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rpi_adc_dma_test.c
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rpi_adc_dma_test.c
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// Raspberry Pi ADC DMA tests; see https://iosoft.blog for details
//
// Copyright (c) 2020 Jeremy P Bentham
//
// 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.
//
// v0.01 JPB 9/6/20 Adapted from rpi_adc_ads7884 v0.11
// Modified MCP3008 functions to match
// v0.02 JPB 9/6/20 Corrected MCP3008 min & max frequencies
// v0.03 JPB 10/6/20 Changed MCP3008 max frequency from 2 to 2.6 MHz
// v0.04 JPB 11/6/20 Moved CLOCK_HZ definition to top of rpi_dma_utils.h
#include <stdint.h>
#include <stdlib.h>
#include <unistd.h>
#include <stdio.h>
#include <signal.h>
#include <string.h>
#include <ctype.h>
#include "rpi_dma_utils.h"
#define VERSION "0.04"
#define MCP3008 // ADC to use: MCP3008 or ADS7884
#define SAMPLE_RATE 10000 // Default sample rate (samples/sec)
#if defined(MCP3008)
#define RX_SAMPLE_SIZE 4 // Number of raw Rx bytes per sample
#define ADC_CHAN 0 // ADC channel number
#define ADC_9_BITS 0 // Set non-zero for 9-bit data
#define SPI_CSVAL 0 // Additional CS register settings
#define MIN_SPI_FREQ 10000 // Minimum SPI frequency
#define MAX_SPI_FREQ 2600000 // Maximum SPI frequency
#define VC_MEM_SIZE(ns) (PAGE_SIZE + ((ns)+4)*RX_SAMPLE_SIZE)
#define ADC_VOLTAGE(n) (((n) * 3.3) / 1024.0)
#elif defined(ADS7884)
#define RX_SAMPLE_SIZE 2 // Number of raw Rx bytes per sample
#define ADC_CHAN 0 // ADC channel number (ignored)
#define SPI_CSVAL 0 // Additional CS register settings
#define MIN_SPI_FREQ 1000 // Minimum SPI frequency
#define MAX_SPI_FREQ 42000000// Maximum SPI frequency
#define ADC_9_BITS 1 // Set non-0 for 9-bit data (0 for 8-bit)
#define VC_MEM_SIZE(ns) (PAGE_SIZE + ((ns)+4)*RX_SAMPLE_SIZE)
#define ADC_VOLTAGE(n) (((n) * 3.3) / 1024.0)
#endif
#define SPI0_CE_NUM 0
#define SPI0_CE0_PIN 8
#define SPI0_MISO_PIN 9
#define SPI0_MOSI_PIN 10
#define SPI0_SCLK_PIN 11
#define SPI0_BASE (PHYS_REG_BASE + 0x204000)
#define SPI_CS 0x00
#define SPI_FIFO 0x04
#define SPI_CLK 0x08
#define SPI_DLEN 0x0c
#define SPI_DC 0x14
#define SPI_FIFO_CLR (3 << 4)
#define SPI_TX_FIFO_CLR (1 << 4)
#define SPI_TFR_ACT (1 << 7)
#define SPI_DMA_EN (1 << 8)
#define SPI_AUTO_CS (1 << 11)
// SPI register strings
char *spi_regstrs[] = {"CS", "FIFO", "CLK", "DLEN", "LTOH", "DC", ""};
// Buffer for processed ADC samples
uint16_t *sample_buff;
// Virtual memory pointers to acceess GPIO, DMA & SPI from user space
extern MEM_MAP gpio_regs, dma_regs;
MEM_MAP vc_mem, spi_regs;
void terminate(int sig);
void map_devices(void);
void get_uncached_mem(MEM_MAP *mp, int size);
int adc_sample(int chan);
int adc_dma_sample_mcp3008(MEM_MAP *mp, int chan);
int adc_sample_ads7884(int chan);
int adc_dma_samples(MEM_MAP *mp, int chan, uint16_t *buff, int nsamp);
int adc_dma_samples_mcp3008(MEM_MAP *mp, int chan, uint16_t *buff, int nsamp);
int adc_dma_samples_ads7884(MEM_MAP *mp, int chan, uint16_t *buff, int nsamp);
void dma_test_spi(MEM_MAP *mp);
void dma_wait(int chan);
int mcp3008_tx_data(void *buff, int chan);
int mcp3008_rx_value(void *buff);
int init_spi(int hz);
void spi_clear(void);
void spi_cs(int set);
void spi_xfer(uint8_t *txd, uint8_t *rxd, int len);
void spi_disable(void);
void disp_spi(void);
// Main program
int main(int argc, char *argv[])
{
int args=0, sample_count=0, sample_rate=SAMPLE_RATE;
int f, spi_freq, val, i, n;
printf("SPI ADC test v" VERSION "\n");
while (argc > ++args) // Process command-line args
{
if (argv[args][0] == '-')
{
switch (toupper(argv[args][1]))
{
case 'N': // -N: number of samples
if (args>=argc-1 || !isdigit(argv[args+1][0]))
fprintf(stderr, "Error: no sample count\n");
else
sample_count = atoi(argv[++args]);
break;
case 'R': // -R: sample rate (samples/sec)
if (args>=argc-1 || !isdigit(argv[args+1][0]))
fprintf(stderr, "Error: no sample rate\n");
else
sample_rate = atoi(argv[++args]);
break;
}
}
}
map_devices();
map_uncached_mem(&vc_mem, VC_MEM_SIZE(sample_count));
signal(SIGINT, terminate);
spi_freq = sample_rate * RX_SAMPLE_SIZE*8;
if (spi_freq < MIN_SPI_FREQ)
fail("Invalid sample rate\n");
f = init_spi(spi_freq);
if (sample_count == 0)
{
printf("SPI frequency %u Hz, %u sample/s\n", f, f/(RX_SAMPLE_SIZE*8));
val = adc_sample(ADC_CHAN);
printf("ADC value %u = %4.3fV\n", val, val*3.3/1024.0);
}
else
{
if (!(sample_buff = malloc((sample_count+4) * 2)))
fail("Can't allocate sample buffer\n");
printf("%u samples at %u S/s\n", sample_count, f/(RX_SAMPLE_SIZE*8));
n = adc_dma_samples(&vc_mem, ADC_CHAN, sample_buff, sample_count);
for (i=0; i<n; i++)
printf("%4.3f\n", ADC_VOLTAGE(sample_buff[i]));
}
terminate(0);
}
// Catastrophic failure in initial setup
void fail(char *s)
{
printf(s);
terminate(0);
}
// Free memory segments and exit
void terminate(int sig)
{
printf("Closing\n");
spi_disable();
stop_dma(DMA_CHAN_A);
stop_dma(DMA_CHAN_B);
unmap_periph_mem(&vc_mem);
unmap_periph_mem(&spi_regs);
unmap_periph_mem(&dma_regs);
unmap_periph_mem(&gpio_regs);
if (sample_buff)
free(sample_buff);
exit(0);
}
// Map GPIO, DMA and SPI registers into virtual mem (user space)
// If any of these fail, program will be terminated
void map_devices(void)
{
map_periph(&gpio_regs, (void *)GPIO_BASE, PAGE_SIZE);
map_periph(&dma_regs, (void *)DMA_BASE, PAGE_SIZE);
map_periph(&spi_regs, (void *)SPI0_BASE, PAGE_SIZE);
}
// Get uncached memory
void get_uncached_mem(MEM_MAP *mp, int size)
{
if (!map_uncached_mem(mp, size))
fail("Error: can't allocate uncached memory\n");
}
// Fetch sample from ADC
int adc_sample(int chan)
{
#if defined(MCP3008)
return(adc_dma_sample_mcp3008(&vc_mem, chan));
#elif defined(ADS7884)
adc_sample_ads7884(chan);
return(adc_sample_ads7884(chan));
#endif
}
// Fetch single sample from MCP3008 ADC using DMA
int adc_dma_sample_mcp3008(MEM_MAP *mp, int chan)
{
DMA_CB *cbs=mp->virt;
uint32_t dlen, *txd=(uint32_t *)(cbs+2);
uint8_t *rxdata=(uint8_t *)(txd+0x10);
enable_dma(DMA_CHAN_A);
enable_dma(DMA_CHAN_B);
dlen = 4;
txd[0] = (dlen << 16) | SPI_TFR_ACT;
mcp3008_tx_data(&txd[1], chan);
cbs[0].ti = DMA_SRCE_DREQ | (DMA_SPI_RX_DREQ << 16) | DMA_WAIT_RESP | DMA_CB_DEST_INC;
cbs[0].tfr_len = dlen;
cbs[0].srce_ad = REG_BUS_ADDR(spi_regs, SPI_FIFO);
cbs[0].dest_ad = MEM_BUS_ADDR(mp, rxdata);
cbs[1].ti = DMA_DEST_DREQ | (DMA_SPI_TX_DREQ << 16) | DMA_WAIT_RESP | DMA_CB_SRCE_INC;
cbs[1].tfr_len = dlen + 4;
cbs[1].srce_ad = MEM_BUS_ADDR(mp, txd);
cbs[1].dest_ad = REG_BUS_ADDR(spi_regs, SPI_FIFO);
*REG32(spi_regs, SPI_DC) = (8 << 24) | (4 << 16) | (8 << 8) | 4;
*REG32(spi_regs, SPI_CS) = SPI_TFR_ACT | SPI_DMA_EN | SPI_AUTO_CS | SPI_FIFO_CLR | SPI_CSVAL;
*REG32(spi_regs, SPI_DLEN) = 0;
start_dma(mp, DMA_CHAN_A, &cbs[0], 0);
start_dma(mp, DMA_CHAN_B, &cbs[1], 0);
dma_wait(DMA_CHAN_A);
#if DEBUG
for (int i=0; i<dlen; i++)
printf("%02X ", rxdata[i]);
printf("\n");
#endif
return(mcp3008_rx_value(rxdata));
}
// Fetch last sample from ADS7884 (call twice for current value)
int adc_sample_ads7884(int chan)
{
uint8_t txdata[4]={0xff,0,0,0xff}, rxdata[4];
spi_clear();
spi_cs(1);
spi_xfer(txdata, rxdata, sizeof(txdata));
spi_cs(0);
return(((int)rxdata[1] << 4) | ((int)rxdata[2] >> 4));
}
// Fetch samples from ADC using DMA
int adc_dma_samples(MEM_MAP *mp, int chan, uint16_t *buff, int nsamp)
{
#if defined(MCP3008)
return(adc_dma_samples_mcp3008(mp, chan, buff, nsamp));
#elif defined(ADS7884)
return(adc_dma_samples_ads7884(mp, chan, buff, nsamp));
#endif
}
// Fetch samples from MCP3008 ADC using DMA
int adc_dma_samples_mcp3008(MEM_MAP *mp, int chan, uint16_t *buff, int nsamp)
{
DMA_CB *cbs=mp->virt;
uint32_t i, dlen, *txd=(uint32_t *)(cbs+4), *pindata=(uint32_t *)(txd+0x10);
uint8_t *rxdata=(uint8_t *)(txd+0x20);
gpio_out(SPI0_CE0_PIN, 1); // Get control of CE pin
gpio_mode(SPI0_CE0_PIN, GPIO_OUT);
enable_dma(DMA_CHAN_A); // Enable 2 DMA channels
enable_dma(DMA_CHAN_B);
mcp3008_tx_data(&txd[1], chan); // Create Tx data word
dlen = nsamp * 4; // One 4-byte word per sample
*pindata = 1 << SPI0_CE0_PIN; // Data to set/clear Chip Select pin
txd[0] = (dlen << 16) | SPI_TFR_ACT;// First Tx byte: SPI settings
// Control block 0: read data from SPI FIFO
cbs[0].ti = DMA_SRCE_DREQ | (DMA_SPI_RX_DREQ << 16) | DMA_WAIT_RESP | DMA_CB_DEST_INC;
cbs[0].tfr_len = dlen;
cbs[0].srce_ad = REG_BUS_ADDR(spi_regs, SPI_FIFO);
cbs[0].dest_ad = MEM_BUS_ADDR(mp, rxdata);
// Control block 1: CS high
cbs[1].srce_ad = cbs[2].srce_ad = MEM_BUS_ADDR(mp, pindata);
cbs[1].dest_ad = REG_BUS_ADDR(gpio_regs, GPIO_SET0);
cbs[1].tfr_len = cbs[2].tfr_len = cbs[3].tfr_len = 4;
cbs[1].ti = cbs[2].ti = DMA_DEST_DREQ | (DMA_SPI_TX_DREQ << 16) | DMA_WAIT_RESP | DMA_CB_SRCE_INC;
// Control block 2: CS low
cbs[2].dest_ad = REG_BUS_ADDR(gpio_regs, GPIO_CLR0);
// Control block 3: write data to Tx FIFO
cbs[3].ti = DMA_DEST_DREQ | (DMA_SPI_TX_DREQ << 16) | DMA_WAIT_RESP | DMA_CB_SRCE_INC;
cbs[3].srce_ad = MEM_BUS_ADDR(mp, &txd[1]);
cbs[3].dest_ad = REG_BUS_ADDR(spi_regs, SPI_FIFO);
// Link CB1, CB2 and CB3 in endless loop
cbs[1].next_cb = MEM_BUS_ADDR(mp, &cbs[2]);
cbs[2].next_cb = MEM_BUS_ADDR(mp, &cbs[3]);
cbs[3].next_cb = MEM_BUS_ADDR(mp, &cbs[1]);
// DMA request every 4 bytes, panic if 8 bytes
*REG32(spi_regs, SPI_DC) = (8 << 24) | (4 << 16) | (8 << 8) | 4;
// Clear SPI length register and Tx & Rx FIFOs, enable DMA
*REG32(spi_regs, SPI_DLEN) = 0;
*REG32(spi_regs, SPI_CS) = SPI_TFR_ACT | SPI_DMA_EN | SPI_AUTO_CS | SPI_FIFO_CLR | SPI_CSVAL;
// Send out first Tx bytes
*REG32(spi_regs, SPI_FIFO) = txd[0];
// Start DMA, wait until complete
start_dma(mp, DMA_CHAN_A, &cbs[0], 0);
start_dma(mp, DMA_CHAN_B, &cbs[3], DMA_PRIORITY(15));
dma_wait(DMA_CHAN_A);
// Relinquish control of CE pin
gpio_mode(SPI0_CE0_PIN, GPIO_ALT0);
#if DEBUG
for (i=0; i<dlen; i++)
printf("%02X ", rxdata[i]);
printf("\n");
#endif
// Convert 32-bit raw values to 16-bit data
for (i=0; i<nsamp; i++)
buff[i] = mcp3008_rx_value(&rxdata[i*4]);
return(nsamp);
}
// Fetch samples from ADS7884 ADC using DMA
int adc_dma_samples_ads7884(MEM_MAP *mp, int chan, uint16_t *buff, int nsamp)
{
DMA_CB *cbs=mp->virt;
uint32_t i, dlen, shift, *txd=(uint32_t *)(cbs+3);
uint8_t *rxdata=(uint8_t *)(txd+0x10);
enable_dma(DMA_CHAN_A); // Enable DMA channels
enable_dma(DMA_CHAN_B);
dlen = (nsamp+3) * 2; // 2 bytes/sample, plus 3 dummy samples
// Control block 0: store Rx data in buffer
cbs[0].ti = DMA_SRCE_DREQ | (DMA_SPI_RX_DREQ << 16) | DMA_WAIT_RESP | DMA_CB_DEST_INC;
cbs[0].tfr_len = dlen;
cbs[0].srce_ad = REG_BUS_ADDR(spi_regs, SPI_FIFO);
cbs[0].dest_ad = MEM_BUS_ADDR(mp, rxdata);
// Control block 1: continuously repeat last Tx word (pulse CS low)
cbs[1].srce_ad = MEM_BUS_ADDR(mp, &txd[2]);
cbs[1].dest_ad = REG_BUS_ADDR(spi_regs, SPI_FIFO);
cbs[1].tfr_len = 4;
cbs[1].ti = DMA_DEST_DREQ | (DMA_SPI_TX_DREQ << 16) | DMA_WAIT_RESP | DMA_CB_SRCE_INC;
cbs[1].next_cb = MEM_BUS_ADDR(mp, &cbs[1]);
// Control block 2: send first 2 Tx words, then switch to CB1 for the rest
cbs[2].srce_ad = MEM_BUS_ADDR(mp, &txd[0]);
cbs[2].dest_ad = REG_BUS_ADDR(spi_regs, SPI_FIFO);
cbs[2].tfr_len = 8;
cbs[2].ti = DMA_DEST_DREQ | (DMA_SPI_TX_DREQ << 16) | DMA_WAIT_RESP | DMA_CB_SRCE_INC;
cbs[2].next_cb = MEM_BUS_ADDR(mp, &cbs[1]);
// DMA request every 4 bytes, panic if 8 bytes
*REG32(spi_regs, SPI_DC) = (8 << 24) | (4 << 16) | (8 << 8) | 4;
// Clear SPI length register and Tx & Rx FIFOs, enable DMA
*REG32(spi_regs, SPI_DLEN) = 0;
*REG32(spi_regs, SPI_CS) = SPI_TFR_ACT | SPI_DMA_EN | SPI_AUTO_CS | SPI_FIFO_CLR | SPI_CSVAL;
// Data to be transmited: 32-bit words, MS bit of LS byte is sent first
txd[0] = (dlen << 16) | SPI_TFR_ACT;// SPI config: data len & TI setting
txd[1] = 0xffffffff; // Set CS high
txd[2] = 0x01000100; // Pulse CS low
// Enable DMA, wait until complete
start_dma(mp, DMA_CHAN_A, &cbs[0], 0);
start_dma(mp, DMA_CHAN_B, &cbs[2], 0);
dma_wait(DMA_CHAN_A);
#if DEBUG
for (i=0; i<dlen; i++)
printf("%02X ", rxdata[i]);
printf("\n");
#endif
// Check whether Rx data has 1 bit delay with respect to Tx
shift = rxdata[4] & 0x80 ? 3 : 4;
// Convert raw data to 16-bit unsigned values, ignoring first 3
for (i=0; i<nsamp; i++)
buff[i] = ((rxdata[i*2+6]<<8 | rxdata[i*2+7]) >> shift) & 0x3ff;
return(nsamp);
}
// Wait until DMA is complete
void dma_wait(int chan)
{
int n = 1000;
do {
usleep(100);
} while (dma_transfer_len(chan) && --n);
if (n == 0)
printf("DMA transfer timeout\n");
}
// Return Tx data for MCP3008
int mcp3008_tx_data(void *buff, int chan)
{
#if ADC_9_BITS
uint8_t txd[2]={0xc0|(chan<<3), 0x00};
#else
uint8_t txd[3]={0x01, 0x80|(chan<<4), 0x00};
#endif
memcpy(buff, txd, sizeof(txd));
return(sizeof(txd));
}
// Return value from ADC Rx data
int mcp3008_rx_value(void *buff)
{
uint8_t *rxd=buff;
#if ADC_9_BITS
return((((int)rxd[0] << 9) | ((int)rxd[1] << 1)) & 0x3ff);
#else
return(((int)(rxd[1]&3)<<8) | rxd[2]);
#endif
}
// Initialise SPI0, given desired clock freq; return actual value
int init_spi(int hz)
{
int f, div = (CLOCK_HZ / hz + 1) & ~1;
gpio_set(SPI0_CE0_PIN, GPIO_ALT0, GPIO_NOPULL);
gpio_set(SPI0_MISO_PIN, GPIO_ALT0, GPIO_PULLUP);
gpio_set(SPI0_MOSI_PIN, GPIO_ALT0, GPIO_NOPULL);
gpio_set(SPI0_SCLK_PIN, GPIO_ALT0, GPIO_NOPULL);
while (div==0 || (f = CLOCK_HZ/div) > MAX_SPI_FREQ)
div += 2;
*REG32(spi_regs, SPI_CS) = 0x30;
*REG32(spi_regs, SPI_CLK) = div;
return(f);
}
// Clear SPI FIFOs
void spi_clear(void)
{
*REG32(spi_regs, SPI_CS) = SPI_FIFO_CLR;
}
// Set / clear SPI chip select
void spi_cs(int set)
{
uint32_t csval = *REG32(spi_regs, SPI_CS);
*REG32(spi_regs, SPI_CS) = set ? csval | 0x80 : csval & ~0x80;
}
// Transfer SPI bytes
void spi_xfer(uint8_t *txd, uint8_t *rxd, int len)
{
while (len--)
{
*REG8(spi_regs, SPI_FIFO) = *txd++;
while((*REG32(spi_regs, SPI_CS) & (1<<17)) == 0) ;
*rxd++ = *REG32(spi_regs, SPI_FIFO);
}
}
// Disable SPI
void spi_disable(void)
{
*REG32(spi_regs, SPI_CS) = SPI_FIFO_CLR;
*REG32(spi_regs, SPI_CS) = 0;
}
// Display DMA registers
void disp_spi(void)
{
volatile uint32_t *p=REG32(spi_regs, SPI_CS);
int i=0;
while (spi_regstrs[i][0])
printf("%-4s %08X ", spi_regstrs[i++], *p++);
printf("\n");
}
// EOF