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320 lines
8.6 KiB
320 lines
8.6 KiB
/*************************************************************************
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* This demo uses the BALibrary to provide enhanced control of
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* the TGA Pro board.
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*
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* The latest copy of the BALibrary can be obtained from
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* https://github.com/Blackaddr/BALibrary
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*
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* This demo will perform a DMA memory test on MEM1 attached
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* to SPI1.
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*
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* NOTE: SPI MEM1 can be used by a Teensy 3.5/3.6.
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* pins.
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*
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*/
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#include <Wire.h>
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#include "BALibrary.h"
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using namespace BALibrary;
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//#define SANITY
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#define DMA_SIZE 256
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#define SPI_WRITE_CMD 0x2
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#define SPI_READ_CMD 0x3
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#define SPI_ADDR_2_MASK 0xFF0000
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#define SPI_ADDR_2_SHIFT 16
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#define SPI_ADDR_1_MASK 0x00FF00
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#define SPI_ADDR_1_SHIFT 8
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#define SPI_ADDR_0_MASK 0x0000FF
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SPISettings memSettings(20000000, MSBFIRST, SPI_MODE0);
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const int cs0pin = SPI1_CS_PIN;
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BASpiMemoryDMA spiMem1(SpiDeviceId::SPI_DEVICE1);
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bool compareBuffers(uint8_t *a, uint8_t *b, size_t numBytes)
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{
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bool pass=true;
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int errorCount = 0;
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for (size_t i=0; i<numBytes; i++) {
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if (a[i] != b[i]) {
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if (errorCount < 10) {
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Serial.print(i); Serial.print(":: a:"); Serial.print(a[i]); Serial.print(" does not match b:"); Serial.println(b[i]);
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pass=false;
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errorCount++;
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} else { return false; }
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}
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}
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return pass;
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}
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bool compareBuffers16(uint16_t *a, uint16_t *b, size_t numWords)
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{
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return compareBuffers(reinterpret_cast<uint8_t *>(a), reinterpret_cast<uint8_t*>(b), sizeof(uint16_t)*numWords);
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}
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size_t SPI_MAX_ADDR = 0;
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void setup() {
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TGA_PRO_MKII_REV1(); // Declare the version of the TGA Pro you are using.
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//TGA_PRO_REVB(x);
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//TGA_PRO_REVA(x);
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Serial.begin(57600);
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while (!Serial) { yield(); }
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delay(5);
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SPI_MEM1_64M();
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SPI_MAX_ADDR = BAHardwareConfig.getSpiMemMaxAddr(MemSelect::MEM1);
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Serial.printf("Enabling SPI, testing MEM1, max address %08X\n\r", SPI_MAX_ADDR); Serial.flush();
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spiMem1.begin();
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}
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bool spi8BitTest(void) {
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size_t spiAddress = 0;
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int spiPhase = 0;
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constexpr uint8_t MASK80 = 0xaa;
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constexpr uint8_t MASK81 = 0x55;
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uint8_t src8[DMA_SIZE];
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uint8_t dest8[DMA_SIZE];
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// Write to the memory using 8-bit transfers
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Serial.println("\nStarting 8-bit test Write/Read"); Serial.flush();
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while (spiPhase < 4) {
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spiAddress = 0;
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while (spiAddress <= SPI_MAX_ADDR) {
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// fill the write data buffer
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switch (spiPhase) {
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case 0 :
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for (int i=0; i<DMA_SIZE; i++) {
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src8[i] = ( (spiAddress+i) & 0xff) ^ MASK80;
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}
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break;
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case 1 :
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for (int i=0; i<DMA_SIZE; i++) {
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src8[i] = ((spiAddress+i) & 0xff) ^ MASK81;
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}
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break;
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case 2 :
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for (int i=0; i<DMA_SIZE; i++) {
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src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK80);
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}
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break;
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case 3 :
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for (int i=0; i<DMA_SIZE; i++) {
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src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK81);
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}
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break;
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}
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// Send the DMA transfer
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spiMem1.write(spiAddress, src8, DMA_SIZE);
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// wait until write is done
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while (spiMem1.isWriteBusy()) {}
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spiAddress += DMA_SIZE;
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}
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// Read back the data using 8-bit transfers
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spiAddress = 0;
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while (spiAddress <= SPI_MAX_ADDR) {
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// generate the golden data
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switch (spiPhase) {
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case 0 :
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for (int i=0; i<DMA_SIZE; i++) {
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src8[i] = ( (spiAddress+i) & 0xff) ^ MASK80;
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}
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break;
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case 1 :
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for (int i=0; i<DMA_SIZE; i++) {
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src8[i] = ((spiAddress+i) & 0xff) ^ MASK81;
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}
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break;
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case 2 :
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for (int i=0; i<DMA_SIZE; i++) {
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src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK80);
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}
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break;
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case 3 :
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for (int i=0; i<DMA_SIZE; i++) {
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src8[i] = ((spiAddress+i) & 0xff) ^ (!MASK81);
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}
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break;
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}
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// Read back the DMA data
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spiMem1.read(spiAddress, dest8, DMA_SIZE);
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// wait until read is done
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while (spiMem1.isReadBusy()) {}
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if (!compareBuffers(src8, dest8, DMA_SIZE)) {
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Serial.println(String("ERROR @") + spiAddress);
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return false; } // stop the test
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spiAddress += DMA_SIZE;
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}
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Serial.println(String("Phase ") + spiPhase + String(": 8-bit Write/Read test passed!"));
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spiPhase++;
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}
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#ifdef SANITY
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for (int i=0; i<DMA_SIZE; i++) {
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Serial.print(src8[i], HEX); Serial.print("="); Serial.println(dest8[i],HEX);
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}
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#endif
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Serial.println("\nStarting 8-bit test Zero/Read"); Serial.flush();
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// Clear the memory
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spiAddress = 0;
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memset(src8, 0, DMA_SIZE);
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while (spiAddress <= SPI_MAX_ADDR) {
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// Send the DMA transfer
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spiMem1.zero(spiAddress, DMA_SIZE);
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// wait until write is done
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while (spiMem1.isWriteBusy()) {}
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spiAddress += DMA_SIZE;
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}
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// Check the memory is clear
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spiAddress = 0;
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while (spiAddress <= SPI_MAX_ADDR) {
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// Read back the DMA data
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spiMem1.read(spiAddress, dest8, DMA_SIZE);
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// wait until read is done
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while (spiMem1.isReadBusy()) {}
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if (!compareBuffers(src8, dest8, DMA_SIZE)) { return false; } // stop the test
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spiAddress += DMA_SIZE;
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}
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Serial.println(String(": 8-bit Zero/Read test passed!"));
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return true;
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}
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bool spi16BitTest(void) {
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size_t spiAddress = 0;
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int spiPhase = 0;
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constexpr uint16_t MASK160 = 0xaaaa;
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constexpr uint16_t MASK161 = 0x5555;
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constexpr int NUM_DATA = DMA_SIZE / sizeof(uint16_t);
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uint16_t src16[NUM_DATA];
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uint16_t dest16[NUM_DATA];
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// Write to the memory using 16-bit transfers
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Serial.println("\nStarting 16-bit test"); Serial.flush();
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while (spiPhase < 4) {
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spiAddress = 0;
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while (spiAddress <= SPI_MAX_ADDR) {
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// fill the write data buffer
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switch (spiPhase) {
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case 0 :
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for (int i=0; i<NUM_DATA; i++) {
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src16[i] = ( (spiAddress+i) & 0xffff) ^ MASK160;
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}
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break;
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case 1 :
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for (int i=0; i<NUM_DATA; i++) {
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src16[i] = ((spiAddress+i) & 0xffff) ^ MASK161;
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}
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break;
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case 2 :
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for (int i=0; i<NUM_DATA; i++) {
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src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK160);
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}
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break;
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case 3 :
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for (int i=0; i<NUM_DATA; i++) {
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src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK161);
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}
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break;
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}
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// Send the DMA transfer
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spiMem1.write16(spiAddress, src16, NUM_DATA);
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// wait until write is done
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while (spiMem1.isWriteBusy()) {}
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spiAddress += DMA_SIZE;
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}
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// Read back the data using 8-bit transfers
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spiAddress = 0;
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while (spiAddress <= SPI_MAX_ADDR) {
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// generate the golden data
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switch (spiPhase) {
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case 0 :
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for (int i=0; i<NUM_DATA; i++) {
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src16[i] = ( (spiAddress+i) & 0xffff) ^ MASK160;
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}
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break;
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case 1 :
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for (int i=0; i<NUM_DATA; i++) {
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src16[i] = ((spiAddress+i) & 0xffff) ^ MASK161;
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}
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break;
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case 2 :
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for (int i=0; i<NUM_DATA; i++) {
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src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK160);
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}
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break;
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case 3 :
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for (int i=0; i<NUM_DATA; i++) {
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src16[i] = ((spiAddress+i) & 0xffff) ^ (!MASK161);
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}
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break;
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}
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// Read back the DMA data
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spiMem1.read16(spiAddress, dest16, NUM_DATA);
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// wait until read is done
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while (spiMem1.isReadBusy()) {}
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if (!compareBuffers16(src16, dest16, NUM_DATA)) {
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Serial.print("ERROR @"); Serial.println(spiAddress, HEX);
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return false; } // stop the test
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spiAddress += DMA_SIZE;
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}
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Serial.println(String("Phase ") + spiPhase + String(": 16-bit test passed!"));
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spiPhase++;
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}
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#ifdef SANITY
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for (int i=0; i<NUM_DATA; i++) {
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Serial.print(src16[i], HEX); Serial.print("="); Serial.println(dest16[i],HEX);
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}
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#endif
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Serial.println("\nStarting 16-bit test Zero/Read"); Serial.flush();
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// Clear the memory
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spiAddress = 0;
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memset(src16, 0, DMA_SIZE);
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while (spiAddress <= SPI_MAX_ADDR) {
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// Send the DMA transfer
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spiMem1.zero16(spiAddress, NUM_DATA);
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// wait until write is done
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while (spiMem1.isWriteBusy()) {}
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spiAddress += DMA_SIZE;
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}
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// Check the memory is clear
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spiAddress = 0;
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while (spiAddress <= SPI_MAX_ADDR) {
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// Read back the DMA data
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spiMem1.read16(spiAddress, dest16, NUM_DATA);
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// wait until read is done
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while (spiMem1.isReadBusy()) {}
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if (!compareBuffers16(src16, dest16, NUM_DATA)) { return false; } // stop the test
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spiAddress += DMA_SIZE;
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}
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Serial.println(String(": 16-bit Zero/Read test passed!"));
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return true;
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}
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void loop() {
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spi8BitTest();
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spi16BitTest();
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Serial.println("\nTEST DONE!");
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while(true) {}
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}
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