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Refactor sdcard_spi.c to use busDevice_t (again)

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This commit is contained in:
jflyper 2018-10-04 12:01:52 +09:00
parent a598d06fe5
commit 6307277d50
4 changed files with 62 additions and 51 deletions
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97
src/main/drivers/sdcard_spi.c
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@ -40,9 +40,6 @@
#define SDCARD_PROFILING
#endif
#define SET_CS_HIGH IOHi(sdcard.chipSelectPin)
#define SET_CS_LOW IOLo(sdcard.chipSelectPin)
#define SDCARD_INIT_NUM_DUMMY_BYTES 10
#define SDCARD_MAXIMUM_BYTE_DELAY_FOR_CMD_REPLY 8
// Chosen so that CMD8 will have the same CRC as CMD0:
@ -70,18 +67,18 @@ static bool sdcardSpi_isFunctional(void)
static void sdcard_select(void)
{
SET_CS_LOW;
IOLo(sdcard.busdev.busdev_u.spi.csnPin);
}
static void sdcard_deselect(void)
{
// As per the SD-card spec, give the card 8 dummy clocks so it can finish its operation
//spiTransferByte(sdcard.instance, 0xFF);
//spiBusTransferByte(&sdcard.busdev, 0xFF);
while (spiIsBusBusy(sdcard.instance)) {
while (spiBusIsBusBusy(&sdcard.busdev)) {
}
SET_CS_HIGH;
IOHi(sdcard.busdev.busdev_u.spi.csnPin);
}
/**
@ -98,7 +95,7 @@ static void sdcard_reset(void)
}
if (sdcard.state >= SDCARD_STATE_READY) {
spiSetDivisor(sdcard.instance, SDCARD_SPI_INITIALIZATION_CLOCK_DIVIDER);
spiSetDivisor(sdcard.busdev.busdev_u.spi.instance, SDCARD_SPI_INITIALIZATION_CLOCK_DIVIDER);
}
sdcard.failureCount++;
@ -118,7 +115,7 @@ static void sdcard_reset(void)
static bool sdcard_waitForIdle(int maxBytesToWait)
{
while (maxBytesToWait > 0) {
uint8_t b = spiTransferByte(sdcard.instance, 0xFF);
uint8_t b = spiBusTransferByte(&sdcard.busdev, 0xFF);
if (b == 0xFF) {
return true;
}
@ -136,7 +133,7 @@ static bool sdcard_waitForIdle(int maxBytesToWait)
static uint8_t sdcard_waitForNonIdleByte(int maxDelay)
{
for (int i = 0; i < maxDelay + 1; i++) { // + 1 so we can wait for maxDelay '0xFF' bytes before reading a response byte afterwards
uint8_t response = spiTransferByte(sdcard.instance, 0xFF);
uint8_t response = spiBusTransferByte(&sdcard.busdev, 0xFF);
if (response != 0xFF) {
return response;
@ -171,7 +168,7 @@ static uint8_t sdcard_sendCommand(uint8_t commandCode, uint32_t commandArgument)
if (!sdcard_waitForIdle(SDCARD_MAXIMUM_BYTE_DELAY_FOR_CMD_REPLY) && commandCode != SDCARD_COMMAND_GO_IDLE_STATE)
return 0xFF;
spiTransfer(sdcard.instance, command, NULL, sizeof(command));
spiBusRawTransfer(&sdcard.busdev, command, NULL, sizeof(command));
/*
* The card can take up to SDCARD_MAXIMUM_BYTE_DELAY_FOR_CMD_REPLY bytes to send the response, in the meantime
@ -207,7 +204,7 @@ static bool sdcard_validateInterfaceCondition(void)
// V1 cards don't support this command
sdcard.version = 1;
} else if (status == SDCARD_R1_STATUS_BIT_IDLE) {
spiTransfer(sdcard.instance, NULL, ifCondReply, sizeof(ifCondReply));
spiBusRawTransfer(&sdcard.busdev, NULL, ifCondReply, sizeof(ifCondReply));
/*
* We don't bother to validate the SDCard's operating voltage range since the spec requires it to accept our
@ -231,7 +228,7 @@ static bool sdcard_readOCRRegister(uint32_t *result)
uint8_t response[4];
spiTransfer(sdcard.instance, NULL, response, sizeof(response));
spiBusRawTransfer(&sdcard.busdev, NULL, response, sizeof(response));
if (status == 0) {
sdcard_deselect();
@ -269,11 +266,11 @@ static sdcardReceiveBlockStatus_e sdcard_receiveDataBlock(uint8_t *buffer, int c
return SDCARD_RECEIVE_ERROR;
}
spiTransfer(sdcard.instance, NULL, buffer, count);
spiBusRawTransfer(&sdcard.busdev, NULL, buffer, count);
// Discard trailing CRC, we don't care
spiTransferByte(sdcard.instance, 0xFF);
spiTransferByte(sdcard.instance, 0xFF);
spiBusTransferByte(&sdcard.busdev, 0xFF);
spiBusTransferByte(&sdcard.busdev, 0xFF);
return SDCARD_RECEIVE_SUCCESS;
}
@ -283,16 +280,16 @@ static bool sdcard_sendDataBlockFinish(void)
#ifdef USE_HAL_DRIVER
// Drain anything left in the Rx FIFO (we didn't read it during the write)
//This is necessary here as when using msc there is timing issue
while (LL_SPI_IsActiveFlag_RXNE(sdcard.instance)) {
sdcard.instance->DR;
while (LL_SPI_IsActiveFlag_RXNE(sdcard.busdev.busdev_u.spi.instance)) {
sdcard.busdev.busdev_u.spi.instance->DR;
}
#endif
// Send a dummy CRC
spiTransferByte(sdcard.instance, 0x00);
spiTransferByte(sdcard.instance, 0x00);
spiBusTransferByte(&sdcard.busdev, 0x00);
spiBusTransferByte(&sdcard.busdev, 0x00);
uint8_t dataResponseToken = spiTransferByte(sdcard.instance, 0xFF);
uint8_t dataResponseToken = spiBusTransferByte(&sdcard.busdev, 0xFF);
/*
* Check if the card accepted the write (no CRC error / no address error)
@ -315,9 +312,9 @@ static bool sdcard_sendDataBlockFinish(void)
static void sdcard_sendDataBlockBegin(const uint8_t *buffer, bool multiBlockWrite)
{
// Card wants 8 dummy clock cycles between the write command's response and a data block beginning:
spiTransferByte(sdcard.instance, 0xFF);
spiBusTransferByte(&sdcard.busdev, 0xFF);
spiTransferByte(sdcard.instance, multiBlockWrite ? SDCARD_MULTIPLE_BLOCK_WRITE_START_TOKEN : SDCARD_SINGLE_BLOCK_WRITE_START_TOKEN);
spiBusTransferByte(&sdcard.busdev, multiBlockWrite ? SDCARD_MULTIPLE_BLOCK_WRITE_START_TOKEN : SDCARD_SINGLE_BLOCK_WRITE_START_TOKEN);
if (sdcard.useDMAForTx) {
#if defined(USE_HAL_DRIVER)
@ -329,7 +326,7 @@ static void sdcard_sendDataBlockBegin(const uint8_t *buffer, bool multiBlockWrit
init.Mode = LL_DMA_MODE_NORMAL;
init.Direction = LL_DMA_DIRECTION_MEMORY_TO_PERIPH;
init.PeriphOrM2MSrcAddress = (uint32_t)&sdcard.instance->DR;
init.PeriphOrM2MSrcAddress = (uint32_t)&sdcard.busdev.busdev_u.spi.instance->DR;
init.Priority = LL_DMA_PRIORITY_LOW;
init.PeriphOrM2MSrcIncMode = LL_DMA_PERIPH_NOINCREMENT;
init.PeriphOrM2MSrcDataSize = LL_DMA_PDATAALIGN_BYTE;
@ -345,7 +342,7 @@ static void sdcard_sendDataBlockBegin(const uint8_t *buffer, bool multiBlockWrit
LL_DMA_EnableStream(sdcard.dma->dma, sdcard.dma->stream);
LL_SPI_EnableDMAReq_TX(sdcard.instance);
LL_SPI_EnableDMAReq_TX(sdcard.busdev.busdev_u.spi.instance);
#else
@ -361,7 +358,7 @@ static void sdcard_sendDataBlockBegin(const uint8_t *buffer, bool multiBlockWrit
init.DMA_MemoryBaseAddr = (uint32_t) buffer;
init.DMA_DIR = DMA_DIR_PeripheralDST;
#endif
init.DMA_PeripheralBaseAddr = (uint32_t) &sdcard.instance->DR;
init.DMA_PeripheralBaseAddr = (uint32_t) &sdcard.busdev.busdev_u.spi.instance->DR;
init.DMA_Priority = DMA_Priority_Low;
init.DMA_PeripheralInc = DMA_PeripheralInc_Disable;
init.DMA_PeripheralDataSize = DMA_PeripheralDataSize_Byte;
@ -377,11 +374,11 @@ static void sdcard_sendDataBlockBegin(const uint8_t *buffer, bool multiBlockWrit
DMA_Cmd(sdcard.dma->ref, ENABLE);
SPI_I2S_DMACmd(sdcard.instance, SPI_I2S_DMAReq_Tx, ENABLE);
SPI_I2S_DMACmd(sdcard.busdev.busdev_u.spi.instance, SPI_I2S_DMAReq_Tx, ENABLE);
#endif
} else {
// Send the first chunk now
spiTransfer(sdcard.instance, buffer, NULL, SDCARD_NON_DMA_CHUNK_SIZE);
spiBusRawTransfer(&sdcard.busdev, buffer, NULL, SDCARD_NON_DMA_CHUNK_SIZE);
}
}
@ -479,7 +476,7 @@ static void sdcardSpi_init(const sdcardConfig_t *config)
return;
}
sdcard.instance = spiInstanceByDevice(SPI_CFG_TO_DEV(config->device));
spiBusSetInstance(&sdcard.busdev, spiInstanceByDevice(SPI_CFG_TO_DEV(config->device)));
sdcard.useDMAForTx = config->useDma;
if (sdcard.useDMAForTx) {
@ -490,13 +487,15 @@ static void sdcardSpi_init(const sdcardConfig_t *config)
dmaInit(config->dmaIdentifier, OWNER_SDCARD, 0);
}
IO_t chipSelectIO;
if (config->chipSelectTag) {
sdcard.chipSelectPin = IOGetByTag(config->chipSelectTag);
IOInit(sdcard.chipSelectPin, OWNER_SDCARD_CS, 0);
IOConfigGPIO(sdcard.chipSelectPin, SPI_IO_CS_CFG);
chipSelectIO = IOGetByTag(config->chipSelectTag);
IOInit(chipSelectIO, OWNER_SDCARD_CS, 0);
IOConfigGPIO(chipSelectIO, SPI_IO_CS_CFG);
} else {
sdcard.chipSelectPin = IO_NONE;
chipSelectIO = IO_NONE;
}
sdcard.busdev.busdev_u.spi.csnPin = chipSelectIO;
if (config->cardDetectTag) {
sdcard.cardDetectPin = IOGetByTag(config->cardDetectTag);
@ -507,19 +506,19 @@ static void sdcardSpi_init(const sdcardConfig_t *config)
}
// Max frequency is initially 400kHz
spiSetDivisor(sdcard.instance, SDCARD_SPI_INITIALIZATION_CLOCK_DIVIDER);
spiSetDivisor(sdcard.busdev.busdev_u.spi.instance, SDCARD_SPI_INITIALIZATION_CLOCK_DIVIDER);
// SDCard wants 1ms minimum delay after power is applied to it
delay(1000);
// Transmit at least 74 dummy clock cycles with CS high so the SD card can start up
SET_CS_HIGH;
IOHi(sdcard.busdev.busdev_u.spi.csnPin);
spiTransfer(sdcard.instance, NULL, NULL, SDCARD_INIT_NUM_DUMMY_BYTES);
spiBusRawTransfer(&sdcard.busdev, NULL, NULL, SDCARD_INIT_NUM_DUMMY_BYTES);
// Wait for that transmission to finish before we enable the SDCard, so it receives the required number of cycles:
int time = 100000;
while (spiIsBusBusy(sdcard.instance)) {
while (spiBusIsBusBusy(&sdcard.busdev)) {
if (time-- == 0) {
sdcard.state = SDCARD_STATE_NOT_PRESENT;
sdcard.failureCount++;
@ -566,9 +565,9 @@ static sdcardOperationStatus_e sdcard_endWriteBlocks(void)
sdcard.multiWriteBlocksRemain = 0;
// 8 dummy clocks to guarantee N_WR clocks between the last card response and this token
spiTransferByte(sdcard.instance, 0xFF);
spiBusTransferByte(&sdcard.busdev, 0xFF);
spiTransferByte(sdcard.instance, SDCARD_MULTIPLE_BLOCK_WRITE_STOP_TOKEN);
spiBusTransferByte(&sdcard.busdev, SDCARD_MULTIPLE_BLOCK_WRITE_STOP_TOKEN);
// Card may choose to raise a busy (non-0xFF) signal after at most N_BR (1 byte) delay
if (sdcard_waitForNonIdleByte(1) == 0xFF) {
@ -672,7 +671,7 @@ static bool sdcardSpi_poll(void)
}
// Now we're done with init and we can switch to the full speed clock (<25MHz)
spiSetDivisor(sdcard.instance, SDCARD_SPI_FULL_SPEED_CLOCK_DIVIDER);
spiSetDivisor(sdcard.busdev.busdev_u.spi.instance, SDCARD_SPI_FULL_SPEED_CLOCK_DIVIDER);
sdcard.multiWriteBlocksRemain = 0;
@ -690,15 +689,15 @@ static bool sdcardSpi_poll(void)
DMA_CLEAR_FLAG(sdcard.dma, DMA_IT_TCIF);
DMA_CLEAR_FLAG(sdcard.dma, DMA_IT_HTIF);
// Drain anything left in the Rx FIFO (we didn't read it during the write)
while (LL_SPI_IsActiveFlag_RXNE(sdcard.instance)) {
sdcard.instance->DR;
while (LL_SPI_IsActiveFlag_RXNE(sdcard.busdev.busdev_u.spi.instance)) {
sdcard.busdev.busdev_u.spi.instance->DR;
}
// Wait for the final bit to be transmitted
while (spiIsBusBusy(sdcard.instance)) {
while (spiBusIsBusBusy(&sdcard.busdev)) {
}
LL_SPI_DisableDMAReq_TX(sdcard.instance);
LL_SPI_DisableDMAReq_TX(sdcard.busdev.busdev_u.spi.instance);
sendComplete = true;
}
@ -714,22 +713,22 @@ static bool sdcardSpi_poll(void)
DMA_Cmd(sdcard.dma->ref, DISABLE);
// Drain anything left in the Rx FIFO (we didn't read it during the write)
while (SPI_I2S_GetFlagStatus(sdcard.instance, SPI_I2S_FLAG_RXNE) == SET) {
sdcard.instance->DR;
while (SPI_I2S_GetFlagStatus(sdcard.busdev.busdev_u.spi.instance, SPI_I2S_FLAG_RXNE) == SET) {
sdcard.busdev.busdev_u.spi.instance->DR;
}
// Wait for the final bit to be transmitted
while (spiIsBusBusy(sdcard.instance)) {
while (spiBusIsBusBusy(&sdcard.busdev)) {
}
SPI_I2S_DMACmd(sdcard.instance, SPI_I2S_DMAReq_Tx, DISABLE);
SPI_I2S_DMACmd(sdcard.busdev.busdev_u.spi.instance, SPI_I2S_DMAReq_Tx, DISABLE);
sendComplete = true;
}
#endif
if (!sdcard.useDMAForTx) {
// Send another chunk
spiTransfer(sdcard.instance, sdcard.pendingOperation.buffer + SDCARD_NON_DMA_CHUNK_SIZE * sdcard.pendingOperation.chunkIndex, NULL, SDCARD_NON_DMA_CHUNK_SIZE);
spiBusRawTransfer(&sdcard.busdev, sdcard.pendingOperation.buffer + SDCARD_NON_DMA_CHUNK_SIZE * sdcard.pendingOperation.chunkIndex, NULL, SDCARD_NON_DMA_CHUNK_SIZE);
sdcard.pendingOperation.chunkIndex++;