/*************************************************************************** * Copyright (C) 2007-2008 by unsik Kim * * * * 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 program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the * * Free Software Foundation, Inc., * * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. * ***************************************************************************/ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include #include #include #include #include "command.h" #include "log.h" #include "target.h" #include "time_support.h" #include "fileio.h" #include "mflash.h" static int s3c2440_set_gpio_to_output (mflash_gpio_num_t gpio); static int s3c2440_set_gpio_output_val (mflash_gpio_num_t gpio, u8 val); static int pxa270_set_gpio_to_output (mflash_gpio_num_t gpio); static int pxa270_set_gpio_output_val (mflash_gpio_num_t gpio, u8 val); static command_t *mflash_cmd; static mflash_bank_t *mflash_bank; static mflash_gpio_drv_t pxa270_gpio = { .name = "pxa270", .set_gpio_to_output = pxa270_set_gpio_to_output, .set_gpio_output_val = pxa270_set_gpio_output_val }; static mflash_gpio_drv_t s3c2440_gpio = { .name = "s3c2440", .set_gpio_to_output = s3c2440_set_gpio_to_output, .set_gpio_output_val = s3c2440_set_gpio_output_val }; static mflash_gpio_drv_t *mflash_gpio[] = { &pxa270_gpio, &s3c2440_gpio, NULL }; #define PXA270_GAFR0_L 0x40E00054 #define PXA270_GAFR3_U 0x40E00070 #define PXA270_GAFR3_U_RESERVED_BITS 0xfffc0000u #define PXA270_GPDR0 0x40E0000C #define PXA270_GPDR3 0x40E0010C #define PXA270_GPDR3_RESERVED_BITS 0xfe000000u #define PXA270_GPSR0 0x40E00018 #define PXA270_GPCR0 0x40E00024 static int pxa270_set_gpio_to_output (mflash_gpio_num_t gpio) { u32 addr, value, mask; target_t *target = mflash_bank->target; int ret; // remove alternate function. mask = 0x3u << (gpio.num & 0xF)*2; addr = PXA270_GAFR0_L + (gpio.num >> 4) * 4; if ((ret = target_read_u32(target, addr, &value)) != ERROR_OK) return ret; value &= ~mask; if (addr == PXA270_GAFR3_U) value &= ~PXA270_GAFR3_U_RESERVED_BITS; if ((ret = target_write_u32(target, addr, value)) != ERROR_OK) return ret; // set direction to output mask = 0x1u << (gpio.num & 0x1F); addr = PXA270_GPDR0 + (gpio.num >> 5) * 4; if ((ret = target_read_u32(target, addr, &value)) != ERROR_OK) return ret; value |= mask; if (addr == PXA270_GPDR3) value &= ~PXA270_GPDR3_RESERVED_BITS; ret = target_write_u32(target, addr, value); return ret; } static int pxa270_set_gpio_output_val (mflash_gpio_num_t gpio, u8 val) { u32 addr, value, mask; target_t *target = mflash_bank->target; int ret; mask = 0x1u << (gpio.num & 0x1F); if (val) { addr = PXA270_GPSR0 + (gpio.num >> 5) * 4; } else { addr = PXA270_GPCR0 + (gpio.num >> 5) * 4; } if ((ret = target_read_u32(target, addr, &value)) != ERROR_OK) return ret; value |= mask; ret = target_write_u32(target, addr, value); return ret; } #define S3C2440_GPACON 0x56000000 #define S3C2440_GPADAT 0x56000004 #define S3C2440_GPJCON 0x560000d0 #define S3C2440_GPJDAT 0x560000d4 static int s3c2440_set_gpio_to_output (mflash_gpio_num_t gpio) { u32 data, mask, gpio_con; target_t *target = mflash_bank->target; int ret; if (gpio.port[0] >= 'a' && gpio.port[0] <= 'h') { gpio_con = S3C2440_GPACON + (gpio.port[0] - 'a') * 0x10; } else if (gpio.port[0] == 'j') { gpio_con = S3C2440_GPJCON; } else { LOG_ERROR("invalid port %d%s", gpio.num, gpio.port); return ERROR_INVALID_ARGUMENTS; } ret = target_read_u32(target, gpio_con, &data); if (ret == ERROR_OK) { if (gpio.port[0] == 'a') { mask = 1 << gpio.num; data &= ~mask; } else { mask = 3 << gpio.num * 2; data &= ~mask; data |= (1 << gpio.num * 2); } ret = target_write_u32(target, gpio_con, data); } return ret; } static int s3c2440_set_gpio_output_val (mflash_gpio_num_t gpio, u8 val) { u32 data, mask, gpio_dat; target_t *target = mflash_bank->target; int ret; if (gpio.port[0] >= 'a' && gpio.port[0] <= 'h') { gpio_dat = S3C2440_GPADAT + (gpio.port[0] - 'a') * 0x10; } else if (gpio.port[0] == 'j') { gpio_dat = S3C2440_GPJDAT; } else { LOG_ERROR("invalid port %d%s", gpio.num, gpio.port); return ERROR_INVALID_ARGUMENTS; } ret = target_read_u32(target, gpio_dat, &data); if (ret == ERROR_OK) { mask = 1 << gpio.num; if (val) data |= mask; else data &= ~mask; ret = target_write_u32(target, gpio_dat, data); } return ret; } static int mflash_rst(u8 level) { return mflash_bank->gpio_drv->set_gpio_output_val(mflash_bank->rst_pin, level); } static int mg_dump_task_reg (void) { target_t *target = mflash_bank->target; u32 address = mflash_bank->base + MG_REG_OFFSET + MG_REG_ERROR; u8 value, i; char *reg_name[9] = { "error ", "sector count ", "sector num (LBA 7- 0) ", "cyl. low (LBA 15- 8) ", "cyl. high (LBA 23-16) ", "drv/head ", "status ", "dev control ", "burst control " }; for (i = 0; i < 9; i++) { target_read_u8(target, address + i * 2, &value); LOG_INFO("%s : 0x%2.2x", reg_name[i], value); } return ERROR_OK; } static int mflash_init_gpio (void) { mflash_gpio_drv_t *gpio_drv = mflash_bank->gpio_drv; gpio_drv->set_gpio_to_output(mflash_bank->rst_pin); gpio_drv->set_gpio_output_val(mflash_bank->rst_pin, 1); if (mflash_bank->wp_pin.num != -1) { gpio_drv->set_gpio_to_output(mflash_bank->wp_pin); gpio_drv->set_gpio_output_val(mflash_bank->wp_pin, 1); } if (mflash_bank->dpd_pin.num != -1) { gpio_drv->set_gpio_to_output(mflash_bank->dpd_pin); gpio_drv->set_gpio_output_val(mflash_bank->dpd_pin, 1); } return ERROR_OK; } static int mg_dsk_wait(mg_io_type_wait wait, u32 time) { u8 status, error; target_t *target = mflash_bank->target; u32 mg_task_reg = mflash_bank->base + MG_REG_OFFSET; duration_t duration; long long t=0; duration_start_measure(&duration); while (time) { target_read_u8(target, mg_task_reg + MG_REG_STATUS, &status); if (status & mg_io_rbit_status_busy) { if (wait == mg_io_wait_bsy) return ERROR_OK; } else { switch(wait) { case mg_io_wait_not_bsy: return ERROR_OK; case mg_io_wait_rdy_noerr: if (status & mg_io_rbit_status_ready) return ERROR_OK; break; case mg_io_wait_drq_noerr: if (status & mg_io_rbit_status_data_req) return ERROR_OK; break; default: break; } // Now we check the error condition! if (status & mg_io_rbit_status_error) { target_read_u8(target, mg_task_reg + MG_REG_ERROR, &error); if (error & mg_io_rbit_err_bad_sect_num) { LOG_ERROR("sector not found"); return ERROR_FAIL; } else if (error & (mg_io_rbit_err_bad_block | mg_io_rbit_err_uncorrectable)) { LOG_ERROR("bad block"); return ERROR_FAIL; } else { LOG_ERROR("disk operation fail"); return ERROR_FAIL; } } switch (wait) { case mg_io_wait_rdy: if (status & mg_io_rbit_status_ready) return ERROR_OK; case mg_io_wait_drq: if (status & mg_io_rbit_status_data_req) return ERROR_OK; default: break; } } duration_stop_measure(&duration, NULL); t=duration.duration.tv_usec/1000; t+=duration.duration.tv_sec*1000; if (t > time) break; } LOG_ERROR("timeout occured"); return ERROR_FAIL; } static int mg_dsk_srst(u8 on) { target_t *target = mflash_bank->target; u32 mg_task_reg = mflash_bank->base + MG_REG_OFFSET; u8 value; int ret; if ((ret = target_read_u8(target, mg_task_reg + MG_REG_DRV_CTRL, &value)) != ERROR_OK) return ret; if(on) { value |= (mg_io_rbit_devc_srst); } else { value &= ~mg_io_rbit_devc_srst; } ret = target_write_u8(target, mg_task_reg + MG_REG_DRV_CTRL, value); return ret; } static int mg_dsk_io_cmd(u32 sect_num, u32 cnt, u8 cmd) { target_t *target = mflash_bank->target; u32 mg_task_reg = mflash_bank->base + MG_REG_OFFSET; u8 value; if (mg_dsk_wait(mg_io_wait_rdy_noerr, MG_OEM_DISK_WAIT_TIME_NORMAL) != ERROR_OK) return ERROR_FAIL; value = mg_io_rval_dev_drv_master | mg_io_rval_dev_lba_mode |((sect_num >> 24) & 0xf); target_write_u8(target, mg_task_reg + MG_REG_DRV_HEAD, value); target_write_u8(target, mg_task_reg + MG_REG_SECT_CNT, (u8)cnt); target_write_u8(target, mg_task_reg + MG_REG_SECT_NUM, (u8)sect_num); target_write_u8(target, mg_task_reg + MG_REG_CYL_LOW, (u8)(sect_num >> 8)); target_write_u8(target, mg_task_reg + MG_REG_CYL_HIGH, (u8)(sect_num >> 16)); target_write_u8(target, mg_task_reg + MG_REG_COMMAND, cmd); return ERROR_OK; } static int mg_dsk_drv_info(void) { target_t *target = mflash_bank->target; u32 mg_buff = mflash_bank->base + MG_BUFFER_OFFSET; if ( mg_dsk_io_cmd(0, 1, mg_io_cmd_identify) != ERROR_OK) return ERROR_FAIL; if ( mg_dsk_wait(mg_io_wait_drq, MG_OEM_DISK_WAIT_TIME_NORMAL) != ERROR_OK) return ERROR_FAIL; LOG_INFO("read drive info."); if (! mflash_bank->drv_info) mflash_bank->drv_info = malloc(sizeof(mg_drv_info_t)); target->type->read_memory(target, mg_buff, 2, sizeof(mg_io_type_drv_info) >> 1, (u8 *)&mflash_bank->drv_info->drv_id); mflash_bank->drv_info->tot_sects = (u32)(mflash_bank->drv_info->drv_id.total_user_addressable_sectors_hi << 16) + mflash_bank->drv_info->drv_id.total_user_addressable_sectors_lo; target_write_u8(target, mflash_bank->base + MG_REG_OFFSET + MG_REG_COMMAND, mg_io_cmd_confirm_read); return ERROR_OK; } static int mg_mflash_probe(void) { mflash_bank->proved = 0; mflash_init_gpio(); LOG_INFO("reset mflash"); mflash_rst(0); if (mg_dsk_wait(mg_io_wait_bsy, MG_OEM_DISK_WAIT_TIME_LONG) != ERROR_OK) return ERROR_FAIL; mflash_rst(1); if (mg_dsk_wait(mg_io_wait_not_bsy, MG_OEM_DISK_WAIT_TIME_LONG) != ERROR_OK) return ERROR_FAIL; mg_dsk_srst(1); if (mg_dsk_wait(mg_io_wait_bsy, MG_OEM_DISK_WAIT_TIME_LONG) != ERROR_OK) return ERROR_FAIL; mg_dsk_srst(0); if (mg_dsk_wait(mg_io_wait_not_bsy, MG_OEM_DISK_WAIT_TIME_LONG) != ERROR_OK) return ERROR_FAIL; if (mg_dsk_drv_info() != ERROR_OK) return ERROR_FAIL; mflash_bank->proved = 1; return ERROR_OK; } static int mflash_probe_command(struct command_context_s *cmd_ctx, char *cmd, char **args, int argc) { int ret; ret = mg_mflash_probe(); if (ret == ERROR_OK) { command_print(cmd_ctx, "mflash (total %u sectors) found at 0x%8.8x", mflash_bank->drv_info->tot_sects, mflash_bank->base ); } return ret; } static int mg_mflash_do_read_sects(void *buff, u32 sect_num, u32 sect_cnt) { u32 i, address; int ret; target_t *target = mflash_bank->target; u8 *buff_ptr = buff; duration_t duration; if ( mg_dsk_io_cmd(sect_num, sect_cnt, mg_io_cmd_read) != ERROR_OK ) return ERROR_FAIL; address = mflash_bank->base + MG_BUFFER_OFFSET; duration_start_measure(&duration); for (i = 0; i < sect_cnt; i++) { mg_dsk_wait(mg_io_wait_drq, MG_OEM_DISK_WAIT_TIME_NORMAL); target->type->read_memory(target, address, 2, MG_MFLASH_SECTOR_SIZE / 2, buff_ptr); buff_ptr += MG_MFLASH_SECTOR_SIZE; target_write_u8(target, mflash_bank->base + MG_REG_OFFSET + MG_REG_COMMAND, mg_io_cmd_confirm_read); LOG_DEBUG("%u (0x%8.8x) sector read", sect_num + i, (sect_num + i) * MG_MFLASH_SECTOR_SIZE); duration_stop_measure(&duration, NULL); if ((duration.duration.tv_sec * 1000 + duration.duration.tv_usec / 1000) > 3000) { LOG_INFO("read %u'th sectors", sect_num + i); duration_start_measure(&duration); } } ret = mg_dsk_wait(mg_io_wait_rdy, MG_OEM_DISK_WAIT_TIME_NORMAL); return ret; } static int mg_mflash_read_sects(void *buff, u32 sect_num, u32 sect_cnt) { u32 quotient, residue, i; u8 *buff_ptr = buff; quotient = sect_cnt >> 8; residue = sect_cnt % 256; for (i = 0; i < quotient; i++) { LOG_DEBUG("sect num : %u buff : 0x%8.8x", sect_num, (u32)buff_ptr); mg_mflash_do_read_sects(buff_ptr, sect_num, 256); sect_num += 256; buff_ptr += 256 * MG_MFLASH_SECTOR_SIZE; } if (residue) { LOG_DEBUG("sect num : %u buff : %8.8x", sect_num, (u32)buff_ptr); mg_mflash_do_read_sects(buff_ptr, sect_num, residue); } return ERROR_OK; } static int mg_mflash_do_write_sects(void *buff, u32 sect_num, u32 sect_cnt) { u32 i, address; int ret; target_t *target = mflash_bank->target; u8 *buff_ptr = buff; duration_t duration; if ( mg_dsk_io_cmd(sect_num, sect_cnt, mg_io_cmd_write) != ERROR_OK ) { LOG_ERROR("mg_io_cmd_write fail"); return ERROR_FAIL; } address = mflash_bank->base + MG_BUFFER_OFFSET; duration_start_measure(&duration); for (i = 0; i < sect_cnt; i++) { ret = mg_dsk_wait(mg_io_wait_drq, MG_OEM_DISK_WAIT_TIME_NORMAL); if (ret != ERROR_OK) LOG_ERROR("mg_io_wait_drq time out"); ret = target->type->write_memory(target, address, 2, MG_MFLASH_SECTOR_SIZE / 2, buff_ptr); if (ret != ERROR_OK) LOG_ERROR("mem write error"); buff_ptr += MG_MFLASH_SECTOR_SIZE; ret = target_write_u8(target, mflash_bank->base + MG_REG_OFFSET + MG_REG_COMMAND, mg_io_cmd_confirm_write); if (ret != ERROR_OK) LOG_ERROR("mg_io_cmd_confirm_write error"); LOG_DEBUG("%u (0x%8.8x) sector write", sect_num + i, (sect_num + i) * MG_MFLASH_SECTOR_SIZE); duration_stop_measure(&duration, NULL); if ((duration.duration.tv_sec * 1000 + duration.duration.tv_usec / 1000) > 3000) { LOG_INFO("wrote %u'th sectors", sect_num + i); duration_start_measure(&duration); } } ret = mg_dsk_wait(mg_io_wait_rdy, MG_OEM_DISK_WAIT_TIME_NORMAL); return ret; } static int mg_mflash_write_sects(void *buff, u32 sect_num, u32 sect_cnt) { u32 quotient, residue, i; u8 *buff_ptr = buff; quotient = sect_cnt >> 8; residue = sect_cnt % 256; for (i = 0; i < quotient; i++) { LOG_DEBUG("sect num : %u buff : %8.8x", sect_num, (u32)buff_ptr); mg_mflash_do_write_sects(buff_ptr, sect_num, 256); sect_num += 256; buff_ptr += 256 * MG_MFLASH_SECTOR_SIZE; } if (residue) { LOG_DEBUG("sect num : %u buff : %8.8x", sect_num, (u32)buff_ptr); mg_mflash_do_write_sects(buff_ptr, sect_num, residue); } return ERROR_OK; } static int mg_mflash_read (u32 addr, u8 *buff, u32 len) { u8 *sect_buff, *buff_ptr = buff; u32 cur_addr, next_sec_addr, end_addr, cnt, sect_num; cnt = 0; cur_addr = addr; end_addr = addr + len; sect_buff = malloc(MG_MFLASH_SECTOR_SIZE); if (cur_addr & MG_MFLASH_SECTOR_SIZE_MASK) { next_sec_addr = (cur_addr + MG_MFLASH_SECTOR_SIZE) & ~MG_MFLASH_SECTOR_SIZE_MASK; sect_num = cur_addr >> MG_MFLASH_SECTOR_SIZE_SHIFT; mg_mflash_read_sects(sect_buff, sect_num, 1); if (end_addr < next_sec_addr) { memcpy(buff_ptr, sect_buff + (cur_addr & MG_MFLASH_SECTOR_SIZE_MASK), end_addr - cur_addr); LOG_DEBUG("copies %u byte from sector offset 0x%8.8x", end_addr - cur_addr, cur_addr); cur_addr = end_addr; } else { memcpy(buff_ptr, sect_buff + (cur_addr & MG_MFLASH_SECTOR_SIZE_MASK), next_sec_addr - cur_addr); LOG_DEBUG("copies %u byte from sector offset 0x%8.8x", next_sec_addr - cur_addr, cur_addr); buff_ptr += (next_sec_addr - cur_addr); cur_addr = next_sec_addr; } } if (cur_addr < end_addr) { sect_num = cur_addr >> MG_MFLASH_SECTOR_SIZE_SHIFT; next_sec_addr = cur_addr + MG_MFLASH_SECTOR_SIZE; while (next_sec_addr <= end_addr) { cnt++; next_sec_addr += MG_MFLASH_SECTOR_SIZE; } if (cnt) mg_mflash_read_sects(buff_ptr, sect_num, cnt); buff_ptr += cnt * MG_MFLASH_SECTOR_SIZE; cur_addr += cnt * MG_MFLASH_SECTOR_SIZE; if (cur_addr < end_addr) { sect_num = cur_addr >> MG_MFLASH_SECTOR_SIZE_SHIFT; mg_mflash_read_sects(sect_buff, sect_num, 1); memcpy(buff_ptr, sect_buff, end_addr - cur_addr); LOG_DEBUG("copies %u byte", end_addr - cur_addr); } } free(sect_buff); return ERROR_OK; } static int mg_mflash_write(u32 addr, u8 *buff, u32 len) { u8 *sect_buff, *buff_ptr = buff; u32 cur_addr, next_sec_addr, end_addr, cnt, sect_num; cnt = 0; cur_addr = addr; end_addr = addr + len; sect_buff = malloc(MG_MFLASH_SECTOR_SIZE); if (cur_addr & MG_MFLASH_SECTOR_SIZE_MASK) { next_sec_addr = (cur_addr + MG_MFLASH_SECTOR_SIZE) & ~MG_MFLASH_SECTOR_SIZE_MASK; sect_num = cur_addr >> MG_MFLASH_SECTOR_SIZE_SHIFT; mg_mflash_read_sects(sect_buff, sect_num, 1); if (end_addr < next_sec_addr) { memcpy(sect_buff + (cur_addr & MG_MFLASH_SECTOR_SIZE_MASK), buff_ptr, end_addr - cur_addr); LOG_DEBUG("copies %u byte to sector offset 0x%8.8x", end_addr - cur_addr, cur_addr); cur_addr = end_addr; } else { memcpy(sect_buff + (cur_addr & MG_MFLASH_SECTOR_SIZE_MASK), buff_ptr, next_sec_addr - cur_addr); LOG_DEBUG("copies %u byte to sector offset 0x%8.8x", next_sec_addr - cur_addr, cur_addr); buff_ptr += (next_sec_addr - cur_addr); cur_addr = next_sec_addr; } mg_mflash_write_sects(sect_buff, sect_num, 1); } if (cur_addr < end_addr) { sect_num = cur_addr >> MG_MFLASH_SECTOR_SIZE_SHIFT; next_sec_addr = cur_addr + MG_MFLASH_SECTOR_SIZE; while (next_sec_addr <= end_addr) { cnt++; next_sec_addr += MG_MFLASH_SECTOR_SIZE; } if (cnt) mg_mflash_write_sects(buff_ptr, sect_num, cnt); buff_ptr += cnt * MG_MFLASH_SECTOR_SIZE; cur_addr += cnt * MG_MFLASH_SECTOR_SIZE; if (cur_addr < end_addr) { sect_num = cur_addr >> MG_MFLASH_SECTOR_SIZE_SHIFT; mg_mflash_read_sects(sect_buff, sect_num, 1); memcpy(sect_buff, buff_ptr, end_addr - cur_addr); LOG_DEBUG("copies %u byte", end_addr - cur_addr); mg_mflash_write_sects(sect_buff, sect_num, 1); } } free(sect_buff); return ERROR_OK; } static int mflash_write_command(struct command_context_s *cmd_ctx, char *cmd, char **args, int argc) { u32 address, buf_cnt; u8 *buffer; // TODO : multi-bank support, large file support fileio_t fileio; duration_t duration; char *duration_text; int ret; if (argc != 3) { return ERROR_COMMAND_SYNTAX_ERROR; } address = strtoul(args[2], NULL, 0); if (! mflash_bank->proved ) { mg_mflash_probe(); } if (fileio_open(&fileio, args[1], FILEIO_READ, FILEIO_BINARY) != ERROR_OK) { return ERROR_FAIL; } buffer = malloc(fileio.size); if (fileio_read(&fileio, fileio.size, buffer, &buf_cnt) != ERROR_OK) { free(buffer); fileio_close(&fileio); return ERROR_FAIL; } duration_start_measure(&duration); ret = mg_mflash_write(address, buffer, (u32)fileio.size); duration_stop_measure(&duration, &duration_text); command_print(cmd_ctx, "wrote %lli byte from file %s in %s (%f kB/s)", fileio.size, args[1], duration_text, (float)fileio.size / 1024.0 / ((float)duration.duration.tv_sec + ((float)duration.duration.tv_usec / 1000000.0))); free(duration_text); fileio_close(&fileio); free(buffer); return ERROR_OK; } static int mflash_dump_command(struct command_context_s *cmd_ctx, char *cmd, char **args, int argc) { u32 address, size_written, size; u8 *buffer; // TODO : multi-bank support fileio_t fileio; duration_t duration; char *duration_text; if (argc != 4) { return ERROR_COMMAND_SYNTAX_ERROR; } address = strtoul(args[2], NULL, 0); size = strtoul(args[3], NULL, 0); if (! mflash_bank->proved ) { mg_mflash_probe(); } if (fileio_open(&fileio, args[1], FILEIO_WRITE, FILEIO_BINARY) != ERROR_OK) { return ERROR_FAIL; } buffer = malloc(size); duration_start_measure(&duration); mg_mflash_read(address, buffer, size); duration_stop_measure(&duration, &duration_text); fileio_write(&fileio, size, buffer, &size_written); command_print(cmd_ctx, "dump image (address 0x%8.8x size %u) to file %s in %s (%f kB/s)", address, size, args[1], duration_text, (float)size / 1024.0 / ((float)duration.duration.tv_sec + ((float)duration.duration.tv_usec / 1000000.0))); free(duration_text); fileio_close(&fileio); free(buffer); return ERROR_OK; } int mflash_init_drivers(struct command_context_s *cmd_ctx) { if (mflash_bank) { register_command(cmd_ctx, mflash_cmd, "probe", mflash_probe_command, COMMAND_EXEC, NULL); register_command(cmd_ctx, mflash_cmd, "write", mflash_write_command, COMMAND_EXEC, "mflash write
"); register_command(cmd_ctx, mflash_cmd, "dump", mflash_dump_command, COMMAND_EXEC, "mflash dump
"); } return ERROR_OK; } static int mflash_bank_command(struct command_context_s *cmd_ctx, char *cmd, char **args, int argc) { target_t *target; char *str; int i; if (argc < 8) { return ERROR_COMMAND_SYNTAX_ERROR; } if ((target = get_target_by_num(strtoul(args[7], NULL, 0))) == NULL) { LOG_ERROR("target %lu not defined", strtoul(args[7], NULL, 0)); return ERROR_FAIL; } mflash_bank = calloc(sizeof(mflash_bank_t), 1); mflash_bank->base = strtoul(args[1], NULL, 0); mflash_bank->chip_width = strtoul(args[2], NULL, 0); mflash_bank->bus_width = strtoul(args[3], NULL, 0); mflash_bank->rst_pin.num = strtoul(args[4], &str, 0); if (*str) mflash_bank->rst_pin.port[0] = (u16)tolower(str[0]); mflash_bank->wp_pin.num = strtol(args[5], &str, 0); if (*str) mflash_bank->wp_pin.port[0] = (u16)tolower(str[0]); mflash_bank->dpd_pin.num = strtol(args[6], &str, 0); if (*str) mflash_bank->dpd_pin.port[0] = (u16)tolower(str[0]); mflash_bank->target = target; for (i = 0; mflash_gpio[i] ; i++) { if (! strcmp(mflash_gpio[i]->name, args[0])) { mflash_bank->gpio_drv = mflash_gpio[i]; } } if (! mflash_bank->gpio_drv) { LOG_ERROR("%s is unsupported soc", args[0]); return ERROR_INVALID_ARGUMENTS; } return ERROR_OK; } int mflash_register_commands(struct command_context_s *cmd_ctx) { mflash_cmd = register_command(cmd_ctx, NULL, "mflash", NULL, COMMAND_ANY, NULL); register_command(cmd_ctx, mflash_cmd, "bank", mflash_bank_command, COMMAND_CONFIG, "mflash bank "); return ERROR_OK; }