/* * Copyright (c) 2010-2013 embedded brains GmbH. All rights reserved. * * embedded brains GmbH * Dornierstr. 4 * 82178 Puchheim * Germany * * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.rtems.org/license/LICENSE. */ #ifndef GEN5200_ATA_H #define GEN5200_ATA_H #include "bestcomm.h" #include #include #include #include #include #include #include #include #ifdef __cplusplus extern "C" { #endif /* __cplusplus */ #define DCTRL_SRST BSP_BBIT8(5) #define DCTRL_NIEN BSP_BBIT8(6) #define DAST_BSY BSP_BBIT8(0) #define DAST_DRDY BSP_BBIT8(1) #define DAST_DRQ BSP_BBIT8(4) #define DAST_ERR BSP_BBIT8(7) #define DST_BSY BSP_BBIT16(0) #define DST_DRDY BSP_BBIT16(1) #define DST_DRQ BSP_BBIT16(4) #define DST_ERR BSP_BBIT16(7) #define DDMA_HUT BSP_BBIT8(1) #define DDMA_FR BSP_BBIT8(2) #define DDMA_FE BSP_BBIT8(3) #define DDMA_IE BSP_BBIT8(4) #define DDMA_UDMA BSP_BBIT8(5) #define DDMA_READ BSP_BBIT8(6) #define DDMA_WRITE BSP_BBIT8(7) #define ATA_SECTOR_SHIFT 9 #define ATA_PER_TRANSFER_SECTOR_COUNT_MAX 256 typedef union { struct { uint8_t alternate_status; uint8_t reserved_0[3]; uint16_t data; uint8_t reserved_1[2]; uint8_t error; uint8_t reserved_2[3]; uint8_t sector_count; uint8_t reserved_3[3]; uint8_t sector; uint8_t reserved_4[3]; uint8_t cylinder_low; uint8_t reserved_5[3]; uint8_t cylinder_high; uint8_t reserved_6[3]; uint8_t head; uint8_t reserved_7[3]; uint16_t status; uint8_t reserved_8[2]; } read; struct { uint8_t control; uint8_t reserved_0[3]; uint16_t data; uint8_t reserved_1[2]; uint8_t feature; uint8_t reserved_2[3]; uint8_t sector_count; uint8_t reserved_3[3]; uint8_t sector; uint8_t reserved_4[3]; uint8_t cylinder_low; uint8_t reserved_5[3]; uint8_t cylinder_high; uint8_t reserved_6[3]; uint8_t head; uint8_t reserved_7[3]; uint8_t command; uint8_t dma_control; uint8_t reserved_8[2]; } write; } ata_drive_registers; #define ATA ((volatile ata_drive_registers *) 0xf0003a5c) static inline bool ata_is_data_request(void) { return (ATA->read.alternate_status & DAST_DRQ) != 0; } static inline bool ata_is_drive_ready_for_selection(void) { return (ATA->read.alternate_status & (DAST_BSY | DAST_DRQ)) == 0; } static inline void ata_wait_400_nano_seconds(void) { ATA->read.alternate_status; } static inline void ata_wait_for_drive_ready(void) { while ((ATA->read.alternate_status & (DAST_BSY | DAST_DRQ | DAST_DRDY)) != DAST_DRDY) { /* Wait */ } } static inline void ata_wait_for_not_busy(void) { ata_wait_400_nano_seconds(); while ((ATA->read.alternate_status & DAST_BSY) != 0) { /* Wait */ } } static inline bool ata_wait_for_data_request(void) { ata_wait_400_nano_seconds(); uint8_t alternate_status; do { alternate_status = ATA->read.alternate_status; } while ((alternate_status & DAST_BSY) == DAST_BSY); return (alternate_status & (DAST_ERR | DAST_DRQ)) == DAST_DRQ; } static inline bool ata_check_status(void) { return (ATA->read.status & (DST_BSY | DST_ERR)) == 0; } static inline void ata_clear_interrupts(void) { ATA->read.status; } static inline uint8_t ata_read_or_write_sectors_command(bool read) { return read ? 0x20 : 0x30; } static inline rtems_blkdev_bnum ata_max_transfer_count(rtems_blkdev_bnum sector_count) { return sector_count > ATA_PER_TRANSFER_SECTOR_COUNT_MAX ? ATA_PER_TRANSFER_SECTOR_COUNT_MAX : sector_count; } static inline void ata_flush_sector(uint16_t *begin) { /* XXX: The dcbi operation does not work properly */ rtems_cache_flush_multiple_data_lines(begin, ATA_SECTOR_SIZE); } void ata_reset_device(void); bool ata_set_transfer_mode(uint8_t mode); bool ata_execute_io_command(uint8_t command, uint32_t lba, uint32_t sector_count); static inline bool ata_execute_io_command_with_sg(uint8_t command, const rtems_blkdev_sg_buffer *sg) { uint32_t lba = sg->block; uint32_t sector_count = sg->length / ATA_SECTOR_SIZE; return ata_execute_io_command(command, lba, sector_count); } typedef struct { const rtems_blkdev_sg_buffer *sg; size_t sg_count; rtems_blkdev_bnum sg_buffer_offset_mask; int sg_index_shift; } ata_sg_context; static inline void ata_sg_reset(ata_sg_context *self, const rtems_blkdev_sg_buffer *sg, size_t sg_count) { self->sg = sg; self->sg_count = sg_count; uint32_t sectors_per_buffer = self->sg[0].length >> ATA_SECTOR_SHIFT; self->sg_buffer_offset_mask = sectors_per_buffer - 1; self->sg_index_shift = __builtin_ffs((int) sectors_per_buffer) - 1; } static inline void ata_sg_create_default(ata_sg_context *self) { ata_sg_reset(self, NULL, 0); } static inline void ata_sg_create(ata_sg_context *self, const rtems_blkdev_sg_buffer *sg, size_t sg_count) { ata_sg_reset(self, sg, sg_count); } static inline rtems_blkdev_bnum ata_sg_get_start_sector(const ata_sg_context *self) { return self->sg[0].block; } static inline rtems_blkdev_bnum ata_sg_get_sector_count(const ata_sg_context *self) { return (self->sg_buffer_offset_mask + 1) * self->sg_count; } static inline uint16_t *ata_sg_get_sector_data_begin(const ata_sg_context *self, rtems_blkdev_bnum relative_sector) { uint16_t *begin = (uint16_t *)(self->sg[relative_sector >> self->sg_index_shift].buffer); return begin + ((relative_sector & self->sg_buffer_offset_mask) << (ATA_SECTOR_SHIFT - 1)); } static inline uint16_t *ata_sg_get_sector_data_end(const ata_sg_context *self, uint16_t *begin) { return begin + ATA_SECTOR_SIZE / 2; } typedef struct { rtems_id lock; bool card_present; } ata_driver; void ata_driver_create(ata_driver *self, const char *device_file_path, rtems_block_device_ioctl io_control); void ata_driver_destroy(ata_driver *self); static inline void ata_driver_lock(const ata_driver *self) { rtems_status_code sc = rtems_semaphore_obtain(self->lock, RTEMS_WAIT, RTEMS_NO_TIMEOUT); assert(sc == RTEMS_SUCCESSFUL); } static inline void ata_driver_unlock(const ata_driver *self) { rtems_status_code sc = rtems_semaphore_release(self->lock); assert(sc == RTEMS_SUCCESSFUL); } static inline bool ata_driver_is_card_present(const ata_driver *self) { return self->card_present; } static inline void ata_driver_io_request( ata_driver *self, rtems_blkdev_request *request, bool (*transfer)(ata_driver *, bool, rtems_blkdev_sg_buffer *, size_t) ) { assert(request->req == RTEMS_BLKDEV_REQ_READ || request->req == RTEMS_BLKDEV_REQ_WRITE); bool read = request->req != RTEMS_BLKDEV_REQ_WRITE; rtems_blkdev_sg_buffer *sg = &request->bufs[0]; uint32_t sg_count = request->bufnum; ata_driver_lock(self); bool ok = (*transfer)(self, read, sg, sg_count); ata_driver_unlock(self); rtems_status_code sc = ok ? RTEMS_SUCCESSFUL : RTEMS_IO_ERROR; rtems_blkdev_request_done(request, sc); } static inline int ata_driver_io_control( rtems_disk_device *dd, uint32_t cmd, void *arg, bool (*transfer)(ata_driver *, bool, rtems_blkdev_sg_buffer *, size_t) ) { ata_driver *self = (ata_driver *) rtems_disk_get_driver_data(dd); switch (cmd) { case RTEMS_BLKIO_REQUEST: ata_driver_io_request(self, (rtems_blkdev_request *) arg, transfer); return 0; case RTEMS_BLKIO_CAPABILITIES: *(uint32_t *) arg = RTEMS_BLKDEV_CAP_MULTISECTOR_CONT; return 0; default: return rtems_blkdev_ioctl(dd, cmd, arg); } } int ata_driver_io_control_pio_polled( rtems_disk_device *dd, uint32_t cmd, void *arg ); typedef struct { ata_driver super; bestcomm_task task; bool read; ata_sg_context sg_context; rtems_blkdev_bnum transfer_current; rtems_blkdev_bnum transfer_end; } ata_driver_dma_pio_single; void ata_driver_dma_pio_single_create( ata_driver_dma_pio_single *self, const char *device_file_path, TaskId task_index ); #ifdef __cplusplus } #endif /* __cplusplus */ #endif /* GEN5200_ATA_H */