sdk-ameba-v4.0c_180328/component/common/mbed/targets/hal/rtl8711b/spi_api.c

/** mbed Microcontroller Library
  ******************************************************************************
  * @file    spi_api.c
  * @author 
  * @version V1.0.0
  * @date    2016-08-01
  * @brief   This file provides mbed API for SPI.
  ******************************************************************************
  * @attention
  *
  * This module is a confidential and proprietary property of RealTek and
  * possession or use of this module requires written permission of RealTek.
  *
  * Copyright(c) 2016, Realtek Semiconductor Corporation. All rights reserved.
  ****************************************************************************** 
  */
#include "objects.h"
#include "spi_api.h"
#include "spi_ex_api.h"
#include "PinNames.h"
#include "pinmap.h"

typedef struct {
	GDMA_InitTypeDef SSITxGdmaInitStruct;
	GDMA_InitTypeDef SSIRxGdmaInitStruct;
	IRQn_Type   IrqNum;
	SPI_TypeDef *spi_dev;

	void (*RxCompCallback)(void *Para);
	void *RxCompCbPara;
	void (*TxCompCallback)(void *Para);
	void *TxCompCbPara;
	void (*TxIdleCallback)(void *Para);
	void *TxIdleCbPara;
	
	void *RxData;
	void *TxData;
	u32  RxLength;
	u32  TxLength;

	u32   Index;
	u32   Role;

	/* mbed var */
	u32 dma_en;
}HAL_SSI_ADAPTOR, *PHAL_SSI_ADAPTOR;

HAL_SSI_ADAPTOR ssi_adapter_g[2];
SSI_InitTypeDef SSI_InitStruct[2];

void spi_flush_rx_fifo (spi_t *obj);

static void spi_tx_done_callback(VOID *spi_obj)
{
	spi_t *obj = (spi_t *)spi_obj;
	spi_irq_handler handler;

	if (obj->state & SPI_STATE_TX_BUSY) {
		obj->state &= ~SPI_STATE_TX_BUSY;
		if (obj->irq_handler) {
			handler = (spi_irq_handler)obj->irq_handler;
			handler(obj->irq_id, SpiTxIrq);
		}
	}
}

static void spi_rx_done_callback(VOID *spi_obj)
{
	spi_t *obj = (spi_t *)spi_obj;
	spi_irq_handler handler;

	obj->state &= ~SPI_STATE_RX_BUSY;
	if (obj->irq_handler) {
		handler = (spi_irq_handler)obj->irq_handler;
		handler(obj->irq_id, SpiRxIrq);
	}
}

// Bus Idle: Real TX done, TX FIFO empty and bus shift all data out already
void spi_bus_tx_done_callback(VOID *spi_obj)
{
	spi_t *obj = (spi_t *)spi_obj;
	spi_irq_handler handler;

	if (obj->bus_tx_done_handler) {
		handler = (spi_irq_handler)obj->bus_tx_done_handler;
		handler(obj->bus_tx_done_irq_id, 0);
	}
}

/**
  * @brief  Set SPI interrupt bus tx done handler if needed.
  * @param  obj: spi object define in application software.
  * @param  handler: interrupt bus tx done callback function
  * @param  id: interrupt callback parameter
  * @retval none  
  */
void spi_bus_tx_done_irq_hook(spi_t *obj, spi_irq_handler handler, uint32_t id) 
{
	obj->bus_tx_done_handler = (u32)handler;
	obj->bus_tx_done_irq_id = (u32)id;
}

static u32 ssi_interrupt(void *Adaptor)
{
	PHAL_SSI_ADAPTOR ssi_adapter = (PHAL_SSI_ADAPTOR) Adaptor;
	u32 InterruptStatus = SSI_GetIsr(ssi_adapter->spi_dev);
	u32 DataFrameSize = SSI_GetDataFrameSize(ssi_adapter->spi_dev);

	SSI_SetIsrClean(ssi_adapter->spi_dev, InterruptStatus);

	if (InterruptStatus & (BIT_ISR_TXOIS | BIT_ISR_RXUIS | BIT_ISR_RXOIS | BIT_ISR_MSTIS)) {
		DBG_PRINTF(MODULE_SPI, LEVEL_INFO, "[INT] Tx/Rx Warning %x \n", InterruptStatus);
	}

	if ((InterruptStatus & BIT_ISR_RXFIS) ) {
		u32 TransLen = 0;

		TransLen = SSI_ReceiveData(ssi_adapter->spi_dev, ssi_adapter->RxData, ssi_adapter->RxLength);
		ssi_adapter->RxLength -= TransLen;
		if (DataFrameSize > 8) {
			// 16~9 bits mode
			ssi_adapter->RxData = (void*)(((u16*)ssi_adapter->RxData) + TransLen);
		} else {
			// 8~4 bits mode
			ssi_adapter->RxData = (void*)(((u8*)ssi_adapter->RxData) + TransLen);
		}
		
		if (ssi_adapter->RxLength == 0) {
			SSI_INTConfig(ssi_adapter->spi_dev, (BIT_IMR_RXFIM | BIT_IMR_RXOIM | BIT_IMR_RXUIM), DISABLE);
			if (ssi_adapter->RxCompCallback != NULL) {
				ssi_adapter->RxCompCallback(ssi_adapter->RxCompCbPara);
			}
		}
	}

	if (InterruptStatus & BIT_ISR_TXEIS) {
		u32 TransLen = 0;
		volatile u32 bus_busy;
		u32 i;

		/* all data complete */
		if (ssi_adapter->TxLength == 0) {
			SSI_INTConfig(ssi_adapter->spi_dev, (BIT_IMR_TXOIM | BIT_IMR_TXEIM), DISABLE);
			for (i=0;i<1000000;i++) {
				bus_busy = SSI_Busy(ssi_adapter->spi_dev);
				if (!bus_busy) {
					break;  // break the for loop
				}
			}
			
			// If it's not a dummy TX for master read SPI, then call the TX_done callback
			if (ssi_adapter->TxData != NULL) {
				if (ssi_adapter->TxIdleCallback != NULL) {
					ssi_adapter->TxIdleCallback(ssi_adapter->TxIdleCbPara);
				}
			}

			return 0;
		}
		
		TransLen = SSI_SendData(ssi_adapter->spi_dev, ssi_adapter->TxData,
			ssi_adapter->TxLength, ssi_adapter->Role);

		ssi_adapter->TxLength -= TransLen;
		if (DataFrameSize > 8) {
			// 16~9 bits mode
			ssi_adapter->TxData = (void*)(((u16*)ssi_adapter->TxData) + TransLen);
		} else {
			// 8~4 bits mode
			ssi_adapter->TxData = (void*)(((u8*)ssi_adapter->TxData) + TransLen);
		}

		/* all data write into fifo */
		if (ssi_adapter->TxLength == 0) {
			SSI_INTConfig(ssi_adapter->spi_dev, (BIT_IMR_TXOIM), DISABLE);
			// If it's not a dummy TX for master read SPI, then call the TX_done callback
			if (ssi_adapter->TxData != NULL) {
				if (ssi_adapter->TxCompCallback != NULL) {
					ssi_adapter->TxCompCallback(ssi_adapter->TxCompCbPara);
				}
			}
		}
	}

	return 0;
}

static u32 ssi_int_read(void *Adapter, void *RxData, u32 Length)
{
	PHAL_SSI_ADAPTOR ssi_adapter = (PHAL_SSI_ADAPTOR) Adapter;
	u32 DataFrameSize = SSI_GetDataFrameSize(ssi_adapter->spi_dev);

	assert_param(Length != 0);

	/*  As a Slave mode, if the peer(Master) side is power off, the BUSY flag is always on */
	if (SSI_Busy(ssi_adapter->spi_dev)) {		
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "ssi_int_read: SSI is busy\n");
		return _FALSE;
	}

	if (DataFrameSize > 8) {
		/*  16~9 bits mode */
		ssi_adapter->RxLength = Length >> 1; // 2 bytes(16 bit) every transfer
	} else {
		/*  8~4 bits mode */
		ssi_adapter->RxLength = Length; // 1 byte(8 bit) every transfer
	}

	ssi_adapter->RxData = RxData;

	SSI_INTConfig(ssi_adapter->spi_dev, (BIT_IMR_RXFIM | BIT_IMR_RXOIM | BIT_IMR_RXUIM), ENABLE);

	return _TRUE;
}


static u32 ssi_int_write(void *Adapter, u8 *pTxData, u32 Length)
{
	PHAL_SSI_ADAPTOR ssi_adapter = (PHAL_SSI_ADAPTOR) Adapter;
	u32 DataFrameSize = SSI_GetDataFrameSize(ssi_adapter->spi_dev);

	assert_param(Length != 0);
	
	if (DataFrameSize > 8) {
		/*  16~9 bits mode */
		ssi_adapter->TxLength = Length >> 1; // 2 bytes(16 bit) every transfer
	} else {
		/*  8~4 bits mode */
		ssi_adapter->TxLength = Length; // 1 byte(8 bit) every transfer
	}

	ssi_adapter->TxData = (void*)pTxData;
	SSI_INTConfig(ssi_adapter->spi_dev, (BIT_IMR_TXOIM | BIT_IMR_TXEIM), ENABLE);

	return _TRUE;
}

/* GDMA IRQ Handler */
static void ssi_dma_tx_irq(void *Data)
{
	PHAL_SSI_ADAPTOR ssi_adapter = (PHAL_SSI_ADAPTOR) Data;
	PGDMA_InitTypeDef GDMA_InitStruct;

	GDMA_InitStruct = &ssi_adapter->SSITxGdmaInitStruct;

	/* Clear Pending ISR */
	GDMA_ClearINT(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);
	GDMA_Cmd(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum, DISABLE);

	/*  Call user TX complete callback */
	if (NULL != ssi_adapter->TxCompCallback) {
		ssi_adapter->TxCompCallback(ssi_adapter->TxCompCbPara);
	}

	SSI_SetDmaEnable(ssi_adapter->spi_dev, DISABLE, BIT_SHIFT_DMACR_TDMAE);

	GDMA_ChnlFree(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);

	ssi_adapter->dma_en &= ~SPI_DMA_TX_EN;
}

static void ssi_dma_rx_irq(void *Data)
{
	PHAL_SSI_ADAPTOR ssi_adapter = (PHAL_SSI_ADAPTOR) Data;
	PGDMA_InitTypeDef GDMA_InitStruct;

	GDMA_InitStruct = &ssi_adapter->SSIRxGdmaInitStruct;

	/* Clear Pending ISR */
	GDMA_ClearINT(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);
	GDMA_Cmd(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum, DISABLE);

	/* Set SSI DMA Disable */
	SSI_SetDmaEnable(ssi_adapter->spi_dev, DISABLE, BIT_SHIFT_DMACR_RDMAE);
	
	/*  Call user RX complete callback */
	if (NULL != ssi_adapter->RxCompCallback) {
		ssi_adapter->RxCompCallback(ssi_adapter->RxCompCbPara);
	}

	GDMA_ChnlFree(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);

	ssi_adapter->dma_en &= ~SPI_DMA_RX_EN;
}

static u32 ssi_dma_send(void *Adapter, u8 *pTxData, u32 Length)
{
	PHAL_SSI_ADAPTOR ssi_adapter = (PHAL_SSI_ADAPTOR) Adapter;
	u32 ret = _TRUE;

	assert_param(Length != 0);
	assert_param(pTxData != NULL);

	if (ssi_adapter->dma_en & SPI_DMA_TX_EN) {
		return _FALSE;
	}
	
	ssi_adapter->dma_en |= SPI_DMA_TX_EN;
	ssi_adapter->TxLength = Length;
	ssi_adapter->TxData = (void*)pTxData;
	
	SSI_SetDmaEnable(ssi_adapter->spi_dev, ENABLE, BIT_SHIFT_DMACR_TDMAE);

	ret = SSI_TXGDMA_Init(ssi_adapter->Index, &ssi_adapter->SSITxGdmaInitStruct,
		ssi_adapter, (IRQ_FUN) ssi_dma_tx_irq,
		pTxData, Length);

	NVIC_SetPriority(GDMA_IrqNum[0][ssi_adapter->SSITxGdmaInitStruct.GDMA_ChNum], 10);			
	
	return ret;
}

static u32 ssi_dma_recv(void *Adapter, u8  *pRxData, u32 Length)
{
	PHAL_SSI_ADAPTOR ssi_adapter = (PHAL_SSI_ADAPTOR) Adapter;
	u32 ret = _TRUE;

	assert_param(Length != 0);
	assert_param(pRxData != NULL);

	if (ssi_adapter->dma_en & SPI_DMA_RX_EN) {
		return _FALSE;
	}
	
	ssi_adapter->dma_en |= SPI_DMA_RX_EN;	
	ssi_adapter->RxLength = Length;
	ssi_adapter->RxData = (void*)pRxData;

	ret = SSI_RXGDMA_Init(ssi_adapter->Index, &ssi_adapter->SSIRxGdmaInitStruct,
		ssi_adapter, (IRQ_FUN) ssi_dma_rx_irq,
		pRxData, Length);

	NVIC_SetPriority(GDMA_IrqNum[0][ssi_adapter->SSIRxGdmaInitStruct.GDMA_ChNum], 11);	
	
	/* Set SSI DMA Enable */
	SSI_SetDmaEnable(ssi_adapter->spi_dev, ENABLE, BIT_SHIFT_DMACR_RDMAE);

	return ret;
}

static u32 spi_stop_recv(spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	PGDMA_InitTypeDef GDMA_InitStruct = &ssi_adapter->SSIRxGdmaInitStruct;	
	u32 DMAStopAddr = 0;
	u32 ReceivedCnt;
	u8 DmaMode = 0;

	SSI_INTConfig(ssi_adapter->spi_dev, (BIT_IMR_RXFIM | BIT_IMR_RXOIM | BIT_IMR_RXUIM), DISABLE);

	if (ssi_adapter->dma_en & SPI_DMA_RX_EN) {
		DmaMode=1;
		/* Set SSI DMA Disable */
		SSI_SetDmaEnable(ssi_adapter->spi_dev, DISABLE, BIT_SHIFT_DMACR_RDMAE);
		
		/* Clear Pending ISR */
		GDMA_ClearINT(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);
		GDMA_ChCleanAutoReload(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum, CLEAN_RELOAD_SRC_DST);
		GDMA_Cmd(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum, DISABLE);	
		DMAStopAddr = GDMA_GetDstAddr(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);
		GDMA_ChnlFree(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);

		ReceivedCnt = DMAStopAddr - (u32)(ssi_adapter->RxData);
		ssi_adapter->RxLength-= ReceivedCnt;
		ssi_adapter->RxData = (u8 *)(ssi_adapter->RxData) + ReceivedCnt;
	
		ssi_adapter->dma_en &= ~SPI_DMA_RX_EN;
	}

	if (ssi_adapter->RxLength > 0) {
		ReceivedCnt = SSI_ReceiveData(ssi_adapter->spi_dev, ssi_adapter->RxData, ssi_adapter->RxLength);
		if (DmaMode && (SSI_GetDataFrameSize(ssi_adapter->spi_dev) > 8))
			ReceivedCnt=ReceivedCnt*2;
		ssi_adapter->RxLength -= ReceivedCnt;
	}

	if (ssi_adapter->RxLength == 0) {
		spi_flush_rx_fifo(obj);
	}

	obj->state &= ~ SPI_STATE_RX_BUSY;
	
	return HAL_OK;
}

/**
  * @brief  Initializes the SPI device, include clock/function/interrupt/SPI registers.
  * @param  obj: spi object define in application software.
  * @param  mosi: MOSI PinName according to pinmux spec.
  * @param  miso: MISO PinName according to pinmux spec.
  * @param  sclk: SCLK PinName according to pinmux spec.
  * @param  ssel: CS PinName according to pinmux spec.
  * @retval none  
  * @note must set obj->spi_index to MBED_SPI0 or MBED_SPI1 before using spi_init
  */
void spi_init (spi_t *obj, PinName mosi, PinName miso, PinName sclk, PinName ssel)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];

	if ((obj->spi_idx != MBED_SPI0) && (obj->spi_idx != MBED_SPI1)) {
		DBG_PRINTF(MODULE_SPI, LEVEL_ERROR, "spi_init: you should set spi_idx MBED_SPI0 or MBED_SPI1");
		assert_param(0);
	}
	
	ssi_adapter->Index = spi_idx;
	obj->sclk = (u8)sclk;

	if (spi_idx == 1) {
		ssi_adapter->Role = SSI_MASTER;
		RCC_PeriphClockCmd(APBPeriph_SPI1, APBPeriph_SPI1_CLOCK, ENABLE);
		Pinmux_Config(mosi, PINMUX_FUNCTION_SPIM);
		Pinmux_Config(miso, PINMUX_FUNCTION_SPIM);
		Pinmux_Config(sclk, PINMUX_FUNCTION_SPIM);
		Pinmux_Config(ssel, PINMUX_FUNCTION_SPIM);
	} else {
		ssi_adapter->Role = SSI_SLAVE;
		RCC_PeriphClockCmd(APBPeriph_SPI0, APBPeriph_SPI0_CLOCK, ENABLE);
		Pinmux_Config(mosi, PINMUX_FUNCTION_SPIS);
		Pinmux_Config(miso, PINMUX_FUNCTION_SPIS);
		Pinmux_Config(sclk, PINMUX_FUNCTION_SPIS);
		Pinmux_Config(ssel, PINMUX_FUNCTION_SPIS);
	}

	//TODO: Implement default setting structure.
	SSI_StructInit(&SSI_InitStruct[spi_idx]);
	if (spi_idx == 1) {
		SSI_InitStruct[spi_idx].SPI_Role = SSI_MASTER;
	} else {
		PAD_PullCtrl(ssel, GPIO_PuPd_UP);
		PAD_PullCtrl(sclk, GPIO_PuPd_UP);
	}

	ssi_adapter->spi_dev = SPI_DEV_TABLE[ssi_adapter->Index].SPIx;
	ssi_adapter->IrqNum = SPI_DEV_TABLE[ssi_adapter->Index].IrqNum;
	InterruptRegister((IRQ_FUN)ssi_interrupt, ssi_adapter->IrqNum, (u32)ssi_adapter, 10);
	InterruptEn(ssi_adapter->IrqNum, 10);
		
	SSI_Init(ssi_adapter->spi_dev, &SSI_InitStruct[spi_idx]);

	ssi_adapter->TxCompCallback = spi_tx_done_callback;
	ssi_adapter->TxCompCbPara = (void*)obj;
	ssi_adapter->RxCompCallback = spi_rx_done_callback;
	ssi_adapter->RxCompCbPara = (void*)obj;
	ssi_adapter->TxIdleCallback = spi_bus_tx_done_callback;
	ssi_adapter->TxIdleCbPara = (void*)obj;
	obj->state = SPI_STATE_READY;

#ifdef CONFIG_GDMA_EN    
	ssi_adapter->dma_en = 0;
#endif
}

/**
  * @brief  Deinitializes the SPI device, include interrupt/DMA/DISABLE SPI.
  * @param  obj: spi object define in application software.
  * @retval none  
  */
void spi_free (spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];

	InterruptDis(ssi_adapter->IrqNum);
	InterruptUnRegister(ssi_adapter->IrqNum);

	SSI_INTConfig(ssi_adapter->spi_dev, (BIT_IMR_RXFIM | BIT_IMR_RXOIM | BIT_IMR_RXUIM), DISABLE);

	if (ssi_adapter->dma_en & SPI_DMA_RX_EN) {
		PGDMA_InitTypeDef GDMA_InitStruct = &ssi_adapter->SSIRxGdmaInitStruct;	
		
		/* Set SSI DMA Disable */
		SSI_SetDmaEnable(ssi_adapter->spi_dev, DISABLE, BIT_SHIFT_DMACR_RDMAE);
		
		/* Clear Pending ISR */
		GDMA_ClearINT(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);
		GDMA_ChCleanAutoReload(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum, CLEAN_RELOAD_SRC_DST);
		GDMA_Cmd(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum, DISABLE);
		GDMA_ChnlFree(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);
	}

	if (ssi_adapter->dma_en & SPI_DMA_TX_EN) {
		PGDMA_InitTypeDef GDMA_InitStruct = &ssi_adapter->SSITxGdmaInitStruct;	
		
		/* Set SSI DMA Disable */
		SSI_SetDmaEnable(ssi_adapter->spi_dev, DISABLE, BIT_SHIFT_DMACR_TDMAE);
		
		/* Clear Pending ISR */
		GDMA_ClearINT(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);
		GDMA_ChCleanAutoReload(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum, CLEAN_RELOAD_SRC_DST);
		GDMA_Cmd(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum, DISABLE);
		GDMA_ChnlFree(GDMA_InitStruct->GDMA_Index, GDMA_InitStruct->GDMA_ChNum);
	}
	
	obj->state = 0;
	
	SSI_Cmd(ssi_adapter->spi_dev, DISABLE);
}

/**
  * @brief  Set SPI format,include DFS/Phase/Polarity.
  * @param  obj: spi object define in application software.
  * @param  bits: data frame size, 4-16 supported.
  * @param  mode: this parameter can be one of the following values:
  *		@arg 0 : [Polarity,Phase]=[0,0]
  *		@arg 1 : [Polarity,Phase]=[0,1]
  *		@arg 2 : [Polarity,Phase]=[1,0]
  *		@arg 3 : [Polarity,Phase]=[1,1]
  * @param  slave: this parameter can be one of the following values:
  *		@arg 0 : indicates role-master 
  *		@arg 1 : indicates role-slave
  * @retval none  
  */
void spi_format (spi_t *obj, int bits, int mode, int slave)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	u32   SclkPhase;
	u32   SclkPolarity;
	u32 DataFrameSize = (bits - 1);

	/*
	* mode | POL PHA
	* -----+--------
	*   0  |  0   0
	*   1  |  0   1
	*   2  |  1   0
	*   3  |  1   1
	*
	* SCPOL_INACTIVE_IS_LOW  = 0,
	* SCPOL_INACTIVE_IS_HIGH = 1
	*
	* SCPH_TOGGLES_IN_MIDDLE = 0,
	* SCPH_TOGGLES_AT_START  = 1
	*/
	switch (mode)
	{
	case 0:
		SclkPolarity = SCPOL_INACTIVE_IS_LOW;
		SclkPhase    = SCPH_TOGGLES_IN_MIDDLE;
	break;
	case 1:
		SclkPolarity = SCPOL_INACTIVE_IS_LOW;
		SclkPhase    = SCPH_TOGGLES_AT_START;
	break;
	case 2:
		SclkPolarity = SCPOL_INACTIVE_IS_HIGH;
		SclkPhase    = SCPH_TOGGLES_IN_MIDDLE;
	break;
	case 3:
		SclkPolarity = SCPOL_INACTIVE_IS_HIGH;
		SclkPhase    = SCPH_TOGGLES_AT_START;
	break;
	default:  // same as 3
		SclkPolarity = SCPOL_INACTIVE_IS_HIGH;
		SclkPhase    = SCPH_TOGGLES_AT_START;
	break;
	}

	if (slave == 1) {
		if (spi_idx == 0) {
			ssi_adapter->Role = SSI_SLAVE;
		} else {
			assert_param(0);
		}
	} else {
		if (spi_idx == 1) {
			ssi_adapter->Role = SSI_MASTER;
		} else {
			assert_param(0);
		}
	}

	SSI_SetSclkPhase(ssi_adapter->spi_dev, SclkPhase);
	SSI_SetSclkPolarity(ssi_adapter->spi_dev, SclkPolarity);
	SSI_SetDataFrameSize(ssi_adapter->spi_dev, DataFrameSize);

	if (slave == 1) {
		if (SclkPolarity == SCPOL_INACTIVE_IS_LOW) {
			PAD_PullCtrl((u32)obj->sclk, GPIO_PuPd_DOWN);
		}
		else {
			PAD_PullCtrl((u32)obj->sclk, GPIO_PuPd_UP);
		}
	}
}

/**
  * @brief  Set SPI baudrate.
  * @param  obj: spi master object define in application software.
  * @param hz: baudrate for SPI bus
  * @retval none  
  * @note "hz" should be less or equal to half of the SPI IpClk
  */
void spi_frequency (spi_t *obj, int hz)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	
	SSI_SetBaud(ssi_adapter->spi_dev, (u32)hz, CPU_ClkGet(_FALSE)/2);
}

void spi_slave_select(spi_t *obj, ChipSelect slaveindex)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	
	if((ssi_adapter->Role == SSI_MASTER) && (spi_idx == 1)){
		SSI_SetSlaveEnable(ssi_adapter->spi_dev,slaveindex);
	} else {
		assert_param(0);
	}
}

static inline void ssi_write (spi_t *obj, int value)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];

	while (!SSI_Writeable(ssi_adapter->spi_dev));
		SSI_WriteData(ssi_adapter->spi_dev, value);
}

static inline int ssi_read(spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];

	while (!SSI_Readable(ssi_adapter->spi_dev));
		return (int)SSI_ReadData(ssi_adapter->spi_dev);
}

/**
  * @brief  Master send one frame use SPI.
  * @param  obj: spi master object define in application software.
  * @param  value: the data to transmit.
  * @retval : data received from slave
  */
int spi_master_write (spi_t *obj, int value)
{
	ssi_write(obj, value);
	return ssi_read(obj);
}

/**
  * @brief  Get slave readable && busy state.
  * @param  obj: spi slave object define in application software.
  * @retval : slave Readable && Busy State
  */
int spi_slave_receive (spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int Readable;
	int Busy;

	Readable = SSI_Readable(ssi_adapter->spi_dev);
	Busy     = (int)SSI_Busy(ssi_adapter->spi_dev);
	return ((Readable && !Busy) ? 1 : 0);
}

/**
  * @brief  Slave receive one frame use SPI.
  * @param  obj: spi slave object define in application software.
  * @retval : data received from master
  */
int spi_slave_read (spi_t *obj)
{
	return ssi_read(obj);
}

/**
  * @brief  Slave send one frame use SPI.
  * @param  obj: spi slave object define in application software.
  * @param  value: the data to transmit.
  * @retval none
  */
void spi_slave_write (spi_t *obj, int value)
{
	ssi_write(obj, value);
}

/**
  * @brief  Get SPI busy state.
  * @param  obj: spi object define in application software.
  * @retval : current busy state
  */
int spi_busy (spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];

	return (int)SSI_Busy(ssi_adapter->spi_dev);
}

/**
  * @brief  SPI device to flush rx fifo.
  * @param  obj: spi  object define in application software.
  * @retval  none
  */
void spi_flush_rx_fifo (spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	u32 rx_fifo_level;
	u32 i;

	while(SSI_Readable(ssi_adapter->spi_dev)){
		rx_fifo_level = SSI_GetRxCount(ssi_adapter->spi_dev);
		for(i=0;i<rx_fifo_level;i++) {
			SSI_ReadData(ssi_adapter->spi_dev);
		}
	}
}

/**
  * @brief  slave recv target length data use interrupt mode.
  * @param  obj: spi slave object define in application software.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be read.
  * @retval  : stream init status
  */
int32_t spi_slave_read_stream(spi_t *obj, char *rx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & SPI_STATE_RX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spis int rx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	//DBG_PRINTF(MODULE_SPI, LEVEL_INFO, "rx_buffer addr: %X, length: %d\n", rx_buffer, length);
	obj->state |= SPI_STATE_RX_BUSY;
	if ((ret = ssi_int_read(ssi_adapter, rx_buffer, length)) != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
	}

	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  slave send target length data use interrupt mode.
  * @param  obj: spi slave object define in application software.
  * @param  tx_buffer: buffer to be written to Tx FIFO.
  * @param  length: number of data bytes to be send.
  * @retval  : stream init status
  */
int32_t spi_slave_write_stream(spi_t *obj, char *tx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & SPI_STATE_TX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spis int tx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	obj->state |= SPI_STATE_TX_BUSY;
	if ((ret=ssi_int_write(ssi_adapter, (u8 *) tx_buffer, length)) != _TRUE) {
		obj->state &= ~SPI_STATE_TX_BUSY;
	}
	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  master recv target length data use interrupt mode.
  * @param  obj: spi master object define in application software.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be read.
  * @retval  : stream init status
  */
int32_t spi_master_read_stream(spi_t *obj, char *rx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];

	int32_t ret;

	if (obj->state & SPI_STATE_RX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spim int rx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	// wait bus idle
	while(SSI_Busy(ssi_adapter->spi_dev));

	obj->state |= SPI_STATE_RX_BUSY;
	if ((ret = ssi_int_read(ssi_adapter, rx_buffer, length)) == _TRUE) {
		/* as Master mode, it need to push data to TX FIFO to generate clock out
		then the slave can transmit data out */
		// send some dummy data out
		if ((ret=ssi_int_write(ssi_adapter, NULL, length)) != _TRUE) {
			obj->state &= ~SPI_STATE_RX_BUSY;
		}
	}
	else {
		obj->state &= ~SPI_STATE_RX_BUSY;
	}

	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  master send target length data use interrupt mode.
  * @param  obj: spi master object define in application software.
  * @param  tx_buffer: buffer to be written to Tx FIFO.
  * @param  length: number of data bytes to be send.
  * @retval  : stream init status
  */
int32_t spi_master_write_stream(spi_t *obj, char *tx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & SPI_STATE_TX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spim int tx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	obj->state |= SPI_STATE_TX_BUSY;
	/* as Master mode, sending data will receive data at sametime, so we need to
	drop those received dummy data */
	if ((ret=ssi_int_write(ssi_adapter, (u8 *) tx_buffer, length)) != _TRUE) {
		obj->state &= ~SPI_STATE_TX_BUSY;
	}
	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  master send & recv target length data use interrupt mode.
  * @param  obj: spi master object define in application software.
  * @param  tx_buffer: buffer to be written to Tx FIFO.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be send & recv.
  * @retval  : stream init status
  */
int32_t spi_master_write_read_stream(spi_t *obj, char *tx_buffer,
        char *rx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & (SPI_STATE_RX_BUSY|SPI_STATE_TX_BUSY)) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spim int trx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	// wait bus idle
	while(SSI_Busy(ssi_adapter->spi_dev));

	obj->state |= SPI_STATE_RX_BUSY;
	/* as Master mode, sending data will receive data at sametime */
	if ((ret = ssi_int_read(ssi_adapter, rx_buffer, length)) == _TRUE) {
		obj->state |= SPI_STATE_TX_BUSY;
		if ((ret=ssi_int_write(ssi_adapter, (u8 *) tx_buffer, length)) != _TRUE) {
			obj->state &= ~(SPI_STATE_RX_BUSY|SPI_STATE_TX_BUSY);
			// Disable RX IRQ
			SSI_INTConfig(ssi_adapter->spi_dev, (BIT_IMR_RXFIM | BIT_IMR_RXOIM | BIT_IMR_RXUIM), DISABLE);
		}
	}
	else {
		obj->state &= ~(SPI_STATE_RX_BUSY);
	}

	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  Set SPI interrupt handler if needed.
  * @param  obj: spi object define in application software.
  * @param  handler: interrupt callback function
  * @param  id: interrupt callback parameter
  * @retval none  
  */
void spi_irq_hook(spi_t *obj, spi_irq_handler handler, uint32_t id)
{
	obj->irq_handler = (u32)handler;
	obj->irq_id = (u32)id;
}

/**
  * @brief  slave recv target length data use DMA mode.
  * @param  obj: spi slave object define in application software.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be read.
  * @retval  : stream init status
  */
int32_t spi_slave_read_stream_dma(spi_t *obj, char *rx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & SPI_STATE_RX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spim dma rx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	obj->state |= SPI_STATE_RX_BUSY;
	ret = ssi_dma_recv(ssi_adapter, (u8 *) rx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
	}
	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  slave send target length data use DMA mode.
  * @param  obj: spi slave object define in application software.
  * @param  tx_buffer: buffer to be written to Tx FIFO.
  * @param  length: number of data bytes to be send.
  * @retval  : stream init status
  */
int32_t spi_slave_write_stream_dma(spi_t *obj, char *tx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & SPI_STATE_TX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spis dma tx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	obj->state |= SPI_STATE_TX_BUSY;
	ret = ssi_dma_send(ssi_adapter, (u8 *) tx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_TX_BUSY;
	}
	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

#define USE_DMA_WRITE_MASTER_READ	1
/**
  * @brief  master recv target length data use DMA mode.
  * @param  obj: spi master object define in application software.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be read.
  * @retval  : stream init status
  * @note : DMA or Interrupt mode can be used to TX dummy data
  */
int32_t spi_master_read_stream_dma(spi_t *obj, char *rx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & SPI_STATE_RX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spim dma rx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	obj->state |= SPI_STATE_RX_BUSY;
	ret = ssi_dma_recv(ssi_adapter, (u8 *) rx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
	}

    // for master mode, we need to send data to generate clock out
#ifdef USE_DMA_WRITE_MASTER_READ
    // TX DMA is on already, so use DMA to TX data
    // Make the GDMA to use the rx_buffer too

	ret = ssi_dma_send(ssi_adapter, (u8 *) rx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
	}
#else
	// TX DMA isn't enabled, so we just use Interrupt mode to TX dummy data
	if ((ret=ssi_int_write(ssi_adapter, NULL, length)) != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
	}
#endif
	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  master send target length data use DMA mode.
  * @param  obj: spi master object define in application software.
  * @param  tx_buffer: buffer to be written to Tx FIFO.
  * @param  length: number of data bytes to be send.
  * @retval  : stream init status
  */
int32_t spi_master_write_stream_dma(spi_t *obj, char *tx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & SPI_STATE_TX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spim dma tx: state(0x%x) is not ready\r\n",
			obj->state);
		return HAL_BUSY;
	}

	obj->state |= SPI_STATE_TX_BUSY;
	ret = ssi_dma_send(ssi_adapter, (u8 *) tx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_TX_BUSY;
	}

	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  master send & recv target length data use DMA mode.
  * @param  obj: spi master object define in application software.
  * @param  tx_buffer: buffer to be written to Tx FIFO.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be send & recv.
  * @retval  : stream init status
  */
int32_t spi_master_write_read_stream_dma(spi_t *obj, char *tx_buffer, 
	char *rx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int32_t ret;

	if (obj->state & (SPI_STATE_RX_BUSY|SPI_STATE_TX_BUSY)) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spi_master_write_and_read_stream: state(0x%x) is not ready\r\n", obj->state);
		return HAL_BUSY;
	}

	obj->state |= SPI_STATE_RX_BUSY;
	ret = ssi_dma_recv(ssi_adapter, (u8 *) rx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
		return HAL_BUSY;
	}
	
	obj->state |= SPI_STATE_TX_BUSY;
	ret = ssi_dma_send(ssi_adapter, (u8 *) tx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_TX_BUSY;
		return HAL_BUSY;
	}

	return (ret == _TRUE) ? HAL_OK : HAL_BUSY;
}

/**
  * @brief  slave recv target length data use DMA mode and timeout mechanism.
  * @param  obj: spi slave object define in application software.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be read.
  * @param  timeout_ms: timeout waiting time.
  * @retval  : number of bytes read already
  */
int32_t spi_slave_read_stream_dma_timeout(spi_t *obj, char *rx_buffer, uint32_t length, uint32_t timeout_ms)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	int ret, timeout = 0;
	uint32_t StartCount = 0;

	assert_param(timeout_ms > 0);
	
	if (obj->state & SPI_STATE_RX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spi_slave_read_stream_dma: state(0x%x) is not ready\r\n", obj->state);
		return -HAL_BUSY;
	}

	obj->state |= SPI_STATE_RX_BUSY;
	ret = ssi_dma_recv(ssi_adapter, (u8 *) rx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
		return -HAL_BUSY;
	}

	StartCount = SYSTIMER_TickGet();

	while (1) {
		/* complete */
		if ((obj->state & SPI_STATE_RX_BUSY) == 0) {
			break;
		}

		/* time out */
		if (SYSTIMER_GetPassTime(StartCount) > timeout_ms) {
			ret = spi_stop_recv(obj);
			obj->state &= ~ SPI_STATE_RX_BUSY;
			timeout = 1;

			DBG_PRINTF(MODULE_SPI, LEVEL_INFO, "Slave is timeout\n");
			break;
		}
	}
			
	//if (SSI_GetDataFrameSize(SPIx) > 8){
	//	ssi_adapter->RxLength <<= 1;
	//}

	if(timeout)
		return (length - ssi_adapter->RxLength);
	else
		return length;
}

/**
  * @brief  slave recv target length data use DMA mode and stop if the spi bus is idle.
  * @param  obj: spi slave object define in application software.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be read.
  * @retval  : number of bytes read already
  */
int32_t spi_slave_read_stream_dma_terminate(spi_t *obj, char *rx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	SPI_TypeDef *SPIx = SPI_DEV_TABLE[spi_idx].SPIx;
	int ret;

	if (obj->state & SPI_STATE_RX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spi_slave_read_stream_dma: state(0x%x) is not ready\r\n", obj->state);
		return -HAL_BUSY;
	}

	obj->state |= SPI_STATE_RX_BUSY;
	ret = ssi_dma_recv(ssi_adapter, (u8 *) rx_buffer, length);
	if (ret != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
		return -HAL_BUSY;
	}

	while(obj->state & SPI_STATE_RX_BUSY){
		if(SSI_Busy(SPIx) == 0){
			ret = spi_stop_recv(obj); 
			goto EndOfDMACS;
		}
	}
	
EndOfDMACS:
	if((obj->state & SPI_STATE_RX_BUSY) != 0){ 
		obj->state &= ~ SPI_STATE_RX_BUSY;
	}

	//if (SSI_GetDataFrameSize(SPIx) > 8) {
	//	ssi_adapter->RxLength <<= 1;
	//}    
	
	return (length - ssi_adapter->RxLength);
}

/**
  * @brief  Slave device to flush tx fifo.
  * @param  obj: spi slave object define in application software.
  * @note : It will discard all data in both tx fifo and rx fifo
  */
void spi_slave_flush_fifo(spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	SPI_TypeDef *SPIx = SPI_DEV_TABLE[spi_idx].SPIx;
	
	SSI_Cmd(SPIx, DISABLE);
	SSI_Cmd(SPIx, ENABLE);

	obj->state &= ~SPI_STATE_TX_BUSY;
}

/**
  * @brief  slave recv target length data use interrupt mode and timeout mechanism.
  * @param  obj: spi slave object define in application software.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be read.
  * @param  timeout_ms: timeout waiting time.
  * @retval  : number of bytes read already
  */
int32_t spi_slave_read_stream_timeout(spi_t *obj, char *rx_buffer, uint32_t length, uint32_t timeout_ms)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	SPI_TypeDef *SPIx = SPI_DEV_TABLE[spi_idx].SPIx;
	uint32_t ret;
	uint32_t timeout = 0;
	uint32_t StartCount = 0;

	assert_param(timeout_ms > 0);
	
	if (obj->state & SPI_STATE_RX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spi_slave_read_stream: state(0x%x) is not ready\r\n", obj->state);
		return -HAL_BUSY;
	}

	obj->state |= SPI_STATE_RX_BUSY;
	if ((ret = ssi_int_read(ssi_adapter, rx_buffer, length)) != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
		return -HAL_BUSY;
	}


	StartCount = SYSTIMER_TickGet();
	while (1) {
		/* complete */
		if ((obj->state & SPI_STATE_RX_BUSY) == 0) {
			break;
		}

		/* time out */
		if (SYSTIMER_GetPassTime(StartCount) > timeout_ms) {
			ret = spi_stop_recv(obj);
			obj->state &= ~ SPI_STATE_RX_BUSY;
			timeout = 1;

			DBG_PRINTF(MODULE_SPI, LEVEL_INFO, "Slave is timeout\n");
			break;
		}
	}
		
	if (SSI_GetDataFrameSize(SPIx) > 8){
		ssi_adapter->RxLength <<= 1;
	}

	if(timeout)
		return (length - ssi_adapter->RxLength);
	else
		return length;
}

/**
  * @brief  slave recv target length data use interrupt mode and stop if the spi bus is idle.
  * @param  obj: spi slave object define in application software.
  * @param  rx_buffer: buffer to save data read from SPI FIFO.
  * @param  length: number of data bytes to be read.
  * @retval  : number of bytes read already
  */
int32_t spi_slave_read_stream_terminate(spi_t *obj, char *rx_buffer, uint32_t length)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	PHAL_SSI_ADAPTOR ssi_adapter = &ssi_adapter_g[spi_idx];
	SPI_TypeDef *SPIx = SPI_DEV_TABLE[spi_idx].SPIx;
	int ret;

	if (obj->state & SPI_STATE_RX_BUSY) {
		DBG_PRINTF(MODULE_SPI, LEVEL_WARN, "spi_slave_read_stream_dma: state(0x%x) is not ready\r\n", obj->state);
		return -HAL_BUSY;
	}

	obj->state |= SPI_STATE_RX_BUSY;
	if ((ret = ssi_int_read(ssi_adapter, rx_buffer, length)) != _TRUE) {
		obj->state &= ~SPI_STATE_RX_BUSY;
		return -HAL_BUSY;
	}


	while(obj->state & SPI_STATE_RX_BUSY) {
		if(SSI_Busy(SPIx) == 0){
			ret = spi_stop_recv(obj); 
			goto EndOfCS;
		}
	}

EndOfCS:
	if((obj->state & SPI_STATE_RX_BUSY) != 0){ 
		obj->state &= ~ SPI_STATE_RX_BUSY;
	}

	if (SSI_GetDataFrameSize(SPIx) > 8) {
		ssi_adapter->RxLength <<= 1;
	}

	return (length - ssi_adapter->RxLength);
}

/**
  * @brief  Open SPI device clock.
  * @param  obj: spi object define in application software.
  * @retval none
  */
void spi_enable(spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	
	if (spi_idx == 1) {
		RCC_PeriphClockCmd(APBPeriph_SPI1, APBPeriph_SPI1_CLOCK, ENABLE);
	} else {
		RCC_PeriphClockCmd(APBPeriph_SPI0, APBPeriph_SPI0_CLOCK, ENABLE);
	}
}

/**
  * @brief  Close SPI device clock.
  * @param  obj: spi object define in application software.
  * @retval none
  */
void spi_disable(spi_t *obj)
{
	uint8_t  spi_idx = obj->spi_idx &0x0F;
	
	if (spi_idx == 1) {
		RCC_PeriphClockCmd(APBPeriph_SPI1, APBPeriph_SPI1_CLOCK, DISABLE);
	} else {
		RCC_PeriphClockCmd(APBPeriph_SPI0, APBPeriph_SPI0_CLOCK, DISABLE);
	}
}