drivers/renesas/rcar/emmc/emmc_interrupt.c - tf-a-mtk - Git at Google

 /*
  * Copyright (c) 2015-2019, Renesas Electronics Corporation. All rights
  * reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <stddef.h>

 #include <lib/mmio.h>

 #include "emmc_config.h"
 #include "emmc_def.h"
 #include "emmc_hal.h"
 #include "emmc_registers.h"
 #include "emmc_std.h"
 #include "rcar_def.h"

 static EMMC_ERROR_CODE emmc_trans_sector(uint32_t *buff_address_virtual);

 uint32_t emmc_interrupt(void)
 {
 	EMMC_ERROR_CODE result;
 	uint32_t prr_data;
 	uint32_t cut_ver;
 	uint32_t end_bit;

 	prr_data = mmio_read_32((uintptr_t) RCAR_PRR);
 	cut_ver = prr_data & PRR_CUT_MASK;
 	if ((prr_data & PRR_PRODUCT_MASK) == PRR_PRODUCT_H3) {
 		if (cut_ver == PRR_PRODUCT_10) {
 			end_bit = BIT17;
 		} else if (cut_ver == PRR_PRODUCT_11) {
 			end_bit = BIT17;
 		} else {
 			end_bit = BIT20;
 		}
 	} else if ((prr_data & PRR_PRODUCT_MASK) == PRR_PRODUCT_M3) {
 		if (cut_ver == PRR_PRODUCT_10) {
 			end_bit = BIT17;
 		} else {
 			end_bit = BIT20;
 		}
 	} else {
 		end_bit = BIT20;
 	}

 	/* SD_INFO */
 	mmc_drv_obj.error_info.info1 = GETR_32(SD_INFO1);
 	mmc_drv_obj.error_info.info2 = GETR_32(SD_INFO2);

 	/* SD_INFO EVENT */
 	mmc_drv_obj.int_event1 =
 	    mmc_drv_obj.error_info.info1 & GETR_32(SD_INFO1_MASK);
 	mmc_drv_obj.int_event2 =
 	    mmc_drv_obj.error_info.info2 & GETR_32(SD_INFO2_MASK);

 	/* ERR_STS */
 	mmc_drv_obj.error_info.status1 = GETR_32(SD_ERR_STS1);
 	mmc_drv_obj.error_info.status2 = GETR_32(SD_ERR_STS2);

 	/* DM_CM_INFO */
 	mmc_drv_obj.error_info.dm_info1 = GETR_32(DM_CM_INFO1);
 	mmc_drv_obj.error_info.dm_info2 = GETR_32(DM_CM_INFO2);

 	/* DM_CM_INFO EVENT */
 	mmc_drv_obj.dm_event1 =
 	    mmc_drv_obj.error_info.dm_info1 & GETR_32(DM_CM_INFO1_MASK);
 	mmc_drv_obj.dm_event2 =
 	    mmc_drv_obj.error_info.dm_info2 & GETR_32(DM_CM_INFO2_MASK);

 	/* ERR SD_INFO2 */
 	if ((SD_INFO2_ALL_ERR & mmc_drv_obj.int_event2) != 0) {
 		SETR_32(SD_INFO1_MASK, 0x00000000U);	/* interrupt disable */
 		SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR);	/* interrupt disable */
 		SETR_32(SD_INFO1, 0x00000000U);	/* interrupt clear */
 		SETR_32(SD_INFO2, SD_INFO2_CLEAR);	/* interrupt clear */
 		mmc_drv_obj.state_machine_blocking = FALSE;
 	}

 	/* PIO Transfer */
 	/* BWE/BRE */
 	else if (((SD_INFO2_BWE | SD_INFO2_BRE) & mmc_drv_obj.int_event2)) {
 		/* BWE */
 		if (SD_INFO2_BWE & mmc_drv_obj.int_event2) {
 			SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BWE));
 		}
 		/* BRE */
 		else {
 			SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BRE));
 		}

 		result = emmc_trans_sector(mmc_drv_obj.buff_address_virtual);
 		mmc_drv_obj.buff_address_virtual += EMMC_BLOCK_LENGTH;
 		mmc_drv_obj.remain_size -= EMMC_BLOCK_LENGTH;

 		if (result != EMMC_SUCCESS) {
 			/* data transfer error */
 			emmc_write_error_info(EMMC_FUNCNO_NONE, result);

 			/* Panic */
 			SETR_32(SD_INFO1_MASK, 0x00000000U);
 			SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR);
 			SETR_32(SD_INFO1, 0x00000000U);
 			/* interrupt clear */
 			SETR_32(SD_INFO2, SD_INFO2_CLEAR);
 			mmc_drv_obj.force_terminate = TRUE;
 		} else {
 			mmc_drv_obj.during_transfer = FALSE;
 		}
 		mmc_drv_obj.state_machine_blocking = FALSE;
 	}

 	/* DMA_TRANSFER */
 	/* DM_CM_INFO1: DMA-ch0 transfer complete or error occurred */
 	else if ((BIT16 & mmc_drv_obj.dm_event1) != 0) {
 		SETR_32(DM_CM_INFO1, 0x00000000U);
 		SETR_32(DM_CM_INFO2, 0x00000000U);
 		/* interrupt clear */
 		SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BWE));
 		/* DM_CM_INFO2:  DMA-ch0 error occured */
 		if ((BIT16 & mmc_drv_obj.dm_event2) != 0) {
 			mmc_drv_obj.dma_error_flag = TRUE;
 		} else {
 			mmc_drv_obj.during_dma_transfer = FALSE;
 			mmc_drv_obj.during_transfer = FALSE;
 		}
 		/* wait next interrupt */
 		mmc_drv_obj.state_machine_blocking = FALSE;
 	}
 	/* DM_CM_INFO1: DMA-ch1 transfer complete or error occured */
 	else if ((end_bit & mmc_drv_obj.dm_event1) != 0U) {
 		SETR_32(DM_CM_INFO1, 0x00000000U);
 		SETR_32(DM_CM_INFO2, 0x00000000U);
 		/* interrupt clear */
 		SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BRE));
 		/* DM_CM_INFO2: DMA-ch1 error occured */
 		if ((BIT17 & mmc_drv_obj.dm_event2) != 0) {
 			mmc_drv_obj.dma_error_flag = TRUE;
 		} else {
 			mmc_drv_obj.during_dma_transfer = FALSE;
 			mmc_drv_obj.during_transfer = FALSE;
 		}
 		/* wait next interrupt */
 		mmc_drv_obj.state_machine_blocking = FALSE;
 	}

 	/* Response end  */
 	else if ((SD_INFO1_INFO0 & mmc_drv_obj.int_event1) != 0) {
 		/* interrupt clear */
 		SETR_32(SD_INFO1, (GETR_32(SD_INFO1) & ~SD_INFO1_INFO0));
 		mmc_drv_obj.state_machine_blocking = FALSE;
 	}
 	/* Access end  */
 	else if ((SD_INFO1_INFO2 & mmc_drv_obj.int_event1) != 0) {
 		/* interrupt clear */
 		SETR_32(SD_INFO1, (GETR_32(SD_INFO1) & ~SD_INFO1_INFO2));
 		mmc_drv_obj.state_machine_blocking = FALSE;
 	} else {
 		/* nothing to do. */
 	}

 	return (uint32_t) 0;
 }

 static EMMC_ERROR_CODE emmc_trans_sector(uint32_t *buff_address_virtual)
 {
 	uint32_t length, i;
 	uint64_t *bufPtrLL;

 	if (buff_address_virtual == NULL) {
 		return EMMC_ERR_PARAM;
 	}

 	if ((mmc_drv_obj.during_transfer != TRUE)
 	    || (mmc_drv_obj.remain_size == 0)) {
 		return EMMC_ERR_STATE;
 	}

 	bufPtrLL = (uint64_t *) buff_address_virtual;
 	length = mmc_drv_obj.remain_size;

 	/* data transefer */
 	for (i = 0; i < (length >> 3); i++) {
 		/* Write */
 		if (mmc_drv_obj.cmd_info.dir == HAL_MEMCARD_WRITE) {
 			SETR_64(SD_BUF0, *bufPtrLL);	/* buffer --> FIFO */
 		}
 		/* Read */
 		else {
 			/* Checks when the read data reaches SD_SIZE. */
 			/* The BRE bit is cleared at emmc_interrupt function. */
 			if (((i %
 			      (uint32_t) (EMMC_BLOCK_LENGTH >>
 					  EMMC_BUF_SIZE_SHIFT)) == 0U)
 			    && (i != 0U)) {
 				/* BRE check */
 				while (((GETR_32(SD_INFO2)) & SD_INFO2_BRE) ==
 				       0U) {
 					/* ERROR check */
 					if (((GETR_32(SD_INFO2)) &
 					     SD_INFO2_ALL_ERR) != 0U) {
 						return EMMC_ERR_TRANSFER;
 					}
 				}
 				/* BRE clear */
 				SETR_32(SD_INFO2,
 					(uint32_t) (GETR_32(SD_INFO2) &
 						    ~SD_INFO2_BRE));
 			}
 			*bufPtrLL = GETR_64(SD_BUF0);	/* FIFO --> buffer */
 		}
 		bufPtrLL++;
 	}

 	return EMMC_SUCCESS;
 }
	/*
	* Copyright (c) 2015-2019, Renesas Electronics Corporation. All rights
	* reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <stddef.h>

	#include <lib/mmio.h>

	#include "emmc_config.h"
	#include "emmc_def.h"
	#include "emmc_hal.h"
	#include "emmc_registers.h"
	#include "emmc_std.h"
	#include "rcar_def.h"

	static EMMC_ERROR_CODE emmc_trans_sector(uint32_t *buff_address_virtual);

	uint32_t emmc_interrupt(void)
	{
	EMMC_ERROR_CODE result;
	uint32_t prr_data;
	uint32_t cut_ver;
	uint32_t end_bit;

	prr_data = mmio_read_32((uintptr_t) RCAR_PRR);
	cut_ver = prr_data & PRR_CUT_MASK;
	if ((prr_data & PRR_PRODUCT_MASK) == PRR_PRODUCT_H3) {
	if (cut_ver == PRR_PRODUCT_10) {
	end_bit = BIT17;
	} else if (cut_ver == PRR_PRODUCT_11) {
	end_bit = BIT17;
	} else {
	end_bit = BIT20;
	}
	} else if ((prr_data & PRR_PRODUCT_MASK) == PRR_PRODUCT_M3) {
	if (cut_ver == PRR_PRODUCT_10) {
	end_bit = BIT17;
	} else {
	end_bit = BIT20;
	}
	} else {
	end_bit = BIT20;
	}

	/* SD_INFO */
	mmc_drv_obj.error_info.info1 = GETR_32(SD_INFO1);
	mmc_drv_obj.error_info.info2 = GETR_32(SD_INFO2);

	/* SD_INFO EVENT */
	mmc_drv_obj.int_event1 =
	mmc_drv_obj.error_info.info1 & GETR_32(SD_INFO1_MASK);
	mmc_drv_obj.int_event2 =
	mmc_drv_obj.error_info.info2 & GETR_32(SD_INFO2_MASK);

	/* ERR_STS */
	mmc_drv_obj.error_info.status1 = GETR_32(SD_ERR_STS1);
	mmc_drv_obj.error_info.status2 = GETR_32(SD_ERR_STS2);

	/* DM_CM_INFO */
	mmc_drv_obj.error_info.dm_info1 = GETR_32(DM_CM_INFO1);
	mmc_drv_obj.error_info.dm_info2 = GETR_32(DM_CM_INFO2);

	/* DM_CM_INFO EVENT */
	mmc_drv_obj.dm_event1 =
	mmc_drv_obj.error_info.dm_info1 & GETR_32(DM_CM_INFO1_MASK);
	mmc_drv_obj.dm_event2 =
	mmc_drv_obj.error_info.dm_info2 & GETR_32(DM_CM_INFO2_MASK);

	/* ERR SD_INFO2 */
	if ((SD_INFO2_ALL_ERR & mmc_drv_obj.int_event2) != 0) {
	SETR_32(SD_INFO1_MASK, 0x00000000U); /* interrupt disable */
	SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR); /* interrupt disable */
	SETR_32(SD_INFO1, 0x00000000U); /* interrupt clear */
	SETR_32(SD_INFO2, SD_INFO2_CLEAR); /* interrupt clear */
	mmc_drv_obj.state_machine_blocking = FALSE;
	}

	/* PIO Transfer */
	/* BWE/BRE */
	else if (((SD_INFO2_BWE \| SD_INFO2_BRE) & mmc_drv_obj.int_event2)) {
	/* BWE */
	if (SD_INFO2_BWE & mmc_drv_obj.int_event2) {
	SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BWE));
	}
	/* BRE */
	else {
	SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BRE));
	}

	result = emmc_trans_sector(mmc_drv_obj.buff_address_virtual);
	mmc_drv_obj.buff_address_virtual += EMMC_BLOCK_LENGTH;
	mmc_drv_obj.remain_size -= EMMC_BLOCK_LENGTH;

	if (result != EMMC_SUCCESS) {
	/* data transfer error */
	emmc_write_error_info(EMMC_FUNCNO_NONE, result);

	/* Panic */
	SETR_32(SD_INFO1_MASK, 0x00000000U);
	SETR_32(SD_INFO2_MASK, SD_INFO2_CLEAR);
	SETR_32(SD_INFO1, 0x00000000U);
	/* interrupt clear */
	SETR_32(SD_INFO2, SD_INFO2_CLEAR);
	mmc_drv_obj.force_terminate = TRUE;
	} else {
	mmc_drv_obj.during_transfer = FALSE;
	}
	mmc_drv_obj.state_machine_blocking = FALSE;
	}

	/* DMA_TRANSFER */
	/* DM_CM_INFO1: DMA-ch0 transfer complete or error occurred */
	else if ((BIT16 & mmc_drv_obj.dm_event1) != 0) {
	SETR_32(DM_CM_INFO1, 0x00000000U);
	SETR_32(DM_CM_INFO2, 0x00000000U);
	/* interrupt clear */
	SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BWE));
	/* DM_CM_INFO2: DMA-ch0 error occured */
	if ((BIT16 & mmc_drv_obj.dm_event2) != 0) {
	mmc_drv_obj.dma_error_flag = TRUE;
	} else {
	mmc_drv_obj.during_dma_transfer = FALSE;
	mmc_drv_obj.during_transfer = FALSE;
	}
	/* wait next interrupt */
	mmc_drv_obj.state_machine_blocking = FALSE;
	}
	/* DM_CM_INFO1: DMA-ch1 transfer complete or error occured */
	else if ((end_bit & mmc_drv_obj.dm_event1) != 0U) {
	SETR_32(DM_CM_INFO1, 0x00000000U);
	SETR_32(DM_CM_INFO2, 0x00000000U);
	/* interrupt clear */
	SETR_32(SD_INFO2, (GETR_32(SD_INFO2) & ~SD_INFO2_BRE));
	/* DM_CM_INFO2: DMA-ch1 error occured */
	if ((BIT17 & mmc_drv_obj.dm_event2) != 0) {
	mmc_drv_obj.dma_error_flag = TRUE;
	} else {
	mmc_drv_obj.during_dma_transfer = FALSE;
	mmc_drv_obj.during_transfer = FALSE;
	}
	/* wait next interrupt */
	mmc_drv_obj.state_machine_blocking = FALSE;
	}

	/* Response end */
	else if ((SD_INFO1_INFO0 & mmc_drv_obj.int_event1) != 0) {
	/* interrupt clear */
	SETR_32(SD_INFO1, (GETR_32(SD_INFO1) & ~SD_INFO1_INFO0));
	mmc_drv_obj.state_machine_blocking = FALSE;
	}
	/* Access end */
	else if ((SD_INFO1_INFO2 & mmc_drv_obj.int_event1) != 0) {
	/* interrupt clear */
	SETR_32(SD_INFO1, (GETR_32(SD_INFO1) & ~SD_INFO1_INFO2));
	mmc_drv_obj.state_machine_blocking = FALSE;
	} else {
	/* nothing to do. */
	}

	return (uint32_t) 0;
	}

	static EMMC_ERROR_CODE emmc_trans_sector(uint32_t *buff_address_virtual)
	{
	uint32_t length, i;
	uint64_t *bufPtrLL;

	if (buff_address_virtual == NULL) {
	return EMMC_ERR_PARAM;
	}

	if ((mmc_drv_obj.during_transfer != TRUE)
	\|\| (mmc_drv_obj.remain_size == 0)) {
	return EMMC_ERR_STATE;
	}

	bufPtrLL = (uint64_t *) buff_address_virtual;
	length = mmc_drv_obj.remain_size;

	/* data transefer */
	for (i = 0; i < (length >> 3); i++) {
	/* Write */
	if (mmc_drv_obj.cmd_info.dir == HAL_MEMCARD_WRITE) {
	SETR_64(SD_BUF0, bufPtrLL); / buffer --> FIFO */
	}
	/* Read */
	else {
	/* Checks when the read data reaches SD_SIZE. */
	/* The BRE bit is cleared at emmc_interrupt function. */
	if (((i %
	(uint32_t) (EMMC_BLOCK_LENGTH >>
	EMMC_BUF_SIZE_SHIFT)) == 0U)
	&& (i != 0U)) {
	/* BRE check */
	while (((GETR_32(SD_INFO2)) & SD_INFO2_BRE) ==
	0U) {
	/* ERROR check */
	if (((GETR_32(SD_INFO2)) &
	SD_INFO2_ALL_ERR) != 0U) {
	return EMMC_ERR_TRANSFER;
	}
	}
	/* BRE clear */
	SETR_32(SD_INFO2,
	(uint32_t) (GETR_32(SD_INFO2) &
	~SD_INFO2_BRE));
	}
	bufPtrLL = GETR_64(SD_BUF0); / FIFO --> buffer */
	}
	bufPtrLL++;
	}

	return EMMC_SUCCESS;
	}