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annotate core/PRU.cpp @ 253:33e0e4831763 prerelease

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Started prerelease branch; updated PRU code to be able to run on either PRU.
author andrewm
date Mon, 16 May 2016 12:13:58 +0100
parents c0bf6157f67e
children abd3657016ea
rev   line source
andrewm@0 1 /*
andrewm@0 2 * PRU.cpp
andrewm@0 3 *
andrewm@0 4 * Code for communicating with the Programmable Realtime Unit (PRU)
andrewm@0 5 * on the BeagleBone AM335x series processors. The PRU loads and runs
andrewm@0 6 * a separate code image compiled from an assembly file. Here it is
andrewm@0 7 * used to handle audio and SPI ADC/DAC data.
andrewm@0 8 *
andrewm@0 9 * This code is specific to the PRU code in the assembly file; for example,
andrewm@0 10 * it uses certain GPIO resources that correspond to that image.
andrewm@0 11 *
andrewm@0 12 * Created on: May 27, 2014
andrewm@0 13 * Author: andrewm
andrewm@0 14 */
andrewm@0 15
andrewm@0 16 #include "../include/PRU.h"
andrewm@0 17 #include "../include/prussdrv.h"
andrewm@0 18 #include "../include/pruss_intc_mapping.h"
giuliomoro@19 19 #include "../include/digital_gpio_mapping.h"
andrewm@0 20 #include "../include/GPIOcontrol.h"
andrewm@45 21 #include "../include/BeagleRT.h"
andrewm@15 22 #include "../include/pru_rtaudio_bin.h"
andrewm@0 23
andrewm@0 24 #include <iostream>
andrewm@0 25 #include <stdlib.h>
andrewm@0 26 #include <cstdio>
andrewm@0 27 #include <cerrno>
andrewm@0 28 #include <fcntl.h>
andrewm@0 29 #include <sys/mman.h>
giuliomoro@16 30 #include <unistd.h>
andrewm@0 31
andrewm@0 32 // Xenomai-specific includes
andrewm@0 33 #include <sys/mman.h>
andrewm@0 34 #include <native/task.h>
andrewm@0 35 #include <native/timer.h>
andrewm@0 36 #include <rtdk.h>
andrewm@0 37
andrewm@0 38 using namespace std;
andrewm@0 39
andrewm@0 40 #define PRU_MEM_MCASP_OFFSET 0x2000 // Offset within PRU-SHARED RAM
andrewm@253 41 #define PRU_MEM_MCASP_LENGTH 0x1000 // Length of McASP memory, in bytes
andrewm@0 42 #define PRU_MEM_DAC_OFFSET 0x0 // Offset within PRU0 RAM
andrewm@0 43 #define PRU_MEM_DAC_LENGTH 0x2000 // Length of ADC+DAC memory, in bytes
andrewm@0 44 #define PRU_MEM_COMM_OFFSET 0x0 // Offset within PRU-SHARED RAM
giuliomoro@19 45 #define PRU_MEM_DIGITAL_OFFSET 0x1000 //Offset within PRU-SHARED RAM
giuliomoro@19 46 #define MEM_DIGITAL_BUFFER1_OFFSET 0x400 //Start pointer to DIGITAL_BUFFER1, which is 256 words.
giuliomoro@16 47 // 256 is the maximum number of frames allowed
andrewm@0 48 #define PRU_SHOULD_STOP 0
andrewm@0 49 #define PRU_CURRENT_BUFFER 1
andrewm@0 50 #define PRU_BUFFER_FRAMES 2
andrewm@0 51 #define PRU_SHOULD_SYNC 3
andrewm@0 52 #define PRU_SYNC_ADDRESS 4
andrewm@0 53 #define PRU_SYNC_PIN_MASK 5
andrewm@253 54 #define PRU_LED_ADDRESS 6
andrewm@253 55 #define PRU_LED_PIN_MASK 7
andrewm@253 56 #define PRU_FRAME_COUNT 8
andrewm@253 57 #define PRU_USE_SPI 9
andrewm@12 58 #define PRU_SPI_NUM_CHANNELS 10
andrewm@253 59 #define PRU_USE_DIGITAL 11
andrewm@253 60 #define PRU_PRU_NUMBER 12
giuliomoro@16 61
giuliomoro@19 62 short int digitalPins[NUM_DIGITALS]={
giuliomoro@16 63 GPIO_NO_BIT_0,
giuliomoro@16 64 GPIO_NO_BIT_1,
giuliomoro@16 65 GPIO_NO_BIT_2,
giuliomoro@16 66 GPIO_NO_BIT_3,
giuliomoro@16 67 GPIO_NO_BIT_4,
giuliomoro@16 68 GPIO_NO_BIT_5,
giuliomoro@16 69 GPIO_NO_BIT_6,
giuliomoro@16 70 GPIO_NO_BIT_7,
giuliomoro@16 71 GPIO_NO_BIT_8,
giuliomoro@16 72 GPIO_NO_BIT_9,
giuliomoro@16 73 GPIO_NO_BIT_10,
giuliomoro@16 74 GPIO_NO_BIT_11,
giuliomoro@16 75 GPIO_NO_BIT_12,
giuliomoro@16 76 GPIO_NO_BIT_13,
giuliomoro@16 77 GPIO_NO_BIT_14,
giuliomoro@16 78 GPIO_NO_BIT_15,
giuliomoro@16 79 };
andrewm@0 80
andrewm@12 81 #define PRU_SAMPLE_INTERVAL_NS 11338 // 88200Hz per SPI sample = 11.338us
andrewm@0 82
andrewm@0 83 #define GPIO0_ADDRESS 0x44E07000
andrewm@0 84 #define GPIO1_ADDRESS 0x4804C000
andrewm@0 85 #define GPIO_SIZE 0x198
andrewm@0 86 #define GPIO_CLEARDATAOUT (0x190 / 4)
andrewm@0 87 #define GPIO_SETDATAOUT (0x194 / 4)
andrewm@0 88
andrewm@0 89 #define TEST_PIN_GPIO_BASE GPIO0_ADDRESS // Use GPIO0(31) for debugging
andrewm@0 90 #define TEST_PIN_MASK (1 << 31)
andrewm@0 91 #define TEST_PIN2_MASK (1 << 26)
andrewm@0 92
andrewm@0 93 #define USERLED3_GPIO_BASE GPIO1_ADDRESS // GPIO1(24) is user LED 3
andrewm@0 94 #define USERLED3_PIN_MASK (1 << 24)
andrewm@0 95
andrewm@0 96 const unsigned int PRU::kPruGPIODACSyncPin = 5; // GPIO0(5); P9-17
andrewm@0 97 const unsigned int PRU::kPruGPIOADCSyncPin = 48; // GPIO1(16); P9-15
andrewm@0 98
andrewm@0 99 const unsigned int PRU::kPruGPIOTestPin = 60; // GPIO1(28); P9-12
andrewm@0 100 const unsigned int PRU::kPruGPIOTestPin2 = 31; // GPIO0(31); P9-13
andrewm@0 101 const unsigned int PRU::kPruGPIOTestPin3 = 26; // GPIO0(26); P8-14
andrewm@0 102
giuliomoro@231 103 extern int gShouldStop;
andrewm@0 104 extern int gRTAudioVerbose;
andrewm@0 105
andrewm@0 106 // Constructor: specify a PRU number (0 or 1)
andrewm@45 107 PRU::PRU(BeagleRTContext *input_context)
andrewm@45 108 : context(input_context), pru_number(0), running(false), analog_enabled(false),
andrewm@45 109 digital_enabled(false), gpio_enabled(false), led_enabled(false),
andrewm@45 110 gpio_test_pin_enabled(false),
andrewm@45 111 pru_buffer_comm(0), pru_buffer_spi_dac(0), pru_buffer_spi_adc(0),
andrewm@45 112 pru_buffer_digital(0), pru_buffer_audio_dac(0), pru_buffer_audio_adc(0),
andrewm@45 113 xenomai_gpio_fd(-1), xenomai_gpio(0)
andrewm@0 114 {
andrewm@0 115
andrewm@0 116 }
andrewm@0 117
andrewm@0 118 // Destructor
andrewm@0 119 PRU::~PRU()
andrewm@0 120 {
andrewm@0 121 if(running)
andrewm@0 122 disable();
andrewm@0 123 if(gpio_enabled)
andrewm@0 124 cleanupGPIO();
andrewm@0 125 if(xenomai_gpio_fd >= 0)
andrewm@0 126 close(xenomai_gpio_fd);
andrewm@0 127 }
andrewm@0 128
andrewm@0 129 // Prepare the GPIO pins needed for the PRU
andrewm@0 130 // If include_test_pin is set, the GPIO output
andrewm@0 131 // is also prepared for an output which can be
andrewm@0 132 // viewed on a scope. If include_led is set,
andrewm@0 133 // user LED 3 on the BBB is taken over by the PRU
andrewm@0 134 // to indicate activity
andrewm@45 135 int PRU::prepareGPIO(int include_test_pin, int include_led)
andrewm@0 136 {
andrewm@45 137 if(context->analogFrames != 0) {
andrewm@0 138 // Prepare DAC CS/ pin: output, high to begin
andrewm@0 139 if(gpio_export(kPruGPIODACSyncPin)) {
andrewm@0 140 if(gRTAudioVerbose)
andrewm@0 141 cout << "Warning: couldn't export DAC sync pin\n";
andrewm@0 142 }
andrewm@0 143 if(gpio_set_dir(kPruGPIODACSyncPin, OUTPUT_PIN)) {
andrewm@0 144 if(gRTAudioVerbose)
andrewm@0 145 cout << "Couldn't set direction on DAC sync pin\n";
andrewm@0 146 return -1;
andrewm@0 147 }
andrewm@0 148 if(gpio_set_value(kPruGPIODACSyncPin, HIGH)) {
andrewm@0 149 if(gRTAudioVerbose)
andrewm@0 150 cout << "Couldn't set value on DAC sync pin\n";
andrewm@0 151 return -1;
andrewm@0 152 }
andrewm@0 153
andrewm@0 154 // Prepare ADC CS/ pin: output, high to begin
andrewm@0 155 if(gpio_export(kPruGPIOADCSyncPin)) {
andrewm@0 156 if(gRTAudioVerbose)
andrewm@0 157 cout << "Warning: couldn't export ADC sync pin\n";
andrewm@0 158 }
andrewm@0 159 if(gpio_set_dir(kPruGPIOADCSyncPin, OUTPUT_PIN)) {
andrewm@0 160 if(gRTAudioVerbose)
andrewm@0 161 cout << "Couldn't set direction on ADC sync pin\n";
andrewm@0 162 return -1;
andrewm@0 163 }
andrewm@0 164 if(gpio_set_value(kPruGPIOADCSyncPin, HIGH)) {
andrewm@0 165 if(gRTAudioVerbose)
andrewm@0 166 cout << "Couldn't set value on ADC sync pin\n";
andrewm@0 167 return -1;
andrewm@0 168 }
andrewm@0 169
andrewm@45 170 analog_enabled = true;
andrewm@0 171 }
andrewm@0 172
andrewm@45 173 if(context->digitalFrames != 0){
andrewm@45 174 for(unsigned int i = 0; i < context->digitalChannels; i++){
giuliomoro@19 175 if(gpio_export(digitalPins[i])) {
giuliomoro@16 176 if(gRTAudioVerbose)
giuliomoro@38 177 cerr << "Warning: couldn't export digital GPIO pin " << digitalPins[i] << "\n"; // this is left as a warning because if the pin has been exported by somebody else, can still be used
giuliomoro@16 178 }
giuliomoro@38 179 if(gpio_set_dir(digitalPins[i], INPUT_PIN)) {
giuliomoro@16 180 if(gRTAudioVerbose)
giuliomoro@38 181 cerr << "Error: Couldn't set direction on digital GPIO pin " << digitalPins[i] << "\n";
giuliomoro@16 182 return -1;
giuliomoro@16 183 }
giuliomoro@16 184 }
andrewm@45 185 digital_enabled = true;
giuliomoro@16 186 }
giuliomoro@16 187
andrewm@0 188 if(include_test_pin) {
andrewm@0 189 // Prepare GPIO test output (for debugging), low to begin
andrewm@0 190 if(gpio_export(kPruGPIOTestPin)) {
andrewm@0 191 if(gRTAudioVerbose)
andrewm@0 192 cout << "Warning: couldn't export GPIO test pin\n";
andrewm@0 193 }
andrewm@0 194 if(gpio_set_dir(kPruGPIOTestPin, OUTPUT_PIN)) {
andrewm@0 195 if(gRTAudioVerbose)
andrewm@0 196 cout << "Couldn't set direction on GPIO test pin\n";
andrewm@0 197 return -1;
andrewm@0 198 }
andrewm@0 199 if(gpio_set_value(kPruGPIOTestPin, LOW)) {
andrewm@0 200 if(gRTAudioVerbose)
andrewm@0 201 cout << "Couldn't set value on GPIO test pin\n";
andrewm@0 202 return -1;
andrewm@0 203 }
andrewm@0 204
andrewm@0 205 if(gpio_export(kPruGPIOTestPin2)) {
andrewm@0 206 if(gRTAudioVerbose)
andrewm@0 207 cout << "Warning: couldn't export GPIO test pin 2\n";
andrewm@0 208 }
andrewm@0 209 if(gpio_set_dir(kPruGPIOTestPin2, OUTPUT_PIN)) {
andrewm@0 210 if(gRTAudioVerbose)
andrewm@0 211 cout << "Couldn't set direction on GPIO test pin 2\n";
andrewm@0 212 return -1;
andrewm@0 213 }
andrewm@0 214 if(gpio_set_value(kPruGPIOTestPin2, LOW)) {
andrewm@0 215 if(gRTAudioVerbose)
andrewm@0 216 cout << "Couldn't set value on GPIO test pin 2\n";
andrewm@0 217 return -1;
andrewm@0 218 }
andrewm@0 219
andrewm@0 220 if(gpio_export(kPruGPIOTestPin3)) {
andrewm@0 221 if(gRTAudioVerbose)
andrewm@0 222 cout << "Warning: couldn't export GPIO test pin 3\n";
andrewm@0 223 }
andrewm@0 224 if(gpio_set_dir(kPruGPIOTestPin3, OUTPUT_PIN)) {
andrewm@0 225 if(gRTAudioVerbose)
andrewm@0 226 cout << "Couldn't set direction on GPIO test pin 3\n";
andrewm@0 227 return -1;
andrewm@0 228 }
andrewm@0 229 if(gpio_set_value(kPruGPIOTestPin3, LOW)) {
andrewm@0 230 if(gRTAudioVerbose)
andrewm@0 231 cout << "Couldn't set value on GPIO test pin 3\n";
andrewm@0 232 return -1;
andrewm@0 233 }
andrewm@0 234 gpio_test_pin_enabled = true;
andrewm@0 235 }
andrewm@0 236
andrewm@0 237 if(include_led) {
andrewm@0 238 // Turn off system function for LED3 so it can be reused by PRU
andrewm@0 239 led_set_trigger(3, "none");
andrewm@0 240 led_enabled = true;
andrewm@0 241 }
andrewm@0 242
andrewm@0 243 gpio_enabled = true;
andrewm@0 244
andrewm@0 245 return 0;
andrewm@0 246 }
andrewm@0 247
andrewm@0 248 // Clean up the GPIO at the end
andrewm@0 249 void PRU::cleanupGPIO()
andrewm@0 250 {
andrewm@0 251 if(!gpio_enabled)
andrewm@0 252 return;
andrewm@45 253 if(analog_enabled) {
andrewm@0 254 gpio_unexport(kPruGPIODACSyncPin);
andrewm@0 255 gpio_unexport(kPruGPIOADCSyncPin);
andrewm@0 256 }
giuliomoro@19 257 if(digital_enabled){
andrewm@45 258 for(unsigned int i = 0; i < context->digitalChannels; i++){
giuliomoro@19 259 gpio_unexport(digitalPins[i]);
giuliomoro@16 260 }
giuliomoro@16 261 }
andrewm@0 262 if(gpio_test_pin_enabled) {
andrewm@0 263 gpio_unexport(kPruGPIOTestPin);
andrewm@0 264 gpio_unexport(kPruGPIOTestPin2);
andrewm@0 265 gpio_unexport(kPruGPIOTestPin3);
andrewm@0 266 }
andrewm@0 267 if(led_enabled) {
andrewm@0 268 // Set LED back to default eMMC status
andrewm@0 269 // TODO: make it go back to its actual value before this program,
andrewm@0 270 // rather than the system default
andrewm@0 271 led_set_trigger(3, "mmc1");
andrewm@0 272 }
andrewm@0 273 gpio_enabled = gpio_test_pin_enabled = false;
andrewm@0 274 }
andrewm@0 275
andrewm@0 276 // Initialise and open the PRU
andrewm@12 277 int PRU::initialise(int pru_num, int frames_per_buffer, int spi_channels, bool xenomai_test_pin)
andrewm@0 278 {
andrewm@0 279 uint32_t *pruMem = 0;
andrewm@0 280
andrewm@0 281 if(!gpio_enabled) {
andrewm@0 282 rt_printf("initialise() called before GPIO enabled\n");
andrewm@0 283 return 1;
andrewm@0 284 }
andrewm@0 285
andrewm@0 286 pru_number = pru_num;
andrewm@0 287
andrewm@0 288 /* Initialize structure used by prussdrv_pruintc_intc */
andrewm@0 289 /* PRUSS_INTC_INITDATA is found in pruss_intc_mapping.h */
andrewm@0 290 tpruss_intc_initdata pruss_intc_initdata = PRUSS_INTC_INITDATA;
andrewm@0 291
andrewm@0 292 /* Allocate and initialize memory */
andrewm@0 293 prussdrv_init();
andrewm@45 294 if(prussdrv_open(PRU_EVTOUT_0)) {
andrewm@0 295 rt_printf("Failed to open PRU driver\n");
andrewm@0 296 return 1;
andrewm@0 297 }
andrewm@0 298
andrewm@0 299 /* Map PRU's INTC */
andrewm@0 300 prussdrv_pruintc_init(&pruss_intc_initdata);
andrewm@0 301
andrewm@0 302 /* Map PRU memory to pointers */
andrewm@0 303 prussdrv_map_prumem (PRUSS0_SHARED_DATARAM, (void **)&pruMem);
andrewm@0 304 pru_buffer_comm = (uint32_t *)&pruMem[PRU_MEM_COMM_OFFSET/sizeof(uint32_t)];
andrewm@0 305 pru_buffer_audio_dac = (int16_t *)&pruMem[PRU_MEM_MCASP_OFFSET/sizeof(uint32_t)];
andrewm@0 306
andrewm@12 307 /* ADC memory starts 2(ch)*2(buffers)*bufsize samples later */
andrewm@45 308 pru_buffer_audio_adc = &pru_buffer_audio_dac[4 * context->audioFrames];
andrewm@0 309
andrewm@45 310 if(analog_enabled) {
andrewm@0 311 prussdrv_map_prumem (pru_number == 0 ? PRUSS0_PRU0_DATARAM : PRUSS0_PRU1_DATARAM, (void **)&pruMem);
andrewm@0 312 pru_buffer_spi_dac = (uint16_t *)&pruMem[PRU_MEM_DAC_OFFSET/sizeof(uint32_t)];
andrewm@0 313
andrewm@12 314 /* ADC memory starts after N(ch)*2(buffers)*bufsize samples */
andrewm@45 315 pru_buffer_spi_adc = &pru_buffer_spi_dac[2 * context->analogChannels * context->analogFrames];
andrewm@0 316 }
andrewm@0 317 else {
andrewm@0 318 pru_buffer_spi_dac = pru_buffer_spi_adc = 0;
andrewm@0 319 }
andrewm@0 320
giuliomoro@19 321 if(digital_enabled) {
giuliomoro@16 322 prussdrv_map_prumem (PRUSS0_SHARED_DATARAM, (void **)&pruMem);
giuliomoro@19 323 pru_buffer_digital = (uint32_t *)&pruMem[PRU_MEM_DIGITAL_OFFSET/sizeof(uint32_t)];
giuliomoro@16 324 }
giuliomoro@16 325 else {
giuliomoro@19 326 pru_buffer_digital = 0;
giuliomoro@16 327 }
andrewm@45 328
andrewm@0 329 /* Set up flags */
andrewm@0 330 pru_buffer_comm[PRU_SHOULD_STOP] = 0;
andrewm@0 331 pru_buffer_comm[PRU_CURRENT_BUFFER] = 0;
andrewm@45 332 pru_buffer_comm[PRU_BUFFER_FRAMES] = context->analogFrames;
andrewm@0 333 pru_buffer_comm[PRU_SHOULD_SYNC] = 0;
andrewm@0 334 pru_buffer_comm[PRU_SYNC_ADDRESS] = 0;
andrewm@0 335 pru_buffer_comm[PRU_SYNC_PIN_MASK] = 0;
andrewm@253 336 pru_buffer_comm[PRU_PRU_NUMBER] = pru_number;
andrewm@0 337 if(led_enabled) {
andrewm@0 338 pru_buffer_comm[PRU_LED_ADDRESS] = USERLED3_GPIO_BASE;
andrewm@0 339 pru_buffer_comm[PRU_LED_PIN_MASK] = USERLED3_PIN_MASK;
andrewm@0 340 }
andrewm@0 341 else {
andrewm@0 342 pru_buffer_comm[PRU_LED_ADDRESS] = 0;
andrewm@0 343 pru_buffer_comm[PRU_LED_PIN_MASK] = 0;
andrewm@0 344 }
andrewm@45 345 if(analog_enabled) {
andrewm@0 346 pru_buffer_comm[PRU_USE_SPI] = 1;
andrewm@45 347 pru_buffer_comm[PRU_SPI_NUM_CHANNELS] = context->analogChannels;
andrewm@0 348 }
andrewm@0 349 else {
andrewm@0 350 pru_buffer_comm[PRU_USE_SPI] = 0;
andrewm@12 351 pru_buffer_comm[PRU_SPI_NUM_CHANNELS] = 0;
andrewm@0 352 }
giuliomoro@19 353 if(digital_enabled) {
giuliomoro@38 354 pru_buffer_comm[PRU_USE_DIGITAL] = 1;
giuliomoro@38 355 //TODO: add mask
giuliomoro@16 356 }
giuliomoro@16 357 else {
giuliomoro@38 358 pru_buffer_comm[PRU_USE_DIGITAL] = 0;
giuliomoro@38 359
giuliomoro@16 360 }
andrewm@0 361
giuliomoro@38 362 /* Clear ADC and DAC memory.*/
giuliomoro@38 363 //TODO: this initialisation should only address the memory effectively used by these buffers, i.e.:depend on the number of frames
giuliomoro@38 364 // (otherwise might cause issues if we move memory locations later on)
andrewm@45 365 if(analog_enabled) {
andrewm@0 366 for(int i = 0; i < PRU_MEM_DAC_LENGTH / 2; i++)
andrewm@0 367 pru_buffer_spi_dac[i] = 0;
giuliomoro@38 368 if(digital_enabled){
giuliomoro@38 369 for(int i = 0; i < PRU_MEM_DIGITAL_OFFSET*2; i++)
giuliomoro@38 370 pru_buffer_digital[i] = 0x0000ffff; // set to all inputs, to avoid unexpected spikes
giuliomoro@38 371 }
andrewm@0 372 }
andrewm@0 373 for(int i = 0; i < PRU_MEM_MCASP_LENGTH / 2; i++)
andrewm@0 374 pru_buffer_audio_dac[i] = 0;
andrewm@45 375
andrewm@0 376 /* If using GPIO test pin for Xenomai (for debugging), initialise the pointer now */
andrewm@0 377 if(xenomai_test_pin && xenomai_gpio_fd < 0) {
andrewm@0 378 xenomai_gpio_fd = open("/dev/mem", O_RDWR);
andrewm@0 379 if(xenomai_gpio_fd < 0)
andrewm@0 380 rt_printf("Unable to open /dev/mem for GPIO test pin\n");
andrewm@0 381 else {
andrewm@0 382 xenomai_gpio = (uint32_t *)mmap(0, GPIO_SIZE, PROT_READ | PROT_WRITE, MAP_SHARED, xenomai_gpio_fd, TEST_PIN_GPIO_BASE);
andrewm@0 383 if(xenomai_gpio == MAP_FAILED) {
andrewm@0 384 rt_printf("Unable to map GPIO address for test pin\n");
andrewm@0 385 xenomai_gpio = 0;
andrewm@0 386 close(xenomai_gpio_fd);
andrewm@0 387 xenomai_gpio_fd = -1;
andrewm@0 388 }
andrewm@0 389 }
andrewm@0 390 }
andrewm@0 391
andrewm@81 392 // Allocate audio buffers
andrewm@81 393 context->audioIn = (float *)malloc(2 * context->audioFrames * sizeof(float));
andrewm@81 394 context->audioOut = (float *)malloc(2 * context->audioFrames * sizeof(float));
andrewm@81 395 if(context->audioIn == 0 || context->audioOut == 0) {
andrewm@81 396 rt_printf("Error: couldn't allocate audio buffers\n");
andrewm@81 397 return 1;
andrewm@81 398 }
andrewm@81 399
andrewm@81 400 // Allocate analog buffers
andrewm@81 401 if(analog_enabled) {
andrewm@81 402 context->analogIn = (float *)malloc(context->analogChannels * context->analogFrames * sizeof(float));
andrewm@81 403 context->analogOut = (float *)malloc(context->analogChannels * context->analogFrames * sizeof(float));
andrewm@81 404 last_analog_out_frame = (float *)malloc(context->analogChannels * sizeof(float));
andrewm@81 405
andrewm@81 406 if(context->analogIn == 0 || context->analogOut == 0 || last_analog_out_frame == 0) {
andrewm@81 407 rt_printf("Error: couldn't allocate analog buffers\n");
andrewm@81 408 return 1;
andrewm@81 409 }
andrewm@81 410
andrewm@81 411 memset(last_analog_out_frame, 0, context->analogChannels * sizeof(float));
andrewm@81 412 }
andrewm@81 413
andrewm@81 414 // Allocate digital buffers
andrewm@81 415 digital_buffer0 = pru_buffer_digital;
andrewm@81 416 digital_buffer1 = pru_buffer_digital + MEM_DIGITAL_BUFFER1_OFFSET / sizeof(uint32_t);
andrewm@81 417 if(digital_enabled) {
andrewm@81 418 last_digital_buffer = (uint32_t *)malloc(context->digitalFrames * sizeof(uint32_t)); //temp buffer to hold previous states
andrewm@81 419 if(last_digital_buffer == 0) {
andrewm@81 420 rt_printf("Error: couldn't allocate digital buffers\n");
andrewm@81 421 return 1;
andrewm@81 422 }
andrewm@81 423
andrewm@81 424 for(unsigned int n = 0; n < context->digitalFrames; n++){
andrewm@81 425 // Initialize lastDigitalFrames to all inputs
andrewm@81 426 last_digital_buffer[n] = 0x0000ffff;
andrewm@81 427 }
andrewm@81 428 }
andrewm@81 429
andrewm@81 430 context->digital = digital_buffer0;
andrewm@81 431
andrewm@0 432 return 0;
andrewm@0 433 }
andrewm@0 434
andrewm@0 435 // Run the code image in the specified file
giuliomoro@16 436 int PRU::start(char * const filename)
andrewm@0 437 {
andrewm@0 438 /* Clear any old interrupt */
andrewm@45 439 prussdrv_pru_clear_event(PRU_EVTOUT_0, PRU0_ARM_INTERRUPT);
andrewm@45 440
giuliomoro@16 441 /* Load and execute binary on PRU */
giuliomoro@16 442 if(filename[0] == '\0') { //if the string is empty, load the embedded code
giuliomoro@16 443 if(gRTAudioVerbose)
giuliomoro@16 444 rt_printf("Using embedded PRU code\n");
giuliomoro@16 445 if(prussdrv_exec_code(pru_number, PRUcode, sizeof(PRUcode))) {
giuliomoro@16 446 rt_printf("Failed to execute PRU code\n");
giuliomoro@16 447 return 1;
giuliomoro@16 448 }
giuliomoro@16 449 } else {
giuliomoro@16 450 if(gRTAudioVerbose)
giuliomoro@16 451 rt_printf("Using PRU code from %s\n",filename);
giuliomoro@16 452 if(prussdrv_exec_program(pru_number, filename)) {
giuliomoro@16 453 rt_printf("Failed to execute PRU code from %s\n", filename);
giuliomoro@16 454 return 1;
giuliomoro@16 455 }
giuliomoro@16 456 }
andrewm@0 457
andrewm@0 458 running = true;
andrewm@0 459 return 0;
andrewm@0 460 }
andrewm@0 461
andrewm@0 462 // Main loop to read and write data from/to PRU
andrewm@45 463 void PRU::loop(RT_INTR *pru_interrupt, void *userData)
andrewm@0 464 {
andrewm@50 465 #ifdef BEAGLERT_USE_XENOMAI_INTERRUPTS
andrewm@50 466 RTIME irqTimeout = PRU_SAMPLE_INTERVAL_NS * 1024; // Timeout for PRU interrupt: about 10ms, much longer than any expected period
andrewm@50 467 #else
andrewm@0 468 // Polling interval is 1/4 of the period
andrewm@50 469 RTIME sleepTime = PRU_SAMPLE_INTERVAL_NS * (context->analogChannels / 2) * context->analogFrames / 4;
andrewm@50 470 #endif
andrewm@45 471
andrewm@45 472 uint32_t pru_audio_offset, pru_spi_offset;
andrewm@0 473
andrewm@81 474 // Before starting, look at the last state of the analog and digital outputs which might
andrewm@81 475 // have been changed by the user during the setup() function. This lets us start with pin
andrewm@81 476 // directions and output values at something other than defaults.
andrewm@81 477
andrewm@81 478 if(analog_enabled) {
andrewm@81 479 if(context->flags & BEAGLERT_FLAG_ANALOG_OUTPUTS_PERSIST) {
andrewm@81 480 // Remember the content of the last_analog_out_frame
andrewm@81 481 for(unsigned int ch = 0; ch < context->analogChannels; ch++){
andrewm@81 482 last_analog_out_frame[ch] = context->analogOut[context->analogChannels * (context->analogFrames - 1) + ch];
andrewm@81 483 }
andrewm@81 484 }
andrewm@0 485 }
andrewm@45 486
andrewm@45 487 if(digital_enabled) {
andrewm@45 488 for(unsigned int n = 0; n < context->digitalFrames; n++){
andrewm@81 489 last_digital_buffer[n] = context->digital[n];
andrewm@45 490 }
giuliomoro@38 491 }
andrewm@45 492
andrewm@45 493 // TESTING
andrewm@50 494 // uint32_t testCount = 0;
andrewm@45 495 // RTIME startTime = rt_timer_read();
andrewm@45 496
andrewm@56 497 #ifdef BEAGLERT_USE_XENOMAI_INTERRUPTS
andrewm@56 498 int result;
andrewm@56 499 #else
andrewm@50 500 // Which buffer the PRU was last processing
andrewm@50 501 uint32_t lastPRUBuffer = 0;
andrewm@50 502 #endif
andrewm@50 503
andrewm@0 504 while(!gShouldStop) {
andrewm@50 505 #ifdef BEAGLERT_USE_XENOMAI_INTERRUPTS
andrewm@45 506 // Wait for PRU to move to change buffers;
andrewm@45 507 // PRU will send an interrupts which we wait for
andrewm@45 508 rt_intr_enable(pru_interrupt);
andrewm@45 509 while(!gShouldStop) {
andrewm@45 510 result = rt_intr_wait(pru_interrupt, irqTimeout);
andrewm@45 511 if(result >= 0)
andrewm@45 512 break;
andrewm@45 513 else if(result == -ETIMEDOUT)
andrewm@45 514 rt_printf("Warning: PRU timeout!\n");
andrewm@45 515 else {
andrewm@45 516 rt_printf("Error: wait for interrupt failed (%d)\n", result);
andrewm@45 517 gShouldStop = 1;
andrewm@45 518 }
andrewm@0 519 }
andrewm@45 520
andrewm@45 521 // Clear pending PRU interrupt
andrewm@45 522 prussdrv_pru_clear_event(PRU_EVTOUT_1, PRU1_ARM_INTERRUPT);
andrewm@50 523 #else
andrewm@50 524 // Poll
andrewm@50 525 while(pru_buffer_comm[PRU_CURRENT_BUFFER] == lastPRUBuffer && !gShouldStop) {
andrewm@50 526 rt_task_sleep(sleepTime);
andrewm@50 527 }
andrewm@50 528
andrewm@50 529 lastPRUBuffer = pru_buffer_comm[PRU_CURRENT_BUFFER];
andrewm@50 530 #endif
andrewm@45 531
andrewm@0 532 if(gShouldStop)
andrewm@0 533 break;
andrewm@0 534
andrewm@45 535 // Check which buffer we're on-- will have been set right
andrewm@45 536 // before the interrupt was asserted
andrewm@45 537 if(pru_buffer_comm[PRU_CURRENT_BUFFER] == 1) {
andrewm@45 538 // PRU is on buffer 1. We read and write to buffer 0
andrewm@45 539 pru_audio_offset = 0;
andrewm@45 540 pru_spi_offset = 0;
andrewm@45 541 if(digital_enabled)
andrewm@81 542 context->digital = digital_buffer0;
andrewm@45 543 }
andrewm@45 544 else {
andrewm@45 545 // PRU is on buffer 0. We read and write to buffer 1
andrewm@45 546 pru_audio_offset = context->audioFrames * 2;
andrewm@45 547 pru_spi_offset = context->analogFrames * context->analogChannels;
andrewm@45 548 if(digital_enabled)
andrewm@81 549 context->digital = digital_buffer1;
andrewm@45 550 }
andrewm@45 551
andrewm@45 552 // FIXME: some sort of margin is needed here to prevent the audio
andrewm@45 553 // code from completely eating the Linux system
andrewm@50 554 // testCount++;
andrewm@45 555 //rt_task_sleep(sleepTime*4);
andrewm@45 556 //rt_task_sleep(sleepTime/4);
andrewm@45 557
andrewm@0 558 if(xenomai_gpio != 0) {
andrewm@0 559 // Set the test pin high
andrewm@0 560 xenomai_gpio[GPIO_SETDATAOUT] = TEST_PIN_MASK;
andrewm@0 561 }
andrewm@0 562
andrewm@45 563 // Convert short (16-bit) samples to float
andrewm@45 564 // TODO: NEON
andrewm@45 565 for(unsigned int n = 0; n < 2 * context->audioFrames; n++)
giuliomoro@231 566 context->audioIn[n] = (float)pru_buffer_audio_adc[n + pru_audio_offset] / 32768.0f;
andrewm@0 567
andrewm@45 568 if(analog_enabled) {
andrewm@45 569 // TODO: NEON
andrewm@45 570 for(unsigned int n = 0; n < context->analogChannels * context->analogFrames; n++)
giuliomoro@231 571 context->analogIn[n] = (float)pru_buffer_spi_adc[n + pru_spi_offset] / 65536.0f;
andrewm@45 572
andrewm@45 573 if(context->flags & BEAGLERT_FLAG_ANALOG_OUTPUTS_PERSIST) {
andrewm@45 574 // Initialize the output buffer with the values that were in the last frame of the previous output
andrewm@45 575 for(unsigned int ch = 0; ch < context->analogChannels; ch++){
andrewm@45 576 for(unsigned int n = 0; n < context->analogFrames; n++){
andrewm@81 577 context->analogOut[n * context->analogChannels + ch] = last_analog_out_frame[ch];
andrewm@45 578 }
giuliomoro@23 579 }
giuliomoro@23 580 }
andrewm@45 581 else {
andrewm@45 582 // Outputs are 0 unless set otherwise
andrewm@45 583 memset(context->analogOut, 0, context->analogChannels * context->analogFrames * sizeof(float));
giuliomoro@23 584 }
andrewm@45 585 }
andrewm@45 586
andrewm@45 587 if(digital_enabled){
andrewm@45 588 // Use past digital values to initialize the array properly.
andrewm@45 589 // For each frame:
andrewm@45 590 // - pins previously set as outputs will keep the output value they had in the last frame of the previous buffer,
andrewm@45 591 // - pins previously set as inputs will carry the newly read input value
andrewm@45 592
andrewm@45 593 for(unsigned int n = 0; n < context->digitalFrames; n++){
andrewm@81 594 uint16_t inputs = last_digital_buffer[n] & 0xffff; // half-word, has 1 for inputs and 0 for outputs
andrewm@45 595
andrewm@45 596 uint16_t outputs = ~inputs; // half-word has 1 for outputs and 0 for inputs;
andrewm@81 597 context->digital[n] = (last_digital_buffer[context->digitalFrames - 1] & (outputs << 16)) | // keep output values set in the last frame of the previous buffer
andrewm@45 598 (context->digital[n] & (inputs << 16)) | // inputs from current context->digital[n];
andrewm@81 599 (last_digital_buffer[n] & (inputs)); // keep pin configuration from previous context->digital[n]
andrewm@45 600 // context->digital[n]=digitalBufferTemp[n]; //ignores inputs
andrewm@45 601 }
andrewm@45 602 }
andrewm@45 603
andrewm@45 604 // Call user render function
andrewm@45 605 // ***********************
andrewm@45 606 render(context, userData);
andrewm@45 607 // ***********************
andrewm@45 608
andrewm@45 609 if(analog_enabled) {
andrewm@45 610 if(context->flags & BEAGLERT_FLAG_ANALOG_OUTPUTS_PERSIST) {
andrewm@81 611 // Remember the content of the last_analog_out_frame
andrewm@45 612 for(unsigned int ch = 0; ch < context->analogChannels; ch++){
andrewm@81 613 last_analog_out_frame[ch] = context->analogOut[context->analogChannels * (context->analogFrames - 1) + ch];
andrewm@45 614 }
andrewm@45 615 }
andrewm@45 616
andrewm@45 617 // Convert float back to short for SPI output
andrewm@45 618 for(unsigned int n = 0; n < context->analogChannels * context->analogFrames; n++) {
giuliomoro@231 619 int out = context->analogOut[n] * 65536.0f;
giuliomoro@16 620 if(out < 0) out = 0;
giuliomoro@16 621 else if(out > 65535) out = 65535;
andrewm@45 622 pru_buffer_spi_dac[n + pru_spi_offset] = (uint16_t)out;
giuliomoro@16 623 }
giuliomoro@16 624 }
andrewm@45 625
andrewm@45 626 if(digital_enabled) { // keep track of past digital values
andrewm@45 627 for(unsigned int n = 0; n < context->digitalFrames; n++){
andrewm@81 628 last_digital_buffer[n] = context->digital[n];
andrewm@45 629 }
andrewm@45 630 }
andrewm@45 631
andrewm@45 632 // Convert float back to short for audio
andrewm@45 633 // TODO: NEON
andrewm@45 634 for(unsigned int n = 0; n < 2 * context->audioFrames; n++) {
giuliomoro@231 635 int out = context->audioOut[n] * 32768.0f;
andrewm@0 636 if(out < -32768) out = -32768;
andrewm@0 637 else if(out > 32767) out = 32767;
andrewm@45 638 pru_buffer_audio_dac[n + pru_audio_offset] = (int16_t)out;
andrewm@0 639 }
andrewm@0 640
andrewm@52 641 // Increment total number of samples that have elapsed
andrewm@52 642 context->audioSampleCount += context->audioFrames;
andrewm@52 643
andrewm@0 644 if(xenomai_gpio != 0) {
andrewm@0 645 // Set the test pin high
andrewm@0 646 xenomai_gpio[GPIO_CLEARDATAOUT] = TEST_PIN_MASK;
andrewm@0 647 }
andrewm@0 648
andrewm@45 649 // FIXME: TESTING!!
andrewm@50 650 // if(testCount > 100000)
andrewm@50 651 // break;
andrewm@45 652 }
andrewm@0 653
andrewm@50 654 #ifdef BEAGLERT_USE_XENOMAI_INTERRUPTS
andrewm@45 655 // Turn off the interrupt for the PRU if it isn't already off
andrewm@45 656 rt_intr_disable(pru_interrupt);
andrewm@50 657 #endif
andrewm@0 658
andrewm@45 659 // FIXME: TESTING
andrewm@45 660 // RTIME endTime = rt_timer_read();
andrewm@45 661 // RTIME diffTime = endTime - startTime;
andrewm@45 662 // rt_printf("%d blocks elapsed in %f seconds, %f Hz block rate\n", testCount, ((float)diffTime / 1.0e9), (float)testCount / ((float)diffTime / 1.0e9));
andrewm@0 663
andrewm@0 664 // Tell PRU to stop
andrewm@0 665 pru_buffer_comm[PRU_SHOULD_STOP] = 1;
andrewm@0 666
andrewm@45 667 // Wait two buffer lengths for the PRU to finish
andrewm@45 668 rt_task_sleep(PRU_SAMPLE_INTERVAL_NS * context->analogFrames * 4 * 2);
andrewm@45 669
andrewm@45 670 // Clean up after ourselves
andrewm@45 671 free(context->audioIn);
andrewm@45 672 free(context->audioOut);
andrewm@45 673
andrewm@45 674 if(analog_enabled) {
andrewm@45 675 free(context->analogIn);
andrewm@45 676 free(context->analogOut);
andrewm@81 677 free(last_analog_out_frame);
andrewm@45 678 }
andrewm@45 679
andrewm@45 680 if(digital_enabled) {
andrewm@81 681 free(last_digital_buffer);
andrewm@45 682 }
andrewm@45 683
andrewm@45 684 context->audioIn = context->audioOut = 0;
andrewm@45 685 context->analogIn = context->analogOut = 0;
andrewm@45 686 context->digital = 0;
andrewm@0 687 }
andrewm@0 688
andrewm@0 689 // Wait for an interrupt from the PRU indicate it is finished
andrewm@0 690 void PRU::waitForFinish()
andrewm@0 691 {
andrewm@0 692 if(!running)
andrewm@0 693 return;
andrewm@45 694 prussdrv_pru_wait_event (PRU_EVTOUT_0);
andrewm@45 695 prussdrv_pru_clear_event(PRU_EVTOUT_0, PRU0_ARM_INTERRUPT);
andrewm@0 696 }
andrewm@0 697
andrewm@0 698 // Turn off the PRU when done
andrewm@0 699 void PRU::disable()
andrewm@0 700 {
andrewm@0 701 /* Disable PRU and close memory mapping*/
andrewm@0 702 prussdrv_pru_disable(pru_number);
andrewm@0 703 prussdrv_exit();
andrewm@0 704 running = false;
andrewm@0 705 }
andrewm@0 706
andrewm@0 707 // Debugging
andrewm@0 708 void PRU::setGPIOTestPin()
andrewm@0 709 {
andrewm@0 710 if(!xenomai_gpio)
andrewm@0 711 return;
andrewm@0 712 xenomai_gpio[GPIO_SETDATAOUT] = TEST_PIN2_MASK;
andrewm@0 713 }
andrewm@0 714
andrewm@0 715 void PRU::clearGPIOTestPin()
andrewm@0 716 {
andrewm@0 717 if(!xenomai_gpio)
andrewm@0 718 return;
andrewm@0 719 xenomai_gpio[GPIO_CLEARDATAOUT] = TEST_PIN2_MASK;
andrewm@0 720 }