return obank.endDead(); }
/// \brief Start of all (alive) PcodeOp objects sorted by sequence number
PcodeOpTree::const_iterator beginOpAll(void) const { return obank.beginAll(); }
/// \brief End of all (alive) PcodeOp objects sorted by sequence number
PcodeOpTree::const_iterator endOpAll(void) const { return obank.endAll(); }
/// \brief Start of all (alive) PcodeOp objects attached to a specific Address
PcodeOpTree::const_iterator beginOp(const Address &addr) const { return obank.begin(addr); }
/// \brief End of all (alive) PcodeOp objects attached to a specific Address
PcodeOpTree::const_iterator endOp(const Address &addr) const { return obank.end(addr); }
bool moveRespectingCover(PcodeOp *op,PcodeOp *lastOp); ///< Move given op past \e lastOp respecting covers if possible
const ResolvedUnion *getUnionField(const Datatype *parent,const PcodeOp *op,int4 slot) const;
bool setUnionField(const Datatype *parent,const PcodeOp *op,int4 slot,const ResolvedUnion &resolve);
void forceFacingType(Datatype *parent,int4 fieldNum,PcodeOp *op,int4 slot);
int4 inheritResolution(Datatype *parent,const PcodeOp *op,int4 slot,PcodeOp *oldOp,int4 oldSlot);
// Jumptable routines
JumpTable *linkJumpTable(PcodeOp *op); ///< Link jump-table with a given BRANCHIND
JumpTable *findJumpTable(const PcodeOp *op) const; ///< Find a jump-table associated with a given BRANCHIND
JumpTable *installJumpTable(const Address &addr); ///< Install a new jump-table for the given Address
JumpTable *recoverJumpTable(Funcdata &partial,PcodeOp *op,FlowInfo *flow,JumpTable::RecoveryMode &mode);
JumpTable::RecoveryMode earlyJumpTableFail(PcodeOp *op); ///< Try to determine, early, if jump-table analysis will fail
int4 numJumpTables(void) const { return jumpvec.size(); } ///< Get the number of jump-tables for \b this function
JumpTable *getJumpTable(int4 i) { return jumpvec[i]; } ///< Get the i-th jump-table
void removeJumpTable(JumpTable *jt); ///< Remove/delete the given jump-table
// Block routines
BlockGraph &getStructure(void) { return sblocks; } ///< Get the current control-flow structuring hierarchy
const BlockGraph &getStructure(void) const { return sblocks; } ///< Get the current control-flow structuring hierarchy
const BlockGraph &getBasicBlocks(void) const { return bblocks; } ///< Get the basic blocks container
/// \brief Set the initial ownership range for the given basic block
///
/// \param bb is the given basic block
/// \param beg is the beginning Address of the owned code range
/// \param end is the ending Address of the owned code range
void setBasicBlockRange(BlockBasic *bb,const Address &beg,const Address &end) { bb->setInitialRange(beg, end); }
void removeDoNothingBlock(BlockBasic *bb); ///< Remove a basic block from control-flow that performs no operations
bool removeUnreachableBlocks(bool issuewarning,bool checkexistence);
void pushBranch(BlockBasic *bb,int4 slot,BlockBasic *bbnew);
void removeBranch(BlockBasic *bb,int4 num); ///< Remove the indicated branch from a basic block
BlockBasic *nodeJoinCreateBlock(BlockBasic *block1,BlockBasic *block2,BlockBasic *exita,BlockBasic *exitb,
bool fora_block1ishigh,bool forb_block1ishigh,const Address &addr);
void nodeSplit(BlockBasic *b,int4 inedge);
bool forceGoto(const Address &pcop,const Address &pcdest);
void removeFromFlowSplit(BlockBasic *bl,bool swap);
void switchEdge(FlowBlock *inblock,BlockBasic *outbefore,FlowBlock *outafter);
void spliceBlockBasic(BlockBasic *bl); ///< Merge the given basic block with the block it flows into
void installSwitchDefaults(void); ///< Make sure default switch cases are properly labeled
bool replaceLessequal(PcodeOp *op); ///< Replace INT_LESSEQUAL and INT_SLESSEQUAL expressions
bool distributeIntMultAdd(PcodeOp *op); ///< Distribute constant coefficient to additive input
bool collapseIntMultMult(Varnode *vn); ///< Collapse constant coefficients for two chained CPUI_INT_MULT
static bool compareCallspecs(const FuncCallSpecs *a,const FuncCallSpecs *b);
#ifdef OPACTION_DEBUG
void (*jtcallback)(Funcdata &orig,Funcdata &fd); ///< Hook point debugging the jump-table simplification process
vector<PcodeOp *> modify_list; ///< List of modified ops
vector<string> modify_before; ///< List of "before" strings for modified ops
int4 opactdbg_count; ///< Number of debug statements printed
int4 opactdbg_breakcount; ///< Which debug to break on
bool opactdbg_on; ///< Are we currently doing op action debugs
bool opactdbg_active; ///< \b true if current op mods should be recorded
bool opactdbg_breakon; ///< Has a breakpoint been hit
vector<Address> opactdbg_pclow; ///< Lower bounds on the PC register
vector<Address> opactdbg_pchigh; ///< Upper bounds on the PC register
vector<uintm> opactdbg_uqlow; ///< Lower bounds on the unique register
vector<uintm> opactdbg_uqhigh; ///< Upper bounds on the unique register
void enableJTCallback(void (*jtcb)(Funcdata &orig,Funcdata &fd)) { jtcallback = jtcb; } ///< Enable a debug callback
void disableJTCallback(void) { jtcallback = (void (*)(Funcdata &orig,Funcdata &fd))0; } ///< Disable debug callback
void debugActivate(void) { if (opactdbg_on) opactdbg_active=true; } ///< Turn on recording
void debugDeactivate(void) { opactdbg_active = false; } ///< Turn off recording
void debugModCheck(PcodeOp *op); ///< Cache \e before state of the given PcodeOp
void debugModClear(void); ///< Abandon printing debug for current action
void debugModPrint(const string &actionname); ///< Print before and after strings for PcodeOps modified by given action
bool debugBreak(void) const { return opactdbg_on&&opactdbg_breakon; } ///< Has a breakpoint been hit
int4 debugSize(void) const { return opactdbg_pclow.size(); } ///< Number of code ranges being debug traced
void debugEnable(void) { opactdbg_on = true; opactdbg_count = 0; } ///< Turn on debugging
void debugDisable(void) { opactdbg_on = false; } ///< Turn off debugging
void debugClear(void) {
opactdbg_pclow.clear(); opactdbg_pchigh.clear(); opactdbg_uqlow.clear(); opactdbg_uqhigh.clear(); } ///< Clear debugging ranges
bool debugCheckRange(PcodeOp *op); ///< Check if the given PcodeOp is being debug traced
void debugSetRange(const Address &pclow,const Address &pchigh,
uintm uqlow=~((uintm)0),uintm uqhigh=~((uintm)0)); ///< Add a new memory range to the debug trace
void debugHandleBreak(void) { opactdbg_breakon = false; } ///< Mark a breakpoint as handled
void debugSetBreak(int4 count) { opactdbg_breakcount = count; } ///< Break on a specific trace hit count
void debugPrintRange(int4 i) const; ///< Print the i-th debug trace range
#endif
};
/// \brief A p-code emitter for building PcodeOp objects
///
/// The emitter is attached to a specific Funcdata object. Any p-code generated (by FlowInfo typically)
/// will be instantiated as PcodeOp and Varnode objects and placed in the Funcdata \e dead list.
class PcodeEmitFd : public PcodeEmit {
Funcdata *fd; ///< The Funcdata container to emit to
virtual void dump(const Address &addr,OpCode opc,VarnodeData *outvar,VarnodeData *vars,int4 isize);
public:
void setFuncdata(Funcdata *f) { fd = f; } ///< Establish the container for \b this emitter
};
/// \brief Helper class for determining if Varnodes can trace their value from a legitimate source
///
/// Try to determine if a Varnode (expressed as a particular input to a CALL, CALLIND, or RETURN op)
/// makes sense as parameter passing (or return value) storage by examining the Varnode's ancestors.
/// If it has ancestors that are \e unaffected, \e abnormal inputs, or \e killedbycall, then this is a sign
/// that the Varnode doesn't make a good parameter.
class AncestorRealistic {
/// \brief Node in a depth first traversal of ancestors
class State {
public:
enum {
seen_solid0 = 1, ///< Indicates a \e solid movement into the Varnode occurred on at least one path to MULTIEQUAL
seen_solid1 = 2, ///< Indicates a \e solid movement into anything other than slot 0 occurred.
seen_kill = 4 ///< Indicates the Varnode is killed by a call on at least path to MULTIEQUAL
};
PcodeOp *op; ///< Operation along the path to the Varnode
int4 slot; ///< vn = op->getIn(slot)
uint4 flags; ///< Boolean properties of the node
int4 offset; ///< Offset of the (eventual) trial value, within a possibly larger register
/// \brief Constructor given a Varnode read
///
/// \param o is the PcodeOp reading the Varnode
/// \param s is the input slot
State(PcodeOp *o,int4 s) {
op = o;
slot = s;
flags = 0;
offset = 0;
}
/// \brief Constructor from old state pulled back through a CPUI_SUBPIECE
///
/// Data ultimately in SUBPIECE output is copied from a non-zero offset within the input Varnode. Note this offset
/// \param o is the CPUI_SUBPIECE
/// \param oldState is the old state being pulled back from
State(PcodeOp *o,const State &oldState) {
op = o;
slot = 0;
flags = 0;
offset = oldState.offset + (int4)op->getIn(1)->getOffset();
}
int4 getSolidSlot(void) const { return ((flags & seen_solid0)!=0) ? 0 : 1; } ///< Get slot associated with \e solid movement
void markSolid(int4 s) { flags |= (s==0) ? seen_solid0 : seen_solid1; } ///< Mark given slot as having \e solid movement
void markKill(void) { flags |= seen_kill; } ///< Mark \e killedbycall seen
bool seenSolid(void) const { return ((flags & (seen_solid0|seen_solid1))!=0); } ///< Has \e solid movement been seen
bool seenKill(void) const { return ((flags & seen_kill)!=0); } ///< Has \e killedbycall been seen
};
/// \brief Enumerations for state of depth first traversal
enum {
enter_node, ///< Extending path into new Varnode
pop_success, ///< Backtracking, from path that contained a reasonable ancestor
pop_solid, ///< Backtracking, from path with successful, solid, movement, via COPY, LOAD, or other arith/logical
pop_fail, ///< Backtracking, from path with a bad ancestor
pop_failkill ///< Backtracking, from path with a bad ancestor, specifically killedbycall
};
ParamTrial *trial; ///< Current trial being analyzed for suitability
vector<State> stateStack; ///< Holds the depth-first traversal stack
vector<const Varnode *> markedVn; ///< Holds visited Varnodes to properly trim cycles
int4 multiDepth; ///< Number of MULTIEQUAL ops along current traversal path
bool allowFailingPath; ///< True if we allow and test for failing paths due to conditional execution
/// \brief Mark given Varnode is visited by the traversal
///
/// \param vn is the given Varnode
void mark(Varnode *vn) {
markedVn.push_back(vn);
vn->setMark();
}
int4 enterNode(void); ///< Traverse into a new Varnode
int4 uponPop(int4 command); ///< Pop a Varnode from the traversal stack
bool checkConditionalExe(State &state); ///< Check if current Varnode produced by conditional flow
public:
bool execute(PcodeOp *op,int4 slot,ParamTrial *t,bool allowFail);
};
extern int4 opFlipInPlaceTest(PcodeOp *op,vector<PcodeOp *> &fliplist);
extern void opFlipInPlaceExecute(Funcdata &data,vector<PcodeOp *> &fliplist);
extern PcodeOp *earliestUseInBlock(Varnode *vn,BlockBasic *bl);
extern PcodeOp *cseFindInBlock(PcodeOp *op,Varnode *vn,BlockBasic *bl,PcodeOp *earliest);
extern PcodeOp *cseElimination(Funcdata &data,PcodeOp *op1,PcodeOp *op2);
extern void cseEliminateList(Funcdata &data,vector< pair<uintm,PcodeOp *> > &list,
vector<Varnode *> &outlist);
} // End namespace ghidra
#endif