2024-04-20 18:20:23 +00:00
8 changed files with 218 additions and 302 deletions
--- a/drv/dma.h
+++ b/drv/dma.h
@ -77,6 +77,13 @@ enum DmaIRQSource {
 typedef void (*DmaCallback)(enum DmaIRQSource, volatile void* param);
 struct DmaParam {
 	void* periph;
 	enum DmaConfig config;    //DMA config, must correspond to peripheral
 	enum DmaPeriph dma;       //DMA peripheral, must correspond to peripheral
 	enum DmaChannel channel;  //DMA channel, must correspond to peripheral
 };
 //--functions-------------------------------------------------------------------
--- a/drv/dma_mbuf.c
+++ b/drv/dma_mbuf.c
@ -1,143 +0,0 @@
 /** @file dma_mbuf.h
 * Module handling Direct Memory Access controller's multibuffer system
 *
 * The module provides a convenient tool to send data to a peripheral in a
 * buffered, low-altency, low-cpu usage, non-blocking way
 */
 //--includes--------------------------------------------------------------------
 #include "dma_mbuf.h"
 //--local definitions-----------------------------------------------------------
 #define DMA_CONFIG (DMA_CONFIG_IRQ_COMPLETE | DMA_CONFIG_FROM_MEM \
 					| DMA_CONFIG_INC_MEM | DMA_CONFIG_PSIZE_8BITS \
 					| DMA_CONFIG_MSIZE_8BITS)
 static void mbuf_callback(enum DmaIRQSource src, volatile void* param);
 //take last 2 bytes of a buffer and assemble them store the current byte index
 #define byte_index (((uint16_t**)buffer->buffers) \
 		[buffer->buffer_index][buffer->buffer_size/2])
 #define dma_byte_index (((uint16_t**)buffer->buffers) \
 		[buffer->dma_buffer_index][buffer->buffer_size/2])
 //--local variables-------------------------------------------------------------
 //--public functions------------------------------------------------------------
 void dma_mbuf_configure(volatile struct DmaMultiBuffer* buffer, void** buffers,
 		volatile void* dest, uint16_t buffer_size, uint8_t buffer_nb,
 		enum DmaPeriph dma, enum DmaChannel channel, enum DmaConfig priority)
 {
 	#warning "check for null ptr"
 	buffer->buffers = buffers;
 	buffer->dest = dest;
 	buffer->buffer_size = buffer_size - 2;
 	buffer->buffer_nb = buffer_nb;
 	buffer->free_buffer_nb = buffer_nb - 1;
 	buffer->buffer_index = 0;
 	buffer->dma_buffer_index = 0;
 	buffer->dma = dma;
 	buffer->channel = channel;
 	buffer->config = DMA_CONFIG | priority;
 	for (uint8_t i=0; i<buffer->buffer_nb; ++i) {
 		for (uint16_t j=0; j<buffer->buffer_size + 2; ++j) {
 			((uint8_t**)buffer->buffers)[i][j] = 0;
 		}
 	}
 }
 uint32_t dma_mbuf_write_byte(volatile struct DmaMultiBuffer* buffer,
 		uint8_t byte)
 {
 	dma_enter_critical(buffer->dma, buffer->channel);
 	//if the current buffer is full, we need to switch it with an empty one
 	volatile uint16_t index = byte_index;
 	if (byte_index >= buffer->buffer_size) {
 		//if all buffer full, give up
 		if (buffer->free_buffer_nb == 0) {
 			dma_exit_critical(buffer->dma, buffer->channel);
 			return 1;
 		}
 		++buffer->buffer_index;
 		if (buffer->buffer_index >= buffer->buffer_nb) {
 			buffer->buffer_index = 0;
 		}
 		--buffer->free_buffer_nb;
 		byte_index = 0;
 	}
 	//write the byte
 	uint8_t** buffers = (uint8_t**)buffer->buffers;
 	buffers[buffer->buffer_index][byte_index] = byte;
 	++byte_index;
 	++index;
 	dma_exit_critical(buffer->dma, buffer->channel);
 	return 0;
 }
 void dma_mbuf_refresh(volatile struct DmaMultiBuffer* buffer)
 {
 	//no more data to send, stop here
 	if (buffer->dma_buffer_index == buffer->buffer_index
 			&& byte_index == 0) {
 		return;
 	}
 	//else start a new transfer
 	dma_configure(buffer->dma, buffer->channel, buffer->config, buffer->dest,
 			buffer->buffers[buffer->dma_buffer_index],
 			dma_byte_index, mbuf_callback, buffer);
 	//if the newly transfering buffer was being written to, switch the current
 	//buffer. Since we just ended a transfer, the next buffer should be empty
 	if (buffer->dma_buffer_index == buffer->buffer_index)
 	{
 		++buffer->buffer_index;
 		if (buffer->buffer_index >= buffer->buffer_nb) {
 			buffer->buffer_index = 0;
 		}
 		--buffer->free_buffer_nb;
 		byte_index = 0;
 	}
 	return;
 }
 //--local functions-------------------------------------------------------------
 /**
 * Callback called on DMA TX tranfert's completion. Checks for any remaining
 * data to send. If any, starts a new transfer, else stop the DMA
 */
 static void mbuf_callback(enum DmaIRQSource src, volatile void* param)
 {
 	(void)src; //only transfer complete expected
 	volatile struct DmaMultiBuffer* buffer = param;
 	//increment DMA's buffer since the last once has already been sent
 	++buffer->dma_buffer_index;
 	if (buffer->dma_buffer_index >= buffer->buffer_nb) {
 		buffer->dma_buffer_index = 0;
 	}
 	++buffer->free_buffer_nb;
 	dma_mbuf_refresh(param);
 }
--- a/drv/usart.c
+++ b/drv/usart.c
@ -14,8 +14,6 @@
 #include "rcc.h"
 #include "dma.h"
 #include "dma_mbuf.h"
 #include "dma_cbuf.h"
 #include "stddef.h"
@ -27,6 +25,8 @@ static void configure_usart(volatile struct USART* regs,
 static void configure_baudrate(volatile struct USART* regs, uint32_t clock,
 		uint32_t baudrate);
 #define DMA_CONFIG (DMA_CONFIG_PSIZE_8BITS)
 //--local variables-------------------------------------------------------------
@ -34,12 +34,47 @@ static volatile struct USART* const usart1 = (struct USART*)USART1_BASE_ADDRESS;
 static volatile struct USART* const usart2 = (struct USART*)USART2_BASE_ADDRESS;
 static volatile struct USART* const usart3 = (struct USART*)USART3_BASE_ADDRESS;
-static volatile struct DmaCircBuffer usart1_rx_buffer;
+static const struct DmaParam usart1_rx_param = {
-static volatile struct DmaMultiBuffer usart1_tx_buffer;
+	(void*)&usart1->DR,
-static volatile struct DmaCircBuffer usart2_rx_buffer;
+	DMA_CONFIG,
-static volatile struct DmaMultiBuffer usart2_tx_buffer;
+	DMA_PERIPH_1,
-static volatile struct DmaCircBuffer usart3_rx_buffer;
+	DMA_CHANNEL_5,
-static volatile struct DmaMultiBuffer usart3_tx_buffer;
+};
 static const struct DmaParam usart2_rx_param = {
 	(void*)&usart2->DR,
 	DMA_CONFIG,
 	DMA_PERIPH_1,
 	DMA_CHANNEL_6,
 };
 static const struct DmaParam usart3_rx_param = {
 	(void*)&usart3->DR,
 	DMA_CONFIG,
 	DMA_PERIPH_1,
 	DMA_CHANNEL_3,
 };
 static const struct DmaParam usart1_tx_param = {
 	(void*)&usart1->DR,
 	DMA_CONFIG,
 	DMA_PERIPH_1,
 	DMA_CHANNEL_4,
 };
 static const struct DmaParam usart2_tx_param = {
 	(void*)&usart2->DR,
 	DMA_CONFIG,
 	DMA_PERIPH_1,
 	DMA_CHANNEL_7,
 };
 static const struct DmaParam usart3_tx_param = {
 	(void*)&usart3->DR,
 	DMA_CONFIG,
 	DMA_PERIPH_1,
 	DMA_CHANNEL_2,
 };
 //--public functions------------------------------------------------------------
@ -55,22 +90,16 @@ void usart_configure(enum UsartPeriph periph, enum UsartConfig config,
 			rcc_enable(RCC_AHB_NONE, RCC_APB1_NONE, RCC_APB2_USART);
 			configure_baudrate(usart1, clocks.apb2_freq, baudrate);
 			configure_usart(usart1, config);
 			usart1_tx_buffer.buffers = NULL;
 			usart1_rx_buffer.buffer = NULL;
 			break;
 		case USART_PERIPH_2:
 			rcc_enable(RCC_AHB_NONE, RCC_APB1_USART2, RCC_APB2_NONE);
 			configure_baudrate(usart2, clocks.apb1_freq, baudrate);
 			configure_usart(usart2, config);
 			usart2_tx_buffer.buffers = NULL;
 			usart2_rx_buffer.buffer = NULL;
 			break;
 		case USART_PERIPH_3:
 			rcc_enable(RCC_AHB_NONE, RCC_APB1_USART3, RCC_APB2_NONE);
 			configure_baudrate(usart3, clocks.apb1_freq, baudrate);
 			configure_usart(usart3, config);
 			usart3_tx_buffer.buffers = NULL;
 			usart3_rx_buffer.buffer = NULL;
 			break;
 		default:
 			break;
@ -80,134 +109,104 @@ void usart_configure(enum UsartPeriph periph, enum UsartConfig config,
 uint32_t usart_write_byte(enum UsartPeriph periph, uint8_t byte)
 {
 	volatile struct USART* regs;
 	volatile struct DmaMultiBuffer* buffer;
 	enum NvicIrq irq;
 	switch (periph) {
 		case USART_PERIPH_1:
 			regs = usart1;
 			buffer = &usart1_tx_buffer;
 			irq = NVIC_IRQ_USART1;
 			break;
 		case USART_PERIPH_2:
 			regs = usart2;
 			buffer = &usart2_tx_buffer;
 			irq = NVIC_IRQ_USART2;
 			break;
 		case USART_PERIPH_3:
 			regs = usart3;
 			buffer = &usart3_tx_buffer;
 			irq = NVIC_IRQ_USART3;
 			break;
 		default:
 			return 1;
 			break;
 	}
-	if (buffer->buffers) {
+	//only write data if the tx register it empty, give up otherwise
-		//if the tx register is empty, there is no need to go through the dma
+	if (regs->SR.TXE) {
-		if (regs->SR.TC) {
+		reg_write(regs->DR, USART_DR_DR, byte);
-			reg_write(regs->DR, USART_DR_DR, byte);
+		return 0;
 			//enable IRQ, disable DMA
 			reg_reset(regs->CR3, USART_CR3_DMAT);
 			reg_set(regs->CR1, USART_CR1_TXEIE);
 			nvic_enable(irq);
 			return 0;
 		} else {
 			return dma_mbuf_write_byte(buffer, byte);
 		}
 	} else {
-		//only write data if the tx register it empty, give up otherwise
+		return 1;
 		if (regs->SR.TXE) {
 			reg_write(regs->DR, USART_DR_DR, byte);
 			return 0;
 		} else {
 			return 1;
 		}
 	}
 }
 uint32_t usart_read_byte(enum UsartPeriph periph, uint8_t* byte)
 {
 	volatile struct USART* regs;
 	volatile struct DmaCircBuffer* buffer;
 	switch (periph) {
 		case USART_PERIPH_1:
 			regs = usart1;
 			buffer = &usart1_rx_buffer;
 			break;
 		case USART_PERIPH_2:
 			regs = usart2;
 			buffer = &usart2_rx_buffer;
 			break;
 		case USART_PERIPH_3:
 			regs = usart3;
 			buffer = &usart3_rx_buffer;
 			break;
 		default:
 			return 1;
 			break;
 	}
-	if (buffer->buffer) {
+	if (regs->SR.RXNE) {
-		return dma_cbuf_read_byte(buffer, byte);
+		*byte = regs->DR.DR;
 		return 0;
 	} else {
-		if (regs->SR.RXNE) {
+		return 1;
 			*byte = regs->DR.DR;
 			return 0;
 		} else {
 			return 1;
 		}
 	}
 }
-void usart_set_tx_buffer(enum UsartPeriph periph, uint8_t** buffers,
+const struct DmaParam* usart_configure_rx_dma(enum UsartPeriph periph)
 		uint16_t buffer_size, uint8_t buffer_nb, enum DmaConfig priority)
 {
-	switch (periph) {
+	const struct DmaParam* param;
 		case USART_PERIPH_1:
 			dma_mbuf_configure(&usart1_tx_buffer, (void**)buffers, &usart1->DR,
 					buffer_size, buffer_nb, DMA_PERIPH_1, DMA_CHANNEL_4,
 					priority);
 			break;
 		case USART_PERIPH_2:
 			dma_mbuf_configure(&usart2_tx_buffer, (void**)buffers, &usart2->DR,
 					buffer_size, buffer_nb, DMA_PERIPH_1, DMA_CHANNEL_7,
 					priority);
 			break;
 		case USART_PERIPH_3:
 			dma_mbuf_configure(&usart3_tx_buffer, (void**)buffers, &usart3->DR,
 					buffer_size, buffer_nb, DMA_PERIPH_1, DMA_CHANNEL_2,
 					priority);
 			break;
 	}
 }
 void usart_set_rx_buffer(enum UsartPeriph periph, uint8_t* buffer,
 		uint16_t size, enum DmaConfig priority)
 {
 	switch (periph) {
 		case USART_PERIPH_1:
-			dma_cbuf_configure(&usart1_rx_buffer, buffer, (void*)&usart1->DR,
+			param = &usart1_rx_param;
 					size, DMA_PERIPH_1, DMA_CHANNEL_5, priority);
 			reg_set(usart1->CR3, USART_CR3_DMAR);
 			break;
 		case USART_PERIPH_2:
-			dma_cbuf_configure(&usart2_rx_buffer, buffer, (void*)&usart2->DR,
+			param = &usart2_rx_param;
 					size, DMA_PERIPH_1, DMA_CHANNEL_6, priority);
 			reg_set(usart2->CR3, USART_CR3_DMAR);
 			break;
 		case USART_PERIPH_3:
-			dma_cbuf_configure(&usart3_rx_buffer, buffer, (void*)&usart3->DR,
+			param = &usart3_rx_param;
 					size, DMA_PERIPH_1, DMA_CHANNEL_3, priority);
 			reg_set(usart3->CR3, USART_CR3_DMAR);
 			break;
 		default:
 			return nullptr;
 	}
 	return param;
 }
 const struct DmaParam* usart_configure_tx_dma(enum UsartPeriph periph)
 {
 	const struct DmaParam* param;
 	switch (periph) {
 		case USART_PERIPH_1:
 			param = &usart1_tx_param;
 			break;
 		case USART_PERIPH_2:
 			param = &usart2_tx_param;
 			break;
 		case USART_PERIPH_3:
 			param = &usart3_tx_param;
 			break;
 		default:
 			return nullptr;
 	}
 	return param;
 }
 //--local functions-------------------------------------------------------------
 /**
@ -309,39 +308,3 @@ static void configure_baudrate(volatile struct USART* regs, uint32_t clock,
 	reg_write(regs->BRR, USART_BRR_DIV_Fraction, divider & 0xF);
 }
 //--ISRs------------------------------------------------------------------------
 void hdr_usart1(void)
 {
 	//disable the interrupt. It will be reenabled on a write if needed
 	nvic_clear_pending(NVIC_IRQ_USART1);
 	nvic_disable(NVIC_IRQ_USART1);
 	reg_reset(usart1->CR1, USART_CR1_TXEIE);
 	reg_set(usart1->CR3, USART_CR3_DMAT);
 	dma_mbuf_refresh(&usart1_tx_buffer);
 }
 void hdr_usart2(void)
 {
 	//disable the interrupt. It will be reenabled on a write if needed
 	nvic_clear_pending(NVIC_IRQ_USART2);
 	nvic_disable(NVIC_IRQ_USART2);
 	reg_reset(usart2->CR1, USART_CR1_TXEIE);
 	reg_set(usart2->CR3, USART_CR3_DMAT);
 	dma_mbuf_refresh(&usart2_tx_buffer);
 }
 void hdr_usart3(void)
 {
 	//disable the interrupt. It will be reenabled on a write if needed
 	nvic_clear_pending(NVIC_IRQ_USART3);
 	nvic_disable(NVIC_IRQ_USART3);
 	reg_reset(usart3->CR1, USART_CR1_TXEIE);
 	reg_set(usart3->CR3, USART_CR3_DMAT);
 	dma_mbuf_refresh(&usart3_tx_buffer);
 }
--- a/drv/usart.h
+++ b/drv/usart.h
@ -41,18 +41,13 @@ enum UsartConfig {
 void usart_configure(enum UsartPeriph periph, enum UsartConfig config,
 		uint32_t baudrate);
 void usart_reset(enum UsartPeriph periph);
 uint32_t usart_write_byte(enum UsartPeriph periph, uint8_t byte);
 uint32_t usart_read_byte(enum UsartPeriph periph, uint8_t* byte);
-void usart_set_tx_buffer(enum UsartPeriph periph, uint8_t** buffers,
+const struct DmaParam* usart_configure_rx_dma(enum UsartPeriph periph);
-		uint16_t buffer_size, uint8_t buffer_nb, enum DmaConfig priority);
+const struct DmaParam* usart_configure_tx_dma(enum UsartPeriph periph);
 void usart_set_rx_buffer(enum UsartPeriph periph, uint8_t* buffer,
 		uint16_t size, enum DmaConfig priority);
 #endif //_USART_H_
--- a/srv/dma_cbuf.c
+++ b/srv/dma_cbuf.c
@ -24,24 +24,23 @@ static void cbuf_callback(enum DmaIRQSource src, volatile void* param);
 //--public functions------------------------------------------------------------
 void dma_cbuf_configure(volatile struct DmaCircBuffer* buffer,
-		volatile void* raw_buffer, volatile void* src, uint16_t buffer_size,
+		const struct DmaParam* param, enum DmaConfig priority,
-		enum DmaPeriph dma, enum DmaChannel channel, enum DmaConfig priority)
+		volatile void* raw_buffer, uint16_t buffer_size)
 {
 	#warning "check for null ptr"
 	buffer->buffer = raw_buffer;
-	buffer->src = src;
+
 	buffer->param = param;
 	buffer->priority = priority;
 	buffer->size = buffer_size;
 	buffer->begin = 0;
 	buffer->dma = dma;
 	buffer->channel = channel;
 	buffer->config = DMA_CONFIG | priority;
 	buffer->dma_looped = false;
-	dma_configure(buffer->dma, buffer->channel, buffer->config, buffer->src,
+	dma_configure(buffer->param->dma, buffer->param->channel,
 			buffer->param->config, buffer->param->periph,
 			buffer->buffer, buffer->size, cbuf_callback, buffer);
 }
@ -50,7 +49,7 @@ uint32_t dma_cbuf_read_byte(volatile struct DmaCircBuffer* buffer,
 {
 	//retreive the current end of the buffer based on the DMA's progress
 	uint16_t end = buffer->size
-		- dma_get_remaining(buffer->dma, buffer->channel);
+		- dma_get_remaining(buffer->param->dma, buffer->param->channel);
 	//check for bytes to read and overflow
 	if ((end > buffer->begin) && buffer->dma_looped) {
--- a/srv/dma_cbuf.h
+++ b/srv/dma_cbuf.h
@ -10,7 +10,7 @@
 //--includes--------------------------------------------------------------------
-#include "dma.h"
+#include "../drv/dma.h"
 //--type definitions------------------------------------------------------------
@ -22,15 +22,13 @@
 */
 struct DmaCircBuffer {
 	volatile void* buffer;    //the buffer to use as a circular buffer
-	volatile void* src;       //source peripheral register
+
 	const struct DmaParam* param;
 	enum DmaConfig priority;    //DMA config, must correspond to peripheral
 	uint16_t size;            //the size of the buffer
 	uint16_t begin;           //pointer to the current begin of the buffer
 	enum DmaPeriph dma;       //DMA peripheral, must correspond to peripheral
 	enum DmaChannel channel;  //DMA channel, must correspond to peripheral
 	enum DmaConfig config;    //DMA config, must correspond to peripheral
 	bool dma_looped;          //whether the DMA looped or not (buffer overflow)
 };
@ -47,8 +45,8 @@ struct DmaCircBuffer {
 * will stay running until manually stopped
 */
 void dma_cbuf_configure(volatile struct DmaCircBuffer* buffer,
-		volatile void* raw_buffer, volatile void* src, uint16_t buffer_size,
+		const struct DmaParam* param, enum DmaConfig priority,
-		enum DmaPeriph dma, enum DmaChannel channel, enum DmaConfig priority);
+		volatile void* raw_buffer, uint16_t buffer_size);
 uint32_t dma_cbuf_read_byte(volatile struct DmaCircBuffer* buffer,
 		uint8_t* byte);
--- a/srv/dma_mbuf.c
+++ b/srv/dma_mbuf.c
@ -0,0 +1,99 @@
 /** @file dma_mbuf.h
 * Module handling Direct Memory Access controller's multibuffer system
 *
 * The module provides a convenient tool to send data to a peripheral in a
 * buffered, low-altency, low-cpu usage, non-blocking way
 */
 //--includes--------------------------------------------------------------------
 #include "dma_mbuf.h"
 //--local definitions-----------------------------------------------------------
 #define DMA_CONFIG (DMA_CONFIG_IRQ_COMPLETE | DMA_CONFIG_FROM_MEM \
 					| DMA_CONFIG_INC_MEM | DMA_CONFIG_PSIZE_8BITS \
 					| DMA_CONFIG_MSIZE_8BITS)
 static void mbuf_callback(enum DmaIRQSource src, volatile void* param);
 //--local variables-------------------------------------------------------------
 //--public functions------------------------------------------------------------
 void dma_mbuf_configure(volatile struct DmaMultiBuffer* buffer,
 		const struct DmaParam* param, enum DmaConfig priority,
 		void* raw_buffer, uint16_t buffer_size)
 {
 	#warning "check for null ptr"
 	buffer->raw_buffer = raw_buffer;
 	buffer->param = param;
 	buffer->priority = priority;
 	buffer->buffer_size = buffer_size / 2;
 	buffer->byte_index = 0;
 	buffer->buffer_index = 0;
 	buffer->dma_running = false;
 }
 uint32_t dma_mbuf_write_byte(volatile struct DmaMultiBuffer* buffer,
 		uint8_t byte)
 {
 	//if the current buffer is full, give up
 	if (buffer->byte_index >= buffer->buffer_size) {
 		return 1;
 	}
 	//write the byte
 	buffer->raw_buffer[buffer->buffer_index * buffer->buffer_size
 		+ buffer->byte_index] = byte;
 	++buffer->byte_index;
 	return 0;
 }
 void dma_mbuf_switch(volatile struct DmaMultiBuffer* buffer)
 {
 	//if transfer already in progress or no data to send, don't start the
 	//transfer
 	if (buffer->dma_running || buffer->byte_index == 0) {
 		return;
 	}
 	//start a new transfer
 	dma_configure(buffer->param->dma, buffer->param->channel,
 			DMA_CONFIG | buffer->param->config | buffer->priority,
 			buffer->param->periph,
 			&buffer->raw_buffer[buffer->buffer_index * buffer->buffer_size],
 			buffer->byte_index, mbuf_callback, buffer);
 	buffer->dma_running = true;
 	buffer->byte_index = 0;
 	++buffer->buffer_index;
 	if (buffer->buffer_index > 1) {
 		buffer->buffer_index = 0;
 	}
 	return;
 }
 //--local functions-------------------------------------------------------------
 /**
 * Callback called on DMA TX tranfert's completion. Checks for any remaining
 * data to send. If any, starts a new transfer, else stop the DMA
 */
 static void mbuf_callback(enum DmaIRQSource src, volatile void* param)
 {
 	(void)src; //only transfer complete expected
 	volatile struct DmaMultiBuffer* buffer = param;
 	buffer->dma_running = false;
 }
--- a/srv/dma_mbuf.h
+++ b/srv/dma_mbuf.h
@ -10,7 +10,7 @@
 //--includes--------------------------------------------------------------------
-#include "dma.h"
+#include "../drv/dma.h"
 //--type definitions------------------------------------------------------------
@ -21,19 +21,17 @@
 * sizes
 */
 struct DmaMultiBuffer {
-	void** buffers;           //list of buffers to write to
+	uint8_t* raw_buffer;
 	volatile void* dest;      //destination peripheral register
-	uint16_t buffer_size;     //size of a single buffer
+	const struct DmaParam* param;
 	enum DmaConfig priority;
-	uint8_t buffer_nb;        //total number of buffers
+	uint16_t buffer_size;
 	uint8_t free_buffer_nb;   //number of buffers not currently used
 	uint8_t buffer_index;     //index of the current buffer
 	uint8_t dma_buffer_index; //index of the DMA's current buffer
-	enum DmaPeriph dma;       //DMA peripheral, must correspond to peripheral
+	uint8_t byte_index;
-	enum DmaChannel channel;  //DMA channel, must correspond to peripheral
+	uint8_t buffer_index;
-	enum DmaConfig config;    //DMA config, must correspond to peripheral
+
 	bool dma_running;
 };
@ -51,9 +49,9 @@ struct DmaMultiBuffer {
 * filling up the buffer. Transfers will then automatically be started as long
 * as there are bytes in the buffer. See the usart module for an usage exemple
 */
-void dma_mbuf_configure(volatile struct DmaMultiBuffer* buffer, void** buffers,
+void dma_mbuf_configure(volatile struct DmaMultiBuffer* buffer,
-		volatile void* dest, uint16_t buffer_size, uint8_t buffer_nb,
+		const struct DmaParam* param, enum DmaConfig priority,
-        enum DmaPeriph dma, enum DmaChannel channel, enum DmaConfig priority);
+		void* raw_buffer, uint16_t buffer_size);
 /**
 * Write the given byte to the given buffer. Returns 0 if the write operation
@ -71,7 +69,7 @@ uint32_t dma_mbuf_write_byte(volatile struct DmaMultiBuffer* buffer,
 * transfer will be handled automatically until there are no bytes left in the
 * buffer
 */
-void dma_mbuf_refresh(volatile struct DmaMultiBuffer* buffer);
+void dma_mbuf_switch(volatile struct DmaMultiBuffer* buffer);
 #endif //_DMA_MBUF_H_