#include "scsi.h" #include "diskio.h" #define HALT_UNTIL_DEBUGGING() \ while (!((*(volatile uint32_t *)0xE000EDF0) & (1 << 0))) {} \ __asm__ __volatile__("bkpt 1") volatile bool usb_bulk_block_send = false; void usb_bulk_block_cb(void* user_data, unsigned int bytes_transferred) { usb_bulk_block_send = true; (void)user_data; (void)bytes_transferred; } void usb_send_bulk(void* const data, const uint32_t maximum_length) { usb_bulk_block_send = false; usb_transfer_schedule_block( &usb_endpoint_bulk_in, data, maximum_length, usb_bulk_block_cb, NULL); while (!usb_bulk_block_send); } void usb_send_csw(msd_cbw_t *msd_cbw_data, uint8_t status) { msd_csw_t csw = { .signature = MSD_CSW_SIGNATURE, .tag = msd_cbw_data->tag, .data_residue = 0, .status = status }; memcpy(&usb_bulk_buffer[0], &csw, sizeof(msd_csw_t)); usb_send_bulk(&usb_bulk_buffer[0], sizeof(msd_csw_t)); } uint8_t handle_inquiry(msd_cbw_t *msd_cbw_data) { (void)msd_cbw_data; scsi_inquiry_response_t ret = { 0x00, /* direct access block device */ 0x80, /* removable */ 0x00, //0x04, /* SPC-2 */ 0x00, //0x02, /* response data format */ 0x20, /* response has 0x20 + 4 bytes */ 0x00, 0x00, 0x00, "Mayhem", "Portapack MSD", {'v','1','.','6'} }; memcpy(&usb_bulk_buffer[0], &ret, sizeof(scsi_inquiry_response_t)); usb_send_bulk(&usb_bulk_buffer[0], sizeof(scsi_inquiry_response_t)); return 0; } uint8_t handle_inquiry_serial_number(msd_cbw_t *msd_cbw_data) { (void)msd_cbw_data; scsi_unit_serial_number_inquiry_response_t ret = { .peripheral = 0x00, .page_code = 0x80, .reserved = 0, .page_length = 0x08, .serialNumber = "Mayhem" }; memcpy(&usb_bulk_buffer[0], &ret, sizeof(scsi_unit_serial_number_inquiry_response_t)); usb_send_bulk(&usb_bulk_buffer[0], sizeof(scsi_unit_serial_number_inquiry_response_t)); return 0; } uint8_t read_format_capacities(msd_cbw_t *msd_cbw_data) { uint16_t len = msd_cbw_data->cmd_data[7] << 8 | msd_cbw_data->cmd_data[8]; if (len != 0) { size_t num_blocks = get_capacity(); scsi_read_format_capacities_response_t ret = { .header = {0, 0, 0, 1 * 8 /* num_entries * 8 */}, .blocknum = {((num_blocks) >> 24)& 0xff, ((num_blocks) >> 16)& 0xff, ((num_blocks) >> 8)& 0xff, num_blocks & 0xff}, .blocklen = {0b10 /* formated */, 0, (512) >> 8, 0}, // .blocknum2 = {((num_blocks) >> 24)& 0xff, ((num_blocks) >> 16)& 0xff, ((num_blocks) >> 8)& 0xff, num_blocks & 0xff}, // .blocklen2 = {0 /* formated */, 0, (512) >> 8, 0} }; memcpy(&usb_bulk_buffer[0], &ret, sizeof(scsi_read_format_capacities_response_t)); usb_send_bulk(&usb_bulk_buffer[0], sizeof(scsi_read_format_capacities_response_t)); } return 0; } uint8_t read_capacity10(msd_cbw_t *msd_cbw_data) { (void)msd_cbw_data; size_t num_blocks = get_capacity(); scsi_read_capacity10_response_t ret = { .last_block_addr = cpu_to_be32(num_blocks - 1), .block_size = cpu_to_be32(512) }; memcpy(&usb_bulk_buffer[0], &ret, sizeof(scsi_read_capacity10_response_t)); usb_send_bulk(&usb_bulk_buffer[0], sizeof(scsi_read_capacity10_response_t)); return 0; } uint8_t request_sense(msd_cbw_t *msd_cbw_data) { (void)msd_cbw_data; scsi_sense_response_t ret = { .byte = { 0x70, 0, SCSI_SENSE_KEY_GOOD, 0, 0, 0, 0, 8, 0, 0 ,0 ,0, SCSI_ASENSE_NO_ADDITIONAL_INFORMATION, SCSI_ASENSEQ_NO_QUALIFIER, 0, 0, 0, 0 } }; memcpy(&usb_bulk_buffer[0], &ret, sizeof(scsi_sense_response_t)); usb_send_bulk(&usb_bulk_buffer[0], sizeof(scsi_sense_response_t)); return 0; } uint8_t mode_sense6 (msd_cbw_t *msd_cbw_data) { (void)msd_cbw_data; scsi_mode_sense6_response_t ret = { .byte = { sizeof(scsi_mode_sense6_response_t) - 1, 0, 0, // 0x01 << 7, // 0 for not write protected 0 } }; memcpy(&usb_bulk_buffer[0], &ret, sizeof(scsi_mode_sense6_response_t)); usb_send_bulk(&usb_bulk_buffer[0], sizeof(scsi_mode_sense6_response_t)); return 0; } static data_request_t decode_data_request(const uint8_t *cmd) { data_request_t req; uint32_t lba; uint16_t blk; memcpy(&lba, &cmd[2], sizeof(lba)); memcpy(&blk, &cmd[7], sizeof(blk)); req.first_lba = be32_to_cpu(lba); req.blk_cnt = be16_to_cpu(blk); return req; } uint8_t data_read10(msd_cbw_t *msd_cbw_data) { data_request_t req = decode_data_request(msd_cbw_data->cmd_data); for (size_t block_index = 0; block_index < req.blk_cnt; block_index++) { read_block(req.first_lba + block_index, &usb_bulk_buffer[0], 1 /* n blocks */); usb_send_bulk(&usb_bulk_buffer[0], 512); } return 0; } volatile uint32_t write10_blocks_send = 0; void write10_cb(void* user_data, unsigned int bytes_transferred) { write10_blocks_send++; (void)user_data; (void)bytes_transferred; } uint8_t data_write10(msd_cbw_t *msd_cbw_data) { write10_blocks_send = 0; data_request_t req = decode_data_request(msd_cbw_data->cmd_data); for (size_t block_index = 0; block_index < req.blk_cnt; block_index++) { usb_transfer_schedule_block( &usb_endpoint_bulk_out, &usb_bulk_buffer[0], 512, write10_cb, msd_cbw_data); while (write10_blocks_send <= block_index); //TODO: write to SD } return 0; } void scsi_command(msd_cbw_t *msd_cbw_data) { uint8_t status = 1; switch (msd_cbw_data->cmd_data[0]) { case SCSI_CMD_INQUIRY: //status = handle_inquiry(msd_cbw_data); if ((msd_cbw_data->cmd_data[1] & 0b1) && msd_cbw_data->cmd_data[2] == 0x80) { status = handle_inquiry_serial_number(msd_cbw_data); } else if ((msd_cbw_data->cmd_data[1] & 0b11) || msd_cbw_data->cmd_data[2] != 0) { //TODO: implement sense status = 1; } else { status = handle_inquiry(msd_cbw_data); } break; case SCSI_CMD_REQUEST_SENSE: status = request_sense(msd_cbw_data); break; case SCSI_CMD_READ_CAPACITY_10: status = read_capacity10(msd_cbw_data); break; case SCSI_CMD_READ_10: status = data_read10(msd_cbw_data); break; case SCSI_CMD_WRITE_10: status = data_write10(msd_cbw_data); break; case SCSI_CMD_TEST_UNIT_READY: status = 0; break; case SCSI_CMD_PREVENT_ALLOW_MEDIUM_REMOVAL: status = 0; break; case SCSI_CMD_MODE_SENSE_6: status = mode_sense6(msd_cbw_data); break; case SCSI_CMD_READ_FORMAT_CAPACITIES: status = read_format_capacities(msd_cbw_data); break; case SCSI_CMD_VERIFY_10: status = 0; break; } usb_send_csw(msd_cbw_data, status); }