/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2007 by Björn Stenberg * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "string.h" #include "system.h" #include "usb_core.h" #include "usb_drv.h" #include "usb_class_driver.h" //#define LOGF_ENABLE #include "logf.h" #include "storage.h" #include "hotswap.h" #include "disk.h" /* Needed to get at the audio buffer */ #include "audio.h" #include "usb_storage.h" /* Enable the following define to export only the SD card slot. This * is useful for USBCV MSC tests, as those are destructive. * This won't work right if the device doesn't have a card slot. */ //#define ONLY_EXPOSE_CARD_SLOT #ifdef USB_USE_RAMDISK #define RAMDISK_SIZE 2048 #endif #define SECTOR_SIZE 512 /* the ARC driver currently supports up to 64k USB transfers. This is * enough for efficient mass storage support, as commonly host OSes * don't do larger SCSI transfers anyway, so larger USB transfers * wouldn't buy us anything. * Due to being the double-buffering system used, using a smaller write buffer * ends up being more efficient. Measurements have shown that 24k to 28k is * optimal, except for sd devices that apparently don't gain anything from * double-buffering */ #define READ_BUFFER_SIZE (1024*64) #if (CONFIG_STORAGE & STORAGE_SD) #define WRITE_BUFFER_SIZE (1024*64) #else #define WRITE_BUFFER_SIZE (1024*24) #endif #define ALLOCATE_BUFFER_SIZE (2*MAX(READ_BUFFER_SIZE,WRITE_BUFFER_SIZE)) /* bulk-only class specific requests */ #define USB_BULK_RESET_REQUEST 0xff #define USB_BULK_GET_MAX_LUN 0xfe #define DIRECT_ACCESS_DEVICE 0x00 /* disks */ #define DEVICE_REMOVABLE 0x80 #define CBW_SIGNATURE 0x43425355 #define CSW_SIGNATURE 0x53425355 #define SCSI_TEST_UNIT_READY 0x00 #define SCSI_INQUIRY 0x12 #define SCSI_MODE_SENSE_6 0x1a #define SCSI_MODE_SENSE_10 0x5a #define SCSI_REQUEST_SENSE 0x03 #define SCSI_ALLOW_MEDIUM_REMOVAL 0x1e #define SCSI_READ_CAPACITY 0x25 #define SCSI_READ_FORMAT_CAPACITY 0x23 #define SCSI_READ_10 0x28 #define SCSI_WRITE_10 0x2a #define SCSI_START_STOP_UNIT 0x1b #define SCSI_REPORT_LUNS 0xa0 #define UMS_STATUS_GOOD 0x00 #define UMS_STATUS_FAIL 0x01 #define SENSE_NOT_READY 0x02 #define SENSE_MEDIUM_ERROR 0x03 #define SENSE_ILLEGAL_REQUEST 0x05 #define SENSE_UNIT_ATTENTION 0x06 #define ASC_MEDIUM_NOT_PRESENT 0x3a #define ASC_INVALID_FIELD_IN_CBD 0x24 #define ASC_LBA_OUT_OF_RANGE 0x21 #define ASC_WRITE_ERROR 0x0C #define ASC_READ_ERROR 0x11 #define ASC_NOT_READY 0x04 #define ASC_INVALID_COMMAND 0x20 #define ASCQ_BECOMING_READY 0x01 #define SCSI_FORMAT_CAPACITY_FORMATTED_MEDIA 0x02000000 /* storage interface */ #define USB_SC_SCSI 0x06 /* Transparent */ #define USB_PROT_BULK 0x50 /* bulk only */ static struct usb_interface_descriptor __attribute__((aligned(2))) interface_descriptor = { .bLength = sizeof(struct usb_interface_descriptor), .bDescriptorType = USB_DT_INTERFACE, .bInterfaceNumber = 0, .bAlternateSetting = 0, .bNumEndpoints = 2, .bInterfaceClass = USB_CLASS_MASS_STORAGE, .bInterfaceSubClass = USB_SC_SCSI, .bInterfaceProtocol = USB_PROT_BULK, .iInterface = 0 }; static struct usb_endpoint_descriptor __attribute__((aligned(2))) endpoint_descriptor = { .bLength = sizeof(struct usb_endpoint_descriptor), .bDescriptorType = USB_DT_ENDPOINT, .bEndpointAddress = 0, .bmAttributes = USB_ENDPOINT_XFER_BULK, .wMaxPacketSize = 0, .bInterval = 0 }; struct inquiry_data { unsigned char DeviceType; unsigned char DeviceTypeModifier; unsigned char Versions; unsigned char Format; unsigned char AdditionalLength; unsigned char Reserved[2]; unsigned char Capability; unsigned char VendorId[8]; unsigned char ProductId[16]; unsigned char ProductRevisionLevel[4]; } __attribute__ ((packed)); struct report_lun_data { unsigned int lun_list_length; unsigned int reserved1; // TODO this should be cleaned up with the VOLUMES vs DRIVES mess unsigned char luns[NUM_VOLUMES][8]; } __attribute__ ((packed)); struct sense_data { unsigned char ResponseCode; unsigned char Obsolete; unsigned char fei_sensekey; unsigned int Information; unsigned char AdditionalSenseLength; unsigned int CommandSpecificInformation; unsigned char AdditionalSenseCode; unsigned char AdditionalSenseCodeQualifier; unsigned char FieldReplaceableUnitCode; unsigned char SKSV; unsigned short SenseKeySpecific; } __attribute__ ((packed)); struct mode_sense_bdesc_longlba { unsigned char num_blocks[8]; unsigned char reserved[4]; unsigned char block_size[4]; } __attribute__ ((packed)); struct mode_sense_bdesc_shortlba { unsigned char density_code; unsigned char num_blocks[3]; unsigned char reserved; unsigned char block_size[3]; } __attribute__ ((packed)); struct mode_sense_data_10 { unsigned short mode_data_length; unsigned char medium_type; unsigned char device_specific; unsigned char longlba; unsigned char reserved; unsigned short block_descriptor_length; struct mode_sense_bdesc_longlba block_descriptor; } __attribute__ ((packed)); struct mode_sense_data_6 { unsigned char mode_data_length; unsigned char medium_type; unsigned char device_specific; unsigned char block_descriptor_length; struct mode_sense_bdesc_shortlba block_descriptor; } __attribute__ ((packed)); struct command_block_wrapper { unsigned int signature; unsigned int tag; unsigned int data_transfer_length; unsigned char flags; unsigned char lun; unsigned char command_length; unsigned char command_block[16]; } __attribute__ ((packed)); struct command_status_wrapper { unsigned int signature; unsigned int tag; unsigned int data_residue; unsigned char status; } __attribute__ ((packed)); struct capacity { unsigned int block_count; unsigned int block_size; } __attribute__ ((packed)); struct format_capacity { unsigned int following_length; unsigned int block_count; unsigned int block_size; } __attribute__ ((packed)); static union { unsigned char* transfer_buffer; struct inquiry_data* inquiry; struct capacity* capacity_data; struct format_capacity* format_capacity_data; struct sense_data *sense_data; struct mode_sense_data_6 *ms_data_6; struct mode_sense_data_10 *ms_data_10; struct report_lun_data *lun_data; struct command_status_wrapper* csw; char *max_lun; } tb; static char *cbw_buffer; static struct { unsigned int sector; unsigned int count; unsigned int orig_count; unsigned int cur_cmd; unsigned int tag; unsigned int lun; unsigned char *data[2]; unsigned char data_select; unsigned int last_result; } cur_cmd; static struct { unsigned char sense_key; unsigned char information; unsigned char asc; unsigned char ascq; } cur_sense_data; static void handle_scsi(struct command_block_wrapper* cbw); static void send_csw(int status); static void send_command_result(void *data,int size); static void send_command_failed_result(void); static void send_block_data(void *data,int size); static void receive_block_data(void *data,int size); static void fill_inquiry(IF_MV_NONVOID(int lun)); static void send_and_read_next(void); static bool ejected[NUM_VOLUMES]; static bool locked[NUM_VOLUMES]; static int usb_interface; static int ep_in, ep_out; #ifdef USB_USE_RAMDISK static unsigned char* ramdisk_buffer; #endif static enum { WAITING_FOR_COMMAND, SENDING_BLOCKS, SENDING_RESULT, SENDING_FAILED_RESULT, RECEIVING_BLOCKS, SENDING_CSW } state = WAITING_FOR_COMMAND; #ifdef TOSHIBA_GIGABEAT_S /* The Gigabeat S factory partition table contains invalid values for the "active" flag in the MBR. This prevents at least the Linux kernel from accepting the partition table, so we fix it on-the-fly. */ static void fix_mbr(unsigned char* mbr) { unsigned char* p = mbr + 0x1be; p[0x00] &= 0x80; p[0x10] &= 0x80; p[0x20] &= 0x80; p[0x30] &= 0x80; } #endif static bool check_disk_present(IF_MV_NONVOID(int volume)) { #ifdef USB_USE_RAMDISK return true; #else unsigned char sector[512]; return storage_read_sectors(volume,0,1,sector) == 0; #endif } void usb_storage_try_release_storage(void) { /* Check if there is a connected drive left. If not, release excusive access */ bool canrelease=true; int i; for(i=0;isignature) == CBW_SIGNATURE) { handle_scsi(cbw); } else { usb_drv_stall(ep_in, true,true); usb_drv_stall(ep_out, true,false); } break; case SENDING_CSW: if(dir==USB_DIR_OUT) { logf("OUT received in SENDING_CSW"); } //logf("csw sent, now go back to idle"); state = WAITING_FOR_COMMAND; #if 0 if(cur_cmd.cur_cmd == SCSI_WRITE_10) { queue_broadcast(SYS_USB_WRITE_DATA, (cur_cmd.lun<<16)+cur_cmd.orig_count); } else if(cur_cmd.cur_cmd == SCSI_READ_10) { queue_broadcast(SYS_USB_READ_DATA, (cur_cmd.lun<<16)+cur_cmd.orig_count); } #endif break; case SENDING_RESULT: if(dir==USB_DIR_OUT) { logf("OUT received in SENDING"); } if(status==0) { //logf("data sent, now send csw"); send_csw(UMS_STATUS_GOOD); } else { logf("Transfer failed %X",status); send_csw(UMS_STATUS_FAIL); /* TODO fill in cur_sense_data */ cur_sense_data.sense_key=0; cur_sense_data.information=0; cur_sense_data.asc=0; cur_sense_data.ascq=0; } break; case SENDING_FAILED_RESULT: if(dir==USB_DIR_OUT) { logf("OUT received in SENDING"); } send_csw(UMS_STATUS_FAIL); break; case SENDING_BLOCKS: if(dir==USB_DIR_OUT) { logf("OUT received in SENDING"); } if(status==0) { if(cur_cmd.count==0) { //logf("data sent, now send csw"); send_csw(UMS_STATUS_GOOD); } else { send_and_read_next(); } } else { logf("Transfer failed %X",status); send_csw(UMS_STATUS_FAIL); /* TODO fill in cur_sense_data */ cur_sense_data.sense_key=0; cur_sense_data.information=0; cur_sense_data.asc=0; cur_sense_data.ascq=0; } break; } } /* called by usb_core_control_request() */ bool usb_storage_control_request(struct usb_ctrlrequest* req, unsigned char* dest) { bool handled = false; (void)dest; switch (req->bRequest) { case USB_BULK_GET_MAX_LUN: { #ifdef ONLY_EXPOSE_CARD_SLOT *tb.max_lun = 0; #else *tb.max_lun = NUM_VOLUMES - 1; #endif logf("ums: getmaxlun"); usb_drv_send(EP_CONTROL, tb.max_lun, 1); usb_drv_recv(EP_CONTROL, NULL, 0); /* ack */ handled = true; break; } case USB_BULK_RESET_REQUEST: logf("ums: bulk reset"); state = WAITING_FOR_COMMAND; /* UMS BOT 3.1 says The device shall preserve the value of its bulk data toggle bits and endpoint STALL conditions despite the Bulk-Only Mass Storage Reset. */ #if 0 usb_drv_reset_endpoint(ep_in, false); usb_drv_reset_endpoint(ep_out, true); #endif usb_drv_send(EP_CONTROL, NULL, 0); /* ack */ handled = true; break; } return handled; } static void send_and_read_next(void) { if(cur_cmd.last_result!=0) { /* The last read failed. */ send_csw(UMS_STATUS_FAIL); cur_sense_data.sense_key=SENSE_MEDIUM_ERROR; cur_sense_data.asc=ASC_READ_ERROR; cur_sense_data.ascq=0; return; } send_block_data(cur_cmd.data[cur_cmd.data_select], MIN(READ_BUFFER_SIZE,cur_cmd.count*SECTOR_SIZE)); /* Switch buffers for the next one */ cur_cmd.data_select=!cur_cmd.data_select; cur_cmd.sector+=(READ_BUFFER_SIZE/SECTOR_SIZE); cur_cmd.count-=MIN(cur_cmd.count,READ_BUFFER_SIZE/SECTOR_SIZE); if(cur_cmd.count!=0) { /* already read the next bit, so we can send it out immediately when the * current transfer completes. */ #ifdef USB_USE_RAMDISK memcpy(cur_cmd.data[cur_cmd.data_select], ramdisk_buffer + cur_cmd.sector*SECTOR_SIZE, MIN(READ_BUFFER_SIZE/SECTOR_SIZE, cur_cmd.count)*SECTOR_SIZE); #else cur_cmd.last_result = storage_read_sectors(cur_cmd.lun, cur_cmd.sector, MIN(READ_BUFFER_SIZE/SECTOR_SIZE, cur_cmd.count), cur_cmd.data[cur_cmd.data_select]); #endif } } /****************************************************************************/ static void handle_scsi(struct command_block_wrapper* cbw) { /* USB Mass Storage assumes LBA capability. TODO: support 48-bit LBA */ struct storage_info info; unsigned int length = cbw->data_transfer_length; unsigned int block_size = 0; unsigned int block_count = 0; bool lun_present=true; #ifdef ONLY_EXPOSE_CARD_SLOT unsigned char lun = cbw->lun+1; #else unsigned char lun = cbw->lun; #endif unsigned int block_size_mult = 1; storage_get_info(lun,&info); #ifdef USB_USE_RAMDISK block_size = SECTOR_SIZE; block_count = RAMDISK_SIZE; #else block_size=info.sector_size; block_count=info.num_sectors; #endif #ifdef HAVE_HOTSWAP if(storage_removable(lun) && !storage_present(lun)) { ejected[lun] = true; } #endif if(ejected[lun]) lun_present = false; #ifdef MAX_LOG_SECTOR_SIZE block_size_mult = disk_sector_multiplier; #endif cur_cmd.tag = cbw->tag; cur_cmd.lun = lun; cur_cmd.cur_cmd = cbw->command_block[0]; switch (cbw->command_block[0]) { case SCSI_TEST_UNIT_READY: logf("scsi test_unit_ready %d",lun); if(!usb_exclusive_storage()) { send_csw(UMS_STATUS_FAIL); cur_sense_data.sense_key=SENSE_NOT_READY; cur_sense_data.asc=ASC_MEDIUM_NOT_PRESENT; cur_sense_data.ascq=0; break; } if(lun_present) { send_csw(UMS_STATUS_GOOD); } else { send_csw(UMS_STATUS_FAIL); cur_sense_data.sense_key=SENSE_NOT_READY; cur_sense_data.asc=ASC_MEDIUM_NOT_PRESENT; cur_sense_data.ascq=0; } break; case SCSI_REPORT_LUNS: { logf("scsi report luns %d",lun); int allocation_length=0; int i; allocation_length|=(cbw->command_block[6]<<24); allocation_length|=(cbw->command_block[7]<<16); allocation_length|=(cbw->command_block[8]<<8); allocation_length|=(cbw->command_block[9]); memset(tb.lun_data,0,sizeof(struct report_lun_data)); tb.lun_data->lun_list_length=htobe32(8*NUM_VOLUMES); for(i=0;iluns[i][1]=1; else #endif tb.lun_data->luns[i][1]=0; } send_command_result(tb.lun_data, MIN(sizeof(struct report_lun_data), length)); break; } case SCSI_INQUIRY: logf("scsi inquiry %d",lun); fill_inquiry(IF_MV(lun)); length = MIN(length, cbw->command_block[4]); send_command_result(tb.inquiry, MIN(sizeof(struct inquiry_data), length)); break; case SCSI_REQUEST_SENSE: { tb.sense_data->ResponseCode=0x70;/*current error*/ tb.sense_data->Obsolete=0; tb.sense_data->fei_sensekey=cur_sense_data.sense_key&0x0f; tb.sense_data->Information=cur_sense_data.information; tb.sense_data->AdditionalSenseLength=10; tb.sense_data->CommandSpecificInformation=0; tb.sense_data->AdditionalSenseCode=cur_sense_data.asc; tb.sense_data->AdditionalSenseCodeQualifier=cur_sense_data.ascq; tb.sense_data->FieldReplaceableUnitCode=0; tb.sense_data->SKSV=0; tb.sense_data->SenseKeySpecific=0; logf("scsi request_sense %d",lun); send_command_result(tb.sense_data, MIN(sizeof(struct sense_data), length)); break; } case SCSI_MODE_SENSE_10: { if(!lun_present) { send_command_failed_result(); cur_sense_data.sense_key=SENSE_NOT_READY; cur_sense_data.asc=ASC_MEDIUM_NOT_PRESENT; cur_sense_data.ascq=0; break; } /*unsigned char pc = (cbw->command_block[2] & 0xc0) >>6;*/ unsigned char page_code = cbw->command_block[2] & 0x3f; logf("scsi mode_sense_10 %d %X",lun,page_code); switch(page_code) { case 0x3f: tb.ms_data_10->mode_data_length = htobe16(sizeof(struct mode_sense_data_10)-2); tb.ms_data_10->medium_type = 0; tb.ms_data_10->device_specific = 0; tb.ms_data_10->reserved = 0; tb.ms_data_10->longlba = 1; tb.ms_data_10->block_descriptor_length = htobe16(sizeof(struct mode_sense_bdesc_longlba)); memset(tb.ms_data_10->block_descriptor.reserved,0,4); memset(tb.ms_data_10->block_descriptor.num_blocks,0,8); tb.ms_data_10->block_descriptor.num_blocks[4] = ((block_count/block_size_mult) & 0xff000000)>>24; tb.ms_data_10->block_descriptor.num_blocks[5] = ((block_count/block_size_mult) & 0x00ff0000)>>16; tb.ms_data_10->block_descriptor.num_blocks[6] = ((block_count/block_size_mult) & 0x0000ff00)>>8; tb.ms_data_10->block_descriptor.num_blocks[7] = ((block_count/block_size_mult) & 0x000000ff); tb.ms_data_10->block_descriptor.block_size[0] = ((block_size*block_size_mult) & 0xff000000)>>24; tb.ms_data_10->block_descriptor.block_size[1] = ((block_size*block_size_mult) & 0x00ff0000)>>16; tb.ms_data_10->block_descriptor.block_size[2] = ((block_size*block_size_mult) & 0x0000ff00)>>8; tb.ms_data_10->block_descriptor.block_size[3] = ((block_size*block_size_mult) & 0x000000ff); send_command_result(tb.ms_data_10, MIN(sizeof(struct mode_sense_data_10), length)); break; default: send_command_failed_result(); cur_sense_data.sense_key=SENSE_ILLEGAL_REQUEST; cur_sense_data.asc=ASC_INVALID_FIELD_IN_CBD; cur_sense_data.ascq=0; break; } break; } case SCSI_MODE_SENSE_6: { if(!lun_present) { send_command_failed_result(); cur_sense_data.sense_key=SENSE_NOT_READY; cur_sense_data.asc=ASC_MEDIUM_NOT_PRESENT; cur_sense_data.ascq=0; break; } /*unsigned char pc = (cbw->command_block[2] & 0xc0) >>6;*/ unsigned char page_code = cbw->command_block[2] & 0x3f; logf("scsi mode_sense_6 %d %X",lun,page_code); switch(page_code) { case 0x3f: /* All supported pages. */ tb.ms_data_6->mode_data_length = sizeof(struct mode_sense_data_6)-1; tb.ms_data_6->medium_type = 0; tb.ms_data_6->device_specific = 0; tb.ms_data_6->block_descriptor_length = sizeof(struct mode_sense_bdesc_shortlba); tb.ms_data_6->block_descriptor.density_code = 0; tb.ms_data_6->block_descriptor.reserved = 0; if(block_count/block_size_mult > 0xffffff) { tb.ms_data_6->block_descriptor.num_blocks[0] = 0xff; tb.ms_data_6->block_descriptor.num_blocks[1] = 0xff; tb.ms_data_6->block_descriptor.num_blocks[2] = 0xff; } else { tb.ms_data_6->block_descriptor.num_blocks[0] = ((block_count/block_size_mult) & 0xff0000)>>16; tb.ms_data_6->block_descriptor.num_blocks[1] = ((block_count/block_size_mult) & 0x00ff00)>>8; tb.ms_data_6->block_descriptor.num_blocks[2] = ((block_count/block_size_mult) & 0x0000ff); } tb.ms_data_6->block_descriptor.block_size[0] = ((block_size*block_size_mult) & 0xff0000)>>16; tb.ms_data_6->block_descriptor.block_size[1] = ((block_size*block_size_mult) & 0x00ff00)>>8; tb.ms_data_6->block_descriptor.block_size[2] = ((block_size*block_size_mult) & 0x0000ff); send_command_result(tb.ms_data_6, MIN(sizeof(struct mode_sense_data_6), length)); break; default: send_command_failed_result(); cur_sense_data.sense_key=SENSE_ILLEGAL_REQUEST; cur_sense_data.asc=ASC_INVALID_FIELD_IN_CBD; cur_sense_data.ascq=0; break; } break; } case SCSI_START_STOP_UNIT: logf("scsi start_stop unit %d",lun); if((cbw->command_block[4] & 0xf0) == 0) /*load/eject bit is valid*/ { /* Process start and eject bits */ logf("scsi load/eject"); if((cbw->command_block[4] & 0x01) == 0) /* Don't start */ { if((cbw->command_block[4] & 0x02) != 0) /* eject */ { logf("scsi eject"); ejected[lun]=true; } } } send_csw(UMS_STATUS_GOOD); break; case SCSI_ALLOW_MEDIUM_REMOVAL: logf("scsi allow_medium_removal %d",lun); if((cbw->command_block[4] & 0x03) == 0) { locked[lun]=false; queue_broadcast(SYS_USB_LUN_LOCKED, (lun<<16)+0); } else { locked[lun]=true; queue_broadcast(SYS_USB_LUN_LOCKED, (lun<<16)+1); } send_csw(UMS_STATUS_GOOD); break; case SCSI_READ_FORMAT_CAPACITY: { logf("scsi read_format_capacity %d",lun); if(lun_present) { tb.format_capacity_data->following_length=htobe32(8); /* "block count" actually means "number of last block" */ tb.format_capacity_data->block_count = htobe32(block_count/block_size_mult - 1); tb.format_capacity_data->block_size = htobe32(block_size*block_size_mult); tb.format_capacity_data->block_size |= htobe32(SCSI_FORMAT_CAPACITY_FORMATTED_MEDIA); send_command_result(tb.format_capacity_data, MIN(sizeof(struct format_capacity), length)); } else { send_command_failed_result(); cur_sense_data.sense_key=SENSE_NOT_READY; cur_sense_data.asc=ASC_MEDIUM_NOT_PRESENT; cur_sense_data.ascq=0; } break; } case SCSI_READ_CAPACITY: { logf("scsi read_capacity %d",lun); if(lun_present) { /* "block count" actually means "number of last block" */ tb.capacity_data->block_count = htobe32(block_count/block_size_mult - 1); tb.capacity_data->block_size = htobe32(block_size*block_size_mult); send_command_result(tb.capacity_data, MIN(sizeof(struct capacity), length)); } else { send_command_failed_result(); cur_sense_data.sense_key=SENSE_NOT_READY; cur_sense_data.asc=ASC_MEDIUM_NOT_PRESENT; cur_sense_data.ascq=0; } break; } case SCSI_READ_10: logf("scsi read10 %d",lun); if(!lun_present) { send_command_failed_result(); cur_sense_data.sense_key=SENSE_NOT_READY; cur_sense_data.asc=ASC_MEDIUM_NOT_PRESENT; cur_sense_data.ascq=0; break; } cur_cmd.data[0] = tb.transfer_buffer; cur_cmd.data[1] = &tb.transfer_buffer[READ_BUFFER_SIZE]; cur_cmd.data_select=0; cur_cmd.sector = block_size_mult * (cbw->command_block[2] << 24 | cbw->command_block[3] << 16 | cbw->command_block[4] << 8 | cbw->command_block[5] ); cur_cmd.count = block_size_mult * (cbw->command_block[7] << 8 | cbw->command_block[8]); cur_cmd.orig_count = cur_cmd.count; //logf("scsi read %d %d", cur_cmd.sector, cur_cmd.count); if((cur_cmd.sector + cur_cmd.count) > block_count) { send_csw(UMS_STATUS_FAIL); cur_sense_data.sense_key=SENSE_ILLEGAL_REQUEST; cur_sense_data.asc=ASC_LBA_OUT_OF_RANGE; cur_sense_data.ascq=0; } else { #ifdef USB_USE_RAMDISK memcpy(cur_cmd.data[cur_cmd.data_select], ramdisk_buffer + cur_cmd.sector*SECTOR_SIZE, MIN(READ_BUFFER_SIZE/SECTOR_SIZE,cur_cmd.count)*SECTOR_SIZE); #else cur_cmd.last_result = storage_read_sectors(cur_cmd.lun, cur_cmd.sector, MIN(READ_BUFFER_SIZE/SECTOR_SIZE, cur_cmd.count), cur_cmd.data[cur_cmd.data_select]); #ifdef TOSHIBA_GIGABEAT_S if(cur_cmd.sector == 0) { fix_mbr(cur_cmd.data[cur_cmd.data_select]); } #endif #endif send_and_read_next(); } break; case SCSI_WRITE_10: logf("scsi write10 %d",lun); if(!lun_present) { send_csw(UMS_STATUS_FAIL); cur_sense_data.sense_key=SENSE_NOT_READY; cur_sense_data.asc=ASC_MEDIUM_NOT_PRESENT; cur_sense_data.ascq=0; break; } cur_cmd.data[0] = tb.transfer_buffer; cur_cmd.data[1] = &tb.transfer_buffer[WRITE_BUFFER_SIZE]; cur_cmd.data_select=0; cur_cmd.sector = block_size_mult * (cbw->command_block[2] << 24 | cbw->command_block[3] << 16 | cbw->command_block[4] << 8 | cbw->command_block[5] ); cur_cmd.count = block_size_mult * (cbw->command_block[7] << 8 | cbw->command_block[8]); cur_cmd.orig_count = cur_cmd.count; /* expect data */ if((cur_cmd.sector + cur_cmd.count) > block_count) { send_csw(UMS_STATUS_FAIL); cur_sense_data.sense_key=SENSE_ILLEGAL_REQUEST; cur_sense_data.asc=ASC_LBA_OUT_OF_RANGE; cur_sense_data.ascq=0; } else { receive_block_data(cur_cmd.data[0], MIN(WRITE_BUFFER_SIZE, cur_cmd.count*SECTOR_SIZE)); } break; default: logf("scsi unknown cmd %x",cbw->command_block[0x0]); send_csw(UMS_STATUS_FAIL); cur_sense_data.sense_key=SENSE_ILLEGAL_REQUEST; cur_sense_data.asc=ASC_INVALID_COMMAND; cur_sense_data.ascq=0; break; } } static void send_block_data(void *data,int size) { usb_drv_send_nonblocking(ep_in, data,size); state = SENDING_BLOCKS; } static void send_command_result(void *data,int size) { usb_drv_send_nonblocking(ep_in, data,size); state = SENDING_RESULT; } static void send_command_failed_result(void) { usb_drv_send_nonblocking(ep_in, NULL, 0); state = SENDING_FAILED_RESULT; } static void receive_block_data(void *data,int size) { usb_drv_recv(ep_out, data, size); state = RECEIVING_BLOCKS; } static void send_csw(int status) { tb.csw->signature = htole32(CSW_SIGNATURE); tb.csw->tag = cur_cmd.tag; tb.csw->data_residue = 0; tb.csw->status = status; usb_drv_send_nonblocking(ep_in, tb.csw, sizeof(struct command_status_wrapper)); state = SENDING_CSW; //logf("CSW: %X",status); /* Already start waiting for the next command */ usb_drv_recv(ep_out, cbw_buffer, 1024); if(status == UMS_STATUS_GOOD) { cur_sense_data.sense_key=0; cur_sense_data.information=0; cur_sense_data.asc=0; cur_sense_data.ascq=0; } } static void copy_padded(char *dest, char *src, int len) { int i=0; while(src[i]!=0 && iVendorId,info.vendor,sizeof(tb.inquiry->VendorId)); copy_padded(tb.inquiry->ProductId,info.product,sizeof(tb.inquiry->ProductId)); copy_padded(tb.inquiry->ProductRevisionLevel,info.revision,sizeof(tb.inquiry->ProductRevisionLevel)); tb.inquiry->DeviceType = DIRECT_ACCESS_DEVICE; tb.inquiry->AdditionalLength = 0x1f; memset(tb.inquiry->Reserved, 0, 3); tb.inquiry->Versions = 4; /* SPC-2 */ tb.inquiry->Format = 2; /* SPC-2/3 inquiry format */ #ifdef TOSHIBA_GIGABEAT_S tb.inquiry->DeviceTypeModifier = 0; #else tb.inquiry->DeviceTypeModifier = DEVICE_REMOVABLE; #endif }