/* * Copyright (C) 2010 Freescale Semiconductor, Inc. * * Copyright 2008 - 2009 (C) Wind River Systems, Inc. * Tom Rix * * 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 * * Part of the rx_handler were copied from the Android project. * Specifically rx command parsing in the usb_rx_data_complete * function of the file bootable/bootloader/legacy/usbloader/usbloader.c * * The logical naming of flash comes from the Android project * Thse structures and functions that look like fastboot_flash_* * They come from bootable/bootloader/legacy/libboot/flash.c * * This is their Copyright: * * Copyright (C) 2008 The Android Open Source Project * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include #include #include #include #include #include #ifdef CONFIG_FASTBOOT /* Use do_reset for fastboot's 'reboot' command */ extern int do_reset(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]); /* Use do_nand for fastboot's flash commands */ #if defined(CONFIG_FASTBOOT_STORAGE_NAND) extern int do_nand(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]); #elif defined(CONFIG_FASTBOOT_STORAGE_EMMC) extern int do_mmcops(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]); extern env_t *env_ptr; #endif /* Use do_setenv and do_saveenv to permenantly save data */ int do_saveenv(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]); int do_setenv(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]); /* Use do_bootm and do_go for fastboot's 'boot' command */ int do_bootm(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]); int do_go(cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]); /* Forward decl */ static int tx_handler(void); static int rx_handler(const unsigned char *buffer, unsigned int buffer_size); static void reset_handler(void); static struct cmd_fastboot_interface interface = { .rx_handler = rx_handler, .reset_handler = reset_handler, .product_name = NULL, .serial_no = NULL, .nand_block_size = 0, .transfer_buffer = (unsigned char *)0xffffffff, .transfer_buffer_size = 0, }; static unsigned int download_size; static unsigned int download_bytes; static unsigned int download_bytes_unpadded; static unsigned int download_error; static unsigned int continue_booting; static unsigned int upload_size; static unsigned int upload_bytes; static unsigned int upload_error; static unsigned int mmc_controller_no; /* To support the Android-style naming of flash */ #define MAX_PTN 16 #define MMC_BLOCK_SIZE 512 static fastboot_ptentry ptable[MAX_PTN]; static unsigned int pcount; static int static_pcount = -1; static void set_env(char *var, char *val) { char *setenv[4] = { "setenv", NULL, NULL, NULL, }; setenv[1] = var; setenv[2] = val; do_setenv(NULL, 0, 3, setenv); } #ifdef CONFIG_FASTBOOT_STORAGE_NAND static void save_env(struct fastboot_ptentry *ptn, char *var, char *val) { char start[32], length[32]; char ecc_type[32]; char *lock[5] = { "nand", "lock", NULL, NULL, NULL, }; char *unlock[5] = { "nand", "unlock", NULL, NULL, NULL, }; char *ecc[4] = { "nand", "ecc", NULL, NULL, }; char *saveenv[2] = { "setenv", NULL, }; lock[2] = unlock[2] = start; lock[3] = unlock[3] = length; set_env(var, val); /* Some flashing requires the nand's ecc to be set */ ecc[2] = ecc_type; if ((ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_HW_ECC) && (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_SW_ECC)) { /* Both can not be true */ printf("Warning can not do hw and sw ecc for partition '%s'\n", ptn->name); printf("Ignoring these flags\n"); } else if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_HW_ECC) { sprintf(ecc_type, "hw"); do_nand(NULL, 0, 3, ecc); } else if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_SW_ECC) { sprintf(ecc_type, "sw"); do_nand(NULL, 0, 3, ecc); } sprintf(start, "0x%x", ptn->start); sprintf(length, "0x%x", ptn->length); /* This could be a problem is there is an outstanding lock */ do_nand(NULL, 0, 4, unlock); do_saveenv(NULL, 0, 1, saveenv); do_nand(NULL, 0, 4, lock); } static void save_block_values(struct fastboot_ptentry *ptn, unsigned int offset, unsigned int size) { struct fastboot_ptentry *env_ptn; char var[64], val[32]; char start[32], length[32]; char ecc_type[32]; char *lock[5] = { "nand", "lock", NULL, NULL, NULL, }; char *unlock[5] = { "nand", "unlock", NULL, NULL, NULL, }; char *ecc[4] = { "nand", "ecc", NULL, NULL, }; char *setenv[4] = { "setenv", NULL, NULL, NULL, }; char *saveenv[2] = { "setenv", NULL, }; setenv[1] = var; setenv[2] = val; lock[2] = unlock[2] = start; lock[3] = unlock[3] = length; printf("saving it..\n"); if (size == 0) { /* The error case, where the variables are being unset */ sprintf(var, "%s_nand_offset", ptn->name); sprintf(val, ""); do_setenv(NULL, 0, 3, setenv); sprintf(var, "%s_nand_size", ptn->name); sprintf(val, ""); do_setenv(NULL, 0, 3, setenv); } else { /* Normal case */ sprintf(var, "%s_nand_offset", ptn->name); sprintf(val, "0x%x", offset); printf("%s %s %s\n", setenv[0], setenv[1], setenv[2]); do_setenv(NULL, 0, 3, setenv); sprintf(var, "%s_nand_size", ptn->name); sprintf(val, "0x%x", size); printf("%s %s %s\n", setenv[0], setenv[1], setenv[2]); do_setenv(NULL, 0, 3, setenv); } /* Warning : The environment is assumed to be in a partition named 'enviroment'. It is very possible that your board stores the enviroment someplace else. */ env_ptn = fastboot_flash_find_ptn("environment"); if (env_ptn) { /* Some flashing requires the nand's ecc to be set */ ecc[2] = ecc_type; if ((env_ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_HW_ECC) && (env_ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_SW_ECC)) { /* Both can not be true */ printf("Warning can not do hw and sw ecc for \ partition '%s'\n", ptn->name); printf("Ignoring these flags\n"); } else if (env_ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_HW_ECC) { sprintf(ecc_type, "hw"); do_nand(NULL, 0, 3, ecc); } else if (env_ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_SW_ECC) { sprintf(ecc_type, "sw"); do_nand(NULL, 0, 3, ecc); } sprintf(start, "0x%x", env_ptn->start); sprintf(length, "0x%x", env_ptn->length); /* This could be a problem is there is an outstanding lock */ do_nand(NULL, 0, 4, unlock); } do_saveenv(NULL, 0, 1, saveenv); if (env_ptn) do_nand(NULL, 0, 4, lock); } #else /* will do later */ #endif static void reset_handler () { /* If there was a download going on, bail */ download_size = 0; download_bytes = 0; download_bytes_unpadded = 0; download_error = 0; continue_booting = 0; upload_size = 0; upload_bytes = 0; upload_error = 0; } #ifdef CONFIG_FASTBOOT_STORAGE_NAND /* When save = 0, just parse. The input is unchanged When save = 1, parse and do the save. The input is changed */ static int parse_env(void *ptn, char *err_string, int save, int debug) { int ret = 1; unsigned int sets = 0; unsigned int comment_start = 0; char *var = NULL; char *var_end = NULL; char *val = NULL; char *val_end = NULL; unsigned int i; char *buff = (char *)interface.transfer_buffer; unsigned int size = download_bytes_unpadded; /* The input does not have to be null terminated. This will cause a problem in the corner case where the last line does not have a new line. Put a null after the end of the input. WARNING : Input buffer is assumed to be bigger than the size of the input */ if (save) buff[size] = 0; for (i = 0; i < size; i++) { if (NULL == var) { /* * Check for comments, comment ok only on * mostly empty lines */ if (buff[i] == '#') comment_start = 1; if (comment_start) { if ((buff[i] == '\r') || (buff[i] == '\n')) { comment_start = 0; } } else { if (!((buff[i] == ' ') || (buff[i] == '\t') || (buff[i] == '\r') || (buff[i] == '\n'))) { /* * Normal whitespace before the * variable */ var = &buff[i]; } } } else if (((NULL == var_end) || (NULL == val)) && ((buff[i] == '\r') || (buff[i] == '\n'))) { /* This is the case when a variable is unset. */ if (save) { /* Set the var end to null so the normal string routines will work WARNING : This changes the input */ buff[i] = '\0'; save_env(ptn, var, val); if (debug) printf("Unsetting %s\n", var); } /* Clear the variable so state is parse is back to initial. */ var = NULL; var_end = NULL; sets++; } else if (NULL == var_end) { if ((buff[i] == ' ') || (buff[i] == '\t')) var_end = &buff[i]; } else if (NULL == val) { if (!((buff[i] == ' ') || (buff[i] == '\t'))) val = &buff[i]; } else if (NULL == val_end) { if ((buff[i] == '\r') || (buff[i] == '\n')) { /* look for escaped cr or ln */ if ('\\' == buff[i - 1]) { /* check for dos */ if ((buff[i] == '\r') && (buff[i+1] == '\n')) buff[i + 1] = ' '; buff[i - 1] = buff[i] = ' '; } else { val_end = &buff[i]; } } } else { sprintf(err_string, "Internal Error"); if (debug) printf("Internal error at %s %d\n", __FILE__, __LINE__); return 1; } /* Check if a var / val pair is ready */ if (NULL != val_end) { if (save) { /* Set the end's with nulls so normal string routines will work. WARNING : This changes the input */ *var_end = '\0'; *val_end = '\0'; save_env(ptn, var, val); if (debug) printf("Setting %s %s\n", var, val); } /* Clear the variable so state is parse is back to initial. */ var = NULL; var_end = NULL; val = NULL; val_end = NULL; sets++; } } /* Corner case Check for the case that no newline at end of the input */ if ((NULL != var) && (NULL == val_end)) { if (save) { /* case of val / val pair */ if (var_end) *var_end = '\0'; /* else case handled by setting 0 past the end of buffer. Similar for val_end being null */ save_env(ptn, var, val); if (debug) { if (var_end) printf("Trailing Setting %s %s\n", var, val); else printf("Trailing Unsetting %s\n", var); } } sets++; } /* Did we set anything ? */ if (0 == sets) sprintf(err_string, "No variables set"); else ret = 0; return ret; } static int saveenv_to_ptn(struct fastboot_ptentry *ptn, char *err_string) { int ret = 1; int save = 0; int debug = 0; /* err_string is only 32 bytes Initialize with a generic error message. */ sprintf(err_string, "%s", "Unknown Error"); /* Parse the input twice. Only save to the enviroment if the entire input if correct */ save = 0; if (0 == parse_env(ptn, err_string, save, debug)) { save = 1; ret = parse_env(ptn, err_string, save, debug); } return ret; } static void set_ptn_ecc(struct fastboot_ptentry *ptn) { char ecc_type[32]; char *ecc[4] = {"nand", "ecc", NULL, NULL, }; /* Some flashing requires the nand's ecc to be set */ ecc[2] = ecc_type; if ((ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_HW_ECC) && (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_SW_ECC)) { /* Both can not be true */ printf("Warning can not do hw and sw ecc for partition '%s'\n", ptn->name); printf("Ignoring these flags\n"); } else if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_HW_ECC) { sprintf(ecc_type, "hw"); do_nand(NULL, 0, 3, ecc); } else if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_SW_ECC) { sprintf(ecc_type, "sw"); do_nand(NULL, 0, 3, ecc); } } static int write_to_ptn(struct fastboot_ptentry *ptn) { int ret = 1; char start[32], length[32]; char wstart[32], wlength[32], addr[32]; char write_type[32]; int repeat, repeat_max; char *lock[5] = { "nand", "lock", NULL, NULL, NULL, }; char *unlock[5] = { "nand", "unlock", NULL, NULL, NULL, }; char *write[6] = { "nand", "write", NULL, NULL, NULL, NULL, }; char *erase[5] = { "nand", "erase", NULL, NULL, NULL, }; lock[2] = unlock[2] = erase[2] = start; lock[3] = unlock[3] = erase[3] = length; write[1] = write_type; write[2] = addr; write[3] = wstart; write[4] = wlength; printf("flashing '%s'\n", ptn->name); /* Which flavor of write to use */ if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_I) sprintf(write_type, "write.i"); #ifdef CFG_NAND_YAFFS_WRITE else if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_YAFFS) sprintf(write_type, "write.yaffs"); #endif else sprintf(write_type, "write"); set_ptn_ecc(ptn); /* Some flashing requires writing the same data in multiple, consecutive flash partitions */ repeat_max = 1; if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_REPEAT_MASK) { if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_CONTIGUOUS_BLOCK) { printf("Warning can not do both 'contiguous block' and 'repeat' writes for for partition '%s'\n", ptn->name); printf("Ignoring repeat flag\n"); } else { repeat_max = ptn->flags & FASTBOOT_PTENTRY_FLAGS_REPEAT_MASK; } } /* Unlock the whole partition instead of trying to manage special cases */ sprintf(length, "0x%x", ptn->length * repeat_max); for (repeat = 0; repeat < repeat_max; repeat++) { sprintf(start, "0x%x", ptn->start + (repeat * ptn->length)); do_nand(NULL, 0, 4, unlock); do_nand(NULL, 0, 4, erase); if ((ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_NEXT_GOOD_BLOCK) && (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_CONTIGUOUS_BLOCK)) { /* Both can not be true */ printf("Warning can not do 'next good block' and \ 'contiguous block' for partition '%s'\n", ptn->name); printf("Ignoring these flags\n"); } else if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_NEXT_GOOD_BLOCK) { /* Keep writing until you get a good block transfer_buffer should already be aligned */ if (interface.nand_block_size) { unsigned int blocks = download_bytes / interface.nand_block_size; unsigned int i = 0; unsigned int offset = 0; sprintf(wlength, "0x%x", interface.nand_block_size); while (i < blocks) { /* Check for overflow */ if (offset >= ptn->length) break; /* download's address only advance if last write was successful */ sprintf(addr, "0x%x", interface.transfer_buffer + (i * interface.nand_block_size)); /* nand's address always advances */ sprintf(wstart, "0x%x", ptn->start + (repeat * ptn->length) + offset); ret = do_nand(NULL, 0, 5, write); if (ret) break; else i++; /* Go to next nand block */ offset += interface.nand_block_size; } } else { printf("Warning nand block size can not be 0 \ when using 'next good block' for \ partition '%s'\n", ptn->name); printf("Ignoring write request\n"); } } else if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_CONTIGUOUS_BLOCK) { /* Keep writing until you get a good block transfer_buffer should already be aligned */ if (interface.nand_block_size) { if (0 == nand_curr_device) { nand_info_t *nand; unsigned long off; unsigned int ok_start; nand = &nand_info[nand_curr_device]; printf("\nDevice %d bad blocks:\n", nand_curr_device); /* Initialize the ok_start to the start of the partition Then try to find a block large enough for the download */ ok_start = ptn->start; /* It is assumed that the start and length are multiples of block size */ for (off = ptn->start; off < ptn->start + ptn->length; off += nand->erasesize) { if (nand_block_isbad(nand, off)) { /* Reset the ok_start to the next block */ ok_start = off + nand->erasesize; } /* Check if we have enough blocks */ if ((ok_start - off) >= download_bytes) break; } /* Check if there is enough space */ if (ok_start + download_bytes <= ptn->start + ptn->length) { sprintf(addr, "0x%x", interface.transfer_buffer); sprintf(wstart, "0x%x", ok_start); sprintf(wlength, "0x%x", download_bytes); ret = do_nand(NULL, 0, 5, write); /* Save the results into an environment variable on the format ptn_name + 'offset' ptn_name + 'size' */ if (ret) { /* failed */ save_block_values(ptn, 0, 0); } else { /* success */ save_block_values(ptn, ok_start, download_bytes); } } else { printf("Error could not find enough contiguous space in partition '%s' \n", ptn->name); printf("Ignoring write request\n"); } } else { /* TBD : Generalize flash handling */ printf("Error only handling 1 NAND per board"); printf("Ignoring write request\n"); } } else { printf("Warning nand block size can not be 0 \ when using 'continuous block' for \ partition '%s'\n", ptn->name); printf("Ignoring write request\n"); } } else { /* Normal case */ sprintf(addr, "0x%x", interface.transfer_buffer); sprintf(wstart, "0x%x", ptn->start + (repeat * ptn->length)); sprintf(wlength, "0x%x", download_bytes); #ifdef CFG_NAND_YAFFS_WRITE if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_YAFFS) sprintf(wlength, "0x%x", download_bytes_unpadded); #endif ret = do_nand(NULL, 0, 5, write); if (0 == repeat) { if (ret) /* failed */ save_block_values(ptn, 0, 0); else /* success */ save_block_values(ptn, ptn->start, download_bytes); } } do_nand(NULL, 0, 4, lock); if (ret) break; } return ret; } #else /* will do environment writing/saving later */ #endif static int tx_handler(void) { if (upload_size) { int bytes_written; bytes_written = fastboot_tx(interface.transfer_buffer + upload_bytes, upload_size - upload_bytes); if (bytes_written > 0) { upload_bytes += bytes_written; /* Check if this is the last */ if (upload_bytes == upload_size) { /* Reset upload */ upload_size = 0; upload_bytes = 0; upload_error = 0; } } } return upload_error; } static int rx_handler (const unsigned char *buffer, unsigned int buffer_size) { int ret = 1, temp_len = 0; /* Use 65 instead of 64 null gets dropped strcpy's need the extra byte */ char response[65]; if (download_size) { /* Something to download */ if (buffer_size) { /* Handle possible overflow */ unsigned int transfer_size = download_size - download_bytes; if (buffer_size < transfer_size) transfer_size = buffer_size; /* Save the data to the transfer buffer */ memcpy(interface.transfer_buffer + download_bytes, buffer, transfer_size); download_bytes += transfer_size; /* Check if transfer is done */ if (download_bytes >= download_size) { /* Reset global transfer variable, Keep download_bytes because it will be used in the next possible flashing command */ download_size = 0; if (download_error) { /* There was an earlier error */ sprintf(response, "ERROR"); } else { /* Everything has transferred, send the OK response */ sprintf(response, "OKAY"); } fastboot_tx_status(response, strlen(response)); printf("\ndownloading of %d bytes finished\n", download_bytes); #if defined(CONFIG_FASTBOOT_STORAGE_NAND) /* Pad to block length In most cases, padding the download to be block aligned is correct. The exception is when the following flash writes to the oob area. This happens when the image is a YAFFS image. Since we do not know what the download is until it is flashed, go ahead and pad it, but save the true size in case if should have been unpadded */ download_bytes_unpadded = download_bytes; if (interface.nand_block_size) { if (download_bytes % interface.nand_block_size) { unsigned int pad = interface.nand_block_size - (download_bytes % interface.nand_block_size); unsigned int i; for (i = 0; i < pad; i++) { if (download_bytes >= interface.transfer_buffer_size) break; interface.transfer_buffer[download_bytes] = 0; download_bytes++; } } } #endif } /* Provide some feedback */ if (download_bytes && 0 == (download_bytes % (16 * interface.nand_block_size))) { /* Some feeback that the download is happening */ if (download_error) printf("X"); else printf("."); if (0 == (download_bytes % (80 * 16 * interface.nand_block_size))) printf("\n"); } } else { /* Ignore empty buffers */ printf("Warning empty download buffer\n"); printf("Ignoring\n"); } ret = 0; } else { /* A command */ /* Cast to make compiler happy with string functions */ const char *cmdbuf = (char *) buffer; printf("cmdbuf: %s\n", cmdbuf); /* Generic failed response */ sprintf(response, "FAIL"); /* reboot Reboot the board. */ if (memcmp(cmdbuf, "reboot", 6) == 0) { sprintf(response, "OKAY"); fastboot_tx_status(response, strlen(response)); udelay(1000000); /* 1 sec */ do_reset(NULL, 0, 0, NULL); /* This code is unreachable, leave it to make the compiler happy */ return 0; } /* getvar Get common fastboot variables Board has a chance to handle other variables */ if (memcmp(cmdbuf, "getvar:", 7) == 0) { strcpy(response, "OKAY"); temp_len = strlen("getvar:"); if (!strcmp(cmdbuf + temp_len, "version")) { strcpy(response + 4, FASTBOOT_VERSION); } else if (!strcmp(cmdbuf + temp_len, "product")) { if (interface.product_name) strcpy(response + 4, interface.product_name); } else if (!strcmp(cmdbuf + temp_len, "serialno")) { if (interface.serial_no) strcpy(response + 4, interface.serial_no); } else if (!strcmp(cmdbuf + temp_len, "downloadsize")) { if (interface.transfer_buffer_size) sprintf(response + 4, "0x%x", interface.transfer_buffer_size); } else { fastboot_getvar(cmdbuf + 7, response + 4); } ret = 0; } /* erase Erase a register flash partition Board has to set up flash partitions */ if (memcmp(cmdbuf, "erase:", 6) == 0) { #if defined(CONFIG_FASTBOOT_STORAGE_NAND) struct fastboot_ptentry *ptn; ptn = fastboot_flash_find_ptn(cmdbuf + 6); if (ptn == 0) { sprintf(response, "FAILpartition does not exist"); } else { char start[32], length[32]; int status, repeat, repeat_max; printf("erasing '%s'\n", ptn->name); char *lock[5] = { "nand", "lock", NULL, NULL, NULL, }; char *unlock[5] = { "nand", "unlock", NULL, NULL, NULL, }; char *erase[5] = { "nand", "erase", NULL, NULL, NULL, }; lock[2] = unlock[2] = erase[2] = start; lock[3] = unlock[3] = erase[3] = length; repeat_max = 1; if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_REPEAT_MASK) repeat_max = ptn->flags & FASTBOOT_PTENTRY_FLAGS_REPEAT_MASK; sprintf(length, "0x%x", ptn->length); for (repeat = 0; repeat < repeat_max; repeat++) { sprintf(start, "0x%x", ptn->start + (repeat * ptn->length)); do_nand(NULL, 0, 4, unlock); status = do_nand(NULL, 0, 4, erase); do_nand(NULL, 0, 4, lock); if (status) break; } if (status) { sprintf(response, "FAILfailed to erase partition"); } else { printf("partition '%s' erased\n", ptn->name); sprintf(response, "OKAY"); } } #elif defined(CONFIG_FASTBOOT_STORAGE_EMMC) struct fastboot_ptentry *ptn; #ifdef CONFIG_DYNAMIC_MMC_DEVNO mmc_controller_no = get_mmc_env_devno(); #else /* Save the MMC controller number */ mmc_controller_no = CONFIG_FASTBOOT_MMC_NO; #endif /* Find the partition and erase it */ ptn = fastboot_flash_find_ptn(cmdbuf + 6); if (ptn == 0) { sprintf(response, "FAIL: partition doesn't exist"); } else { /* Call MMC erase function here */ char start[32], length[32]; char slot_no[32]; char *erase[5] = {"mmc", "erase", NULL, NULL, NULL}; char *mmc_init[2] = {"mmcinit", NULL}; mmc_init[1] = slot_no; erase[2] = slot_no; erase[3] = start; erase[4] = length; sprintf(slot_no, "%d", mmc_controller_no); sprintf(length, "0x%x", ptn->length / MMC_BLOCK_SIZE); sprintf(start, "0x%x", ptn->start / MMC_BLOCK_SIZE); printf("Initializing '%s'\n", ptn->name); if (do_mmcops(NULL, 0, 2, mmc_init)) sprintf(response, "FAIL: Init of MMC card"); else sprintf(response, "OKAY"); printf("Erasing '%s'\n", ptn->name); if (do_mmcops(NULL, 0, 5, erase)) { printf("Erasing '%s' FAILED!\n", ptn->name); sprintf(response, "FAIL: Erase partition"); } else { printf("Erasing '%s' DONE!\n", ptn->name); sprintf(response, "OKAY"); } } #endif ret = 0; } /* download download something .. What happens to it depends on the next command after data */ if (memcmp(cmdbuf, "download:", 9) == 0) { /* save the size */ download_size = simple_strtoul(cmdbuf + 9, NULL, 16); /* Reset the bytes count, now it is safe */ download_bytes = 0; /* Reset error */ download_error = 0; printf("Starting download of %d bytes\n", download_size); if (0 == download_size) { /* bad user input */ sprintf(response, "FAILdata invalid size"); } else if (download_size > interface.transfer_buffer_size) { /* set download_size to 0 because this is an error */ download_size = 0; sprintf(response, "FAILdata too large"); } else { /* The default case, the transfer fits completely in the interface buffer */ sprintf(response, "DATA%08x", download_size); } ret = 0; } /* boot boot what was downloaded WARNING WARNING WARNING This is not what you expect. The fastboot client does its own packaging of the kernel. The layout is defined in the android header file bootimage.h. This layeout is copiedlooks like this, ** ** +-----------------+ ** | boot header | 1 page ** +-----------------+ ** | kernel | n pages ** +-----------------+ ** | ramdisk | m pages ** +-----------------+ ** | second stage | o pages ** +-----------------+ ** We only care about the kernel. So we have to jump past a page. What is a page size ? The fastboot client uses 2048 The is the default value of CFG_FASTBOOT_MKBOOTIMAGE_PAGE_SIZE */ if (memcmp(cmdbuf, "boot", 4) == 0) { if ((download_bytes) && (CFG_FASTBOOT_MKBOOTIMAGE_PAGE_SIZE < download_bytes)) { char start[32]; char *bootm[3] = { "bootm", NULL, NULL, }; char *go[3] = { "go", NULL, NULL, }; /* * Use this later to determine if a command line was passed * for the kernel. */ struct fastboot_boot_img_hdr *fb_hdr = (struct fastboot_boot_img_hdr *) interface.transfer_buffer; /* Skip the mkbootimage header */ image_header_t *hdr = (image_header_t *) &interface.transfer_buffer[CFG_FASTBOOT_MKBOOTIMAGE_PAGE_SIZE]; bootm[1] = go[1] = start; sprintf(start, "0x%x", (unsigned int)hdr); /* Execution should jump to kernel so send the response now and wait a bit. */ sprintf(response, "OKAY"); fastboot_tx_status(response, strlen(response)); udelay(1000000); /* 1 sec */ if (ntohl(hdr->ih_magic) == IH_MAGIC) { /* Looks like a kernel.. */ printf("Booting kernel..\n"); /* * Check if the user sent a bootargs down. * If not, do not override what is already there */ if (strlen((char *)&fb_hdr->cmdline[0])) set_env("bootargs", (char *)&fb_hdr->cmdline[0]); do_bootm(NULL, 0, 2, bootm); } else { /* Raw image, maybe another uboot */ printf("Booting raw image..\n"); do_go(NULL, 0, 2, go); } printf("ERROR : bootting failed\n"); printf("You should reset the board\n"); } sprintf(response, "FAILinvalid boot image"); ret = 0; } /* flash Flash what was downloaded */ if (memcmp(cmdbuf, "flash:", 6) == 0) { #if defined(CONFIG_FASTBOOT_STORAGE_NAND) if (download_bytes) { struct fastboot_ptentry *ptn; ptn = fastboot_flash_find_ptn(cmdbuf + 6); if (ptn == 0) { sprintf(response, "FAILpartition does not exist"); } else if ((download_bytes > ptn->length) && !(ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_ENV)) { sprintf(response, "FAILimage too large for partition"); /* TODO : Improve check for yaffs write */ } else { /* Check if this is not really a flash write but rather a saveenv */ if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_ENV) { /* Since the response can only be 64 bytes, there is no point in having a large error message. */ char err_string[32]; if (saveenv_to_ptn(ptn, &err_string[0])) { printf("savenv '%s' failed : %s\n", ptn->name, err_string); sprintf(response, "FAIL%s", err_string); } else { printf("partition '%s' saveenv-ed\n", ptn->name); sprintf(response, "OKAY"); } } else { /* Normal case */ if (write_to_ptn(ptn)) { printf("flashing '%s' failed\n", ptn->name); sprintf(response, "FAILfailed to flash partition"); } else { printf("partition '%s' flashed\n", ptn->name); sprintf(response, "OKAY"); } } } } else { sprintf(response, "FAILno image downloaded"); } #elif defined(CONFIG_FASTBOOT_STORAGE_EMMC) if (download_bytes) { struct fastboot_ptentry *ptn; #ifdef CONFIG_DYNAMIC_MMC_DEVNO mmc_controller_no = get_mmc_env_devno(); #else /* Save the MMC controller number */ mmc_controller_no = CONFIG_FASTBOOT_MMC_NO; #endif /* Next is the partition name */ ptn = fastboot_flash_find_ptn(cmdbuf + 6); if (ptn == 0) { printf("Partition:'%s' does not exist\n", ptn->name); sprintf(response, "FAILpartition does not exist"); } else if ((download_bytes > ptn->length) && !(ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_ENV)) { printf("Image too large for the partition\n"); sprintf(response, "FAILimage too large for partition"); } else if (ptn->flags & FASTBOOT_PTENTRY_FLAGS_WRITE_ENV) { /* Check if this is not really a flash write, * but instead a saveenv */ unsigned int i = 0; /* Env file is expected with a NULL delimeter between * env variables So replace New line Feeds (0x0a) with * NULL (0x00) */ printf("Goto write env, flags=0x%x\n", ptn->flags); for (i = 0; i < download_bytes; i++) { if (interface.transfer_buffer[i] == 0x0a) interface.transfer_buffer[i] = 0x00; } memset(env_ptr->data, 0, ENV_SIZE); memcpy(env_ptr->data, interface.transfer_buffer, download_bytes); do_saveenv(NULL, 0, 1, NULL); printf("saveenv to '%s' DONE!\n", ptn->name); sprintf(response, "OKAY"); } else { /* Normal case */ char source[32], dest[32], length[32]; char slot_no[32]; unsigned int temp; printf("writing to partition '%s'\n", ptn->name); char *mmc_write[6] = {"mmc", "write", NULL, NULL, NULL, NULL}; char *mmc_init[2] = {"mmcinit", NULL,}; mmc_init[1] = slot_no; mmc_write[2] = slot_no; mmc_write[3] = source; mmc_write[4] = dest; mmc_write[5] = length; sprintf(slot_no, "%d", mmc_controller_no); sprintf(source, "0x%x", interface.transfer_buffer); /* block offset */ temp = ptn->start / MMC_BLOCK_SIZE; sprintf(dest, "0x%x", temp); /* block count */ temp = (download_bytes + MMC_BLOCK_SIZE - 1) / MMC_BLOCK_SIZE; sprintf(length, "0x%x", temp); printf("Initializing '%s'\n", ptn->name); if (do_mmcops(NULL, 0, 2, mmc_init)) sprintf(response, "FAIL:Init of MMC card"); else sprintf(response, "OKAY"); printf("Writing '%s'\n", ptn->name); if (do_mmcops(NULL, 0, 6, mmc_write)) { printf("Writing '%s' FAILED!\n", ptn->name); sprintf(response, "FAIL: Write partition"); } else { printf("Writing '%s' DONE!\n", ptn->name); sprintf(response, "OKAY"); } } } else { sprintf(response, "FAILno image downloaded"); } #endif ret = 0; } /* continue Stop doing fastboot */ if (memcmp(cmdbuf, "continue", 8) == 0) { sprintf(response, "OKAY"); continue_booting = 1; ret = 0; } /* upload Upload just the data in a partition */ if ((memcmp(cmdbuf, "upload:", 7) == 0) || (memcmp(cmdbuf, "uploadraw:", 10) == 0)) { #if defined(CONFIG_FASTBOOT_STORAGE_NAND) unsigned int adv, delim_index, len; struct fastboot_ptentry *ptn; unsigned int is_raw = 0; /* Is this a raw read ? */ if (memcmp(cmdbuf, "uploadraw:", 10) == 0) { is_raw = 1; adv = 10; } else { adv = 7; } /* Scan to the next ':' to find when the size starts */ len = strlen(cmdbuf); for (delim_index = adv; delim_index < len; delim_index++) { if (cmdbuf[delim_index] == ':') { /* WARNING, cmdbuf is being modified. */ *((char *) &cmdbuf[delim_index]) = 0; break; } } ptn = fastboot_flash_find_ptn(cmdbuf + adv); if (ptn == 0) { sprintf(response, "FAILpartition does not exist"); } else { /* This is how much the user is expecting */ unsigned int user_size; /* * This is the maximum size needed for * this partition */ unsigned int size; /* This is the length of the data */ unsigned int length; /* * Used to check previous write of * the parition */ char env_ptn_length_var[128]; char *env_ptn_length_val; user_size = 0; if (delim_index < len) user_size = simple_strtoul(cmdbuf + delim_index + 1, NULL, 16); /* Make sure output is padded to block size */ length = ptn->length; sprintf(env_ptn_length_var, "%s_nand_size", ptn->name); env_ptn_length_val = getenv(env_ptn_length_var); if (env_ptn_length_val) { length = simple_strtoul(env_ptn_length_val, NULL, 16); /* Catch possible problems */ if (!length) length = ptn->length; } size = length / interface.nand_block_size; size *= interface.nand_block_size; if (length % interface.nand_block_size) size += interface.nand_block_size; if (is_raw) size += (size / interface.nand_block_size) * interface.nand_oob_size; if (size > interface.transfer_buffer_size) { sprintf(response, "FAILdata too large"); } else if (user_size == 0) { /* Send the data response */ sprintf(response, "DATA%08x", size); } else if (user_size != size) { /* This is the wrong size */ sprintf(response, "FAIL"); } else { /* * This is where the transfer * buffer is populated */ unsigned char *buf = interface.transfer_buffer; char start[32], length[32], type[32], addr[32]; char *read[6] = { "nand", NULL, NULL, NULL, NULL, NULL, }; /* * Setting upload_size causes * transfer to happen in main loop */ upload_size = size; upload_bytes = 0; upload_error = 0; /* * Poison the transfer buffer, 0xff * is erase value of nand */ memset(buf, 0xff, upload_size); /* Which flavor of read to use */ if (is_raw) sprintf(type, "read.raw"); else sprintf(type, "read.i"); sprintf(addr, "0x%x", interface.transfer_buffer); sprintf(start, "0x%x", ptn->start); sprintf(length, "0x%x", upload_size); read[1] = type; read[2] = addr; read[3] = start; read[4] = length; set_ptn_ecc(ptn); do_nand(NULL, 0, 5, read); /* Send the data response */ sprintf(response, "DATA%08x", size); } } #endif ret = 0; } fastboot_tx_status(response, strlen(response)); } /* End of command */ return ret; } static int check_against_static_partition(struct fastboot_ptentry *ptn) { int ret = 0; struct fastboot_ptentry *c; int i; for (i = 0; i < static_pcount; i++) { c = fastboot_flash_get_ptn((unsigned int) i); if (0 == ptn->length) break; if ((ptn->start >= c->start) && (ptn->start < c->start + c->length)) break; if ((ptn->start + ptn->length > c->start) && (ptn->start + ptn->length <= c->start + c->length)) break; if ((0 == strcmp(ptn->name, c->name)) && (0 == strcmp(c->name, ptn->name))) break; } if (i >= static_pcount) ret = 1; return ret; } static unsigned long long memparse(char *ptr, char **retptr) { char *endptr; /* local pointer to end of parsed string */ unsigned long ret = simple_strtoul(ptr, &endptr, 0); switch (*endptr) { case 'M': case 'm': ret <<= 10; case 'K': case 'k': ret <<= 10; endptr++; default: break; } if (retptr) *retptr = endptr; return ret; } static int add_partition_from_environment(char *s, char **retptr) { unsigned long size; unsigned long offset = 0; char *name; int name_len; int delim; unsigned int flags; struct fastboot_ptentry part; size = memparse(s, &s); if (0 == size) { printf("Error:FASTBOOT size of parition is 0\n"); return 1; } /* fetch partition name and flags */ flags = 0; /* this is going to be a regular partition */ delim = 0; /* check for offset */ if (*s == '@') { s++; offset = memparse(s, &s); } else { printf("Error:FASTBOOT offset of parition is not given\n"); return 1; } /* now look for name */ if (*s == '(') delim = ')'; if (delim) { char *p; name = ++s; p = strchr((const char *)name, delim); if (!p) { printf("Error:FASTBOOT no closing %c found in partition name\n", delim); return 1; } name_len = p - name; s = p + 1; } else { printf("Error:FASTBOOT no partition name for \'%s\'\n", s); return 1; } /* test for options */ while (1) { if (strncmp(s, "i", 1) == 0) { flags |= FASTBOOT_PTENTRY_FLAGS_WRITE_I; s += 1; } else if (strncmp(s, "yaffs", 5) == 0) { /* yaffs */ flags |= FASTBOOT_PTENTRY_FLAGS_WRITE_YAFFS; s += 5; } else if (strncmp(s, "swecc", 5) == 0) { /* swecc */ flags |= FASTBOOT_PTENTRY_FLAGS_WRITE_SW_ECC; s += 5; } else if (strncmp(s, "hwecc", 5) == 0) { /* hwecc */ flags |= FASTBOOT_PTENTRY_FLAGS_WRITE_HW_ECC; s += 5; } else { break; } if (strncmp(s, "|", 1) == 0) s += 1; } /* enter this partition (offset will be calculated later if it is zero at this point) */ part.length = size; part.start = offset; part.flags = flags; if (name) { if (name_len >= sizeof(part.name)) { printf("Error:FASTBOOT partition name is too long\n"); return 1; } strncpy(&part.name[0], name, name_len); /* name is not null terminated */ part.name[name_len] = '\0'; } else { printf("Error:FASTBOOT no name\n"); return 1; } /* Check if this overlaps a static partition */ if (check_against_static_partition(&part)) { printf("Adding: %s, offset 0x%8.8x, size 0x%8.8x, flags 0x%8.8x\n", part.name, part.start, part.length, part.flags); fastboot_flash_add_ptn(&part); } /* return (updated) pointer command line string */ *retptr = s; /* return partition table */ return 0; } int do_fastboot (cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]) { int ret = 1; char fbparts[4096], *env; int check_timeout = 0; uint64_t timeout_endtime = 0; uint64_t timeout_ticks = 1000; long timeout_seconds = -1; int continue_from_disconnect = 0; /* * Place the runtime partitions at the end of the * static paritions. First save the start off so * it can be saved from run to run. */ if (static_pcount >= 0) { /* Reset */ pcount = static_pcount; } else { /* Save */ static_pcount = pcount; } env = getenv("fbparts"); if (env) { unsigned int len; len = strlen(env); if (len && len < 4096) { char *s, *e; memcpy(&fbparts[0], env, len + 1); printf("Fastboot: Adding partitions from environment\n"); s = &fbparts[0]; e = s + len; while (s < e) { if (add_partition_from_environment(s, &s)) { printf("Error:Fastboot: Abort adding partitions\n"); /* reset back to static */ pcount = static_pcount; break; } /* Skip a bunch of delimiters */ while (s < e) { if ((' ' == *s) || ('\t' == *s) || ('\n' == *s) || ('\r' == *s) || (',' == *s)) { s++; } else { break; } } } } } /* Time out */ if (2 == argc) { long try_seconds; char *try_seconds_end; /* Check for timeout */ try_seconds = simple_strtol(argv[1], &try_seconds_end, 10); if ((try_seconds_end != argv[1]) && (try_seconds >= 0)) { check_timeout = 1; timeout_seconds = try_seconds; printf("Fastboot inactivity timeout %ld seconds\n", timeout_seconds); } } do { continue_from_disconnect = 0; /* Initialize the board specific support */ if (0 == fastboot_init(&interface)) { int poll_status; /* If we got this far, we are a success */ ret = 0; printf("fastboot initialized\n"); timeout_endtime = get_timer(0); timeout_endtime += timeout_ticks; while (1) { uint64_t current_time = 0; poll_status = fastboot_poll(); if (1 == check_timeout) current_time = get_timer(0); if (FASTBOOT_ERROR == poll_status) { /* Error */ break; } else if (FASTBOOT_DISCONNECT == poll_status) { /* beak, cleanup and re-init */ printf("Fastboot disconnect detected\n"); continue_from_disconnect = 1; break; } else if ((1 == check_timeout) && (FASTBOOT_INACTIVE == poll_status)) { /* No activity */ if (current_time >= timeout_endtime) { printf("Fastboot inactivity detected\n"); break; } } else { /* Something happened */ if (1 == check_timeout) { /* Update the timeout endtime */ timeout_endtime = current_time; timeout_endtime += timeout_ticks; } } /* Check if the user wanted to terminate with ^C */ if ((FASTBOOT_INACTIVE == poll_status) && (ctrlc())) { printf("Fastboot ended by user\n"); break; } /* * Check if the fastboot client wanted to * continue booting */ if (continue_booting) { printf("Fastboot ended by client\n"); break; } /* Check if there is something to upload */ tx_handler(); } } /* Reset the board specific support */ fastboot_shutdown(); /* restart the loop if a disconnect was detected */ } while (continue_from_disconnect); return ret; } U_BOOT_CMD( fastboot, 2, 1, do_fastboot, "fastboot- use USB Fastboot protocol\n", "[inactive timeout]\n" " - Run as a fastboot usb device.\n" " - The optional inactive timeout is the decimal seconds before\n" " - the normal console resumes\n" ); /* * Android style flash utilties */ void fastboot_flash_add_ptn(fastboot_ptentry *ptn) { if (pcount < MAX_PTN) { memcpy(ptable + pcount, ptn, sizeof(fastboot_ptentry)); pcount++; } } void fastboot_flash_dump_ptn(void) { unsigned int n; for (n = 0; n < pcount; n++) { fastboot_ptentry *ptn = ptable + n; printf("ptn %d name='%s' start=%d len=%d\n", n, ptn->name, ptn->start, ptn->length); } } fastboot_ptentry *fastboot_flash_find_ptn(const char *name) { unsigned int n; for (n = 0; n < pcount; n++) { /* Make sure a substring is not accepted */ if (strlen(name) == strlen(ptable[n].name)) { if (0 == strcmp(ptable[n].name, name)) return ptable + n; } } return 0; } fastboot_ptentry *fastboot_flash_get_ptn(unsigned int n) { if (n < pcount) return ptable + n; else return 0; } unsigned int fastboot_flash_get_ptn_count(void) { return pcount; } #endif /* CONFIG_FASTBOOT */