Prepare v2024.04

[ti-u-boot/ti-u-boot.git] / tools / mxsimage.c

// SPDX-License-Identifier: GPL-2.0+
/*
 * Freescale i.MX23/i.MX28 SB image generator
 *
 * Copyright (C) 2012-2013 Marek Vasut <marex@denx.de>
 */

#ifdef CONFIG_MXS

#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <string.h>
#include <u-boot/crc.h>
#include <unistd.h>
#include <limits.h>

#include <openssl/evp.h>

#include "imagetool.h"
#include "mxsimage.h"
#include "pbl_crc32.h"
#include <image.h>

/*
 * OpenSSL 1.1.0 and newer compatibility functions:
 * https://wiki.openssl.org/index.php/1.1_API_Changes
 */
#if OPENSSL_VERSION_NUMBER < 0x10100000L || \
    (defined(LIBRESSL_VERSION_NUMBER) && LIBRESSL_VERSION_NUMBER < 0x2070000fL)
static void *OPENSSL_zalloc(size_t num)
{
        void *ret = OPENSSL_malloc(num);

        if (ret != NULL)
                memset(ret, 0, num);
        return ret;
}

EVP_MD_CTX *EVP_MD_CTX_new(void)
{
        return OPENSSL_zalloc(sizeof(EVP_MD_CTX));
}

void EVP_MD_CTX_free(EVP_MD_CTX *ctx)
{
        EVP_MD_CTX_cleanup(ctx);
        OPENSSL_free(ctx);
}

int EVP_CIPHER_CTX_reset(EVP_CIPHER_CTX *ctx)
{
        return EVP_CIPHER_CTX_cleanup(ctx);
}
#endif

/*
 * DCD block
 * |-Write to address command block
 * |  0xf00 == 0xf33d
 * |  0xba2 == 0xb33f
 * |-ORR address with mask command block
 * |  0xf00 |= 0x1337
 * |-Write to address command block
 * |  0xba2 == 0xd00d
 * :
 */
#define SB_HAB_DCD_WRITE        0xccUL
#define SB_HAB_DCD_CHECK        0xcfUL
#define SB_HAB_DCD_NOOP         0xc0UL
#define SB_HAB_DCD_MASK_BIT     (1 << 3)
#define SB_HAB_DCD_SET_BIT      (1 << 4)

/* Addr.n = Value.n */
#define SB_DCD_WRITE    \
        (SB_HAB_DCD_WRITE << 24)
/* Addr.n &= ~Value.n */
#define SB_DCD_ANDC     \
        ((SB_HAB_DCD_WRITE << 24) | SB_HAB_DCD_SET_BIT)
/* Addr.n |= Value.n */
#define SB_DCD_ORR      \
        ((SB_HAB_DCD_WRITE << 24) | SB_HAB_DCD_SET_BIT | SB_HAB_DCD_MASK_BIT)
/* (Addr.n & Value.n) == 0 */
#define SB_DCD_CHK_EQZ  \
        (SB_HAB_DCD_CHECK << 24)
/* (Addr.n & Value.n) == Value.n */
#define SB_DCD_CHK_EQ   \
        ((SB_HAB_DCD_CHECK << 24) | SB_HAB_DCD_SET_BIT)
/* (Addr.n & Value.n) != Value.n */
#define SB_DCD_CHK_NEQ  \
        ((SB_HAB_DCD_CHECK << 24) | SB_HAB_DCD_MASK_BIT)
/* (Addr.n & Value.n) != 0 */
#define SB_DCD_CHK_NEZ  \
        ((SB_HAB_DCD_CHECK << 24) | SB_HAB_DCD_SET_BIT | SB_HAB_DCD_MASK_BIT)
/* NOP */
#define SB_DCD_NOOP     \
        (SB_HAB_DCD_NOOP << 24)

struct sb_dcd_ctx {
        struct sb_dcd_ctx               *dcd;

        uint32_t                        id;

        /* The DCD block. */
        uint32_t                        *payload;
        /* Size of the whole DCD block. */
        uint32_t                        size;

        /* Pointer to previous DCD command block. */
        uint32_t                        *prev_dcd_head;
};

/*
 * IMAGE
 *   |-SECTION
 *   |    |-CMD
 *   |    |-CMD
 *   |    `-CMD
 *   |-SECTION
 *   |    |-CMD
 *   :    :
 */
struct sb_cmd_list {
        char                            *cmd;
        size_t                          len;
        unsigned int                    lineno;
};

struct sb_cmd_ctx {
        uint32_t                        size;

        struct sb_cmd_ctx               *cmd;

        uint8_t                         *data;
        uint32_t                        length;

        struct sb_command               payload;
        struct sb_command               c_payload;
};

struct sb_section_ctx {
        uint32_t                        size;

        /* Section flags */
        unsigned int                    boot:1;

        struct sb_section_ctx           *sect;

        struct sb_cmd_ctx               *cmd_head;
        struct sb_cmd_ctx               *cmd_tail;

        struct sb_sections_header       payload;
};

struct sb_image_ctx {
        unsigned int                    in_section:1;
        unsigned int                    in_dcd:1;
        /* Image configuration */
        unsigned int                    display_progress:1;
        unsigned int                    silent_dump:1;
        char                            *input_filename;
        char                            *output_filename;
        char                            *cfg_filename;
        uint8_t                         image_key[16];

        /* Number of section in the image */
        unsigned int                    sect_count;
        /* Bootable section */
        unsigned int                    sect_boot;
        unsigned int                    sect_boot_found:1;

        struct sb_section_ctx           *sect_head;
        struct sb_section_ctx           *sect_tail;

        struct sb_dcd_ctx               *dcd_head;
        struct sb_dcd_ctx               *dcd_tail;

        EVP_CIPHER_CTX                  *cipher_ctx;
        EVP_MD_CTX                      *md_ctx;
        uint8_t                         digest[32];
        struct sb_key_dictionary_key    sb_dict_key;

        struct sb_boot_image_header     payload;
};

/*
 * Instruction semantics:
 * NOOP
 * TAG [LAST]
 * LOAD       address file
 * LOAD  IVT  address IVT_entry_point
 * FILL address pattern length
 * JUMP [HAB] address [r0_arg]
 * CALL [HAB] address [r0_arg]
 * MODE mode
 *      For i.MX23, mode = USB/I2C/SPI1_FLASH/SPI2_FLASH/NAND_BCH
 *                         JTAG/SPI3_EEPROM/SD_SSP0/SD_SSP1
 *      For i.MX28, mode = USB/I2C/SPI2_FLASH/SPI3_FLASH/NAND_BCH
 *                         JTAG/SPI2_EEPROM/SD_SSP0/SD_SSP1
 */

/*
 * AES libcrypto
 */
static int sb_aes_init(struct sb_image_ctx *ictx, uint8_t *iv, int enc)
{
        EVP_CIPHER_CTX *ctx;
        int ret;

        /* If there is no init vector, init vector is all zeroes. */
        if (!iv)
                iv = ictx->image_key;

        ctx = EVP_CIPHER_CTX_new();
        ret = EVP_CipherInit(ctx, EVP_aes_128_cbc(), ictx->image_key, iv, enc);
        if (ret == 1) {
                EVP_CIPHER_CTX_set_padding(ctx, 0);
                ictx->cipher_ctx = ctx;
        }
        return ret;
}

static int sb_aes_crypt(struct sb_image_ctx *ictx, uint8_t *in_data,
                        uint8_t *out_data, int in_len)
{
        EVP_CIPHER_CTX *ctx = ictx->cipher_ctx;
        int ret, outlen;
        uint8_t *outbuf;

        outbuf = malloc(in_len);
        if (!outbuf)
                return -ENOMEM;
        memset(outbuf, 0, sizeof(in_len));

        ret = EVP_CipherUpdate(ctx, outbuf, &outlen, in_data, in_len);
        if (!ret) {
                ret = -EINVAL;
                goto err;
        }

        if (out_data)
                memcpy(out_data, outbuf, outlen);

err:
        free(outbuf);
        return ret;
}

static int sb_aes_deinit(EVP_CIPHER_CTX *ctx)
{
        return EVP_CIPHER_CTX_reset(ctx);
}

static int sb_aes_reinit(struct sb_image_ctx *ictx, int enc)
{
        int ret;
        EVP_CIPHER_CTX *ctx = ictx->cipher_ctx;
        struct sb_boot_image_header *sb_header = &ictx->payload;
        uint8_t *iv = sb_header->iv;

        ret = sb_aes_deinit(ctx);
        if (!ret)
                return ret;
        return sb_aes_init(ictx, iv, enc);
}

/*
 * Debug
 */
static void soprintf(struct sb_image_ctx *ictx, const char *fmt, ...)
{
        va_list ap;

        if (ictx->silent_dump)
                return;

        va_start(ap, fmt);
        vfprintf(stdout, fmt, ap);
        va_end(ap);
}

/*
 * Code
 */
static time_t sb_get_timestamp(void)
{
        struct tm time_2000 = {
                .tm_yday        = 1,    /* Jan. 1st */
                .tm_year        = 100,  /* 2000 */
        };
        time_t seconds_to_2000 = mktime(&time_2000);
        time_t seconds_to_now = time(NULL);

        return seconds_to_now - seconds_to_2000;
}

static int sb_get_time(time_t time, struct tm *tm)
{
        struct tm time_2000 = {
                .tm_yday        = 1,    /* Jan. 1st */
                .tm_year        = 0,    /* 1900 */
        };
        const time_t seconds_to_2000 = mktime(&time_2000);
        const time_t seconds_to_now = seconds_to_2000 + time;
        struct tm *ret;
        ret = gmtime_r(&seconds_to_now, tm);
        return ret ? 0 : -EINVAL;
}

static void sb_encrypt_sb_header(struct sb_image_ctx *ictx)
{
        EVP_MD_CTX *md_ctx = ictx->md_ctx;
        struct sb_boot_image_header *sb_header = &ictx->payload;
        uint8_t *sb_header_ptr = (uint8_t *)sb_header;

        /* Encrypt the header, compute the digest. */
        sb_aes_crypt(ictx, sb_header_ptr, NULL, sizeof(*sb_header));
        EVP_DigestUpdate(md_ctx, sb_header_ptr, sizeof(*sb_header));
}

static void sb_encrypt_sb_sections_header(struct sb_image_ctx *ictx)
{
        EVP_MD_CTX *md_ctx = ictx->md_ctx;
        struct sb_section_ctx *sctx = ictx->sect_head;
        struct sb_sections_header *shdr;
        uint8_t *sb_sections_header_ptr;
        const int size = sizeof(*shdr);

        while (sctx) {
                shdr = &sctx->payload;
                sb_sections_header_ptr = (uint8_t *)shdr;

                sb_aes_crypt(ictx, sb_sections_header_ptr,
                             ictx->sb_dict_key.cbc_mac, size);
                EVP_DigestUpdate(md_ctx, sb_sections_header_ptr, size);

                sctx = sctx->sect;
        };
}

static void sb_encrypt_key_dictionary_key(struct sb_image_ctx *ictx)
{
        EVP_MD_CTX *md_ctx = ictx->md_ctx;

        sb_aes_crypt(ictx, ictx->image_key, ictx->sb_dict_key.key,
                     sizeof(ictx->sb_dict_key.key));
        EVP_DigestUpdate(md_ctx, &ictx->sb_dict_key, sizeof(ictx->sb_dict_key));
}

static void sb_decrypt_key_dictionary_key(struct sb_image_ctx *ictx)
{
        EVP_MD_CTX *md_ctx = ictx->md_ctx;

        EVP_DigestUpdate(md_ctx, &ictx->sb_dict_key, sizeof(ictx->sb_dict_key));
        sb_aes_crypt(ictx, ictx->sb_dict_key.key, ictx->image_key,
                     sizeof(ictx->sb_dict_key.key));
}

static void sb_encrypt_tag(struct sb_image_ctx *ictx,
                struct sb_cmd_ctx *cctx)
{
        EVP_MD_CTX *md_ctx = ictx->md_ctx;
        struct sb_command *cmd = &cctx->payload;

        sb_aes_crypt(ictx, (uint8_t *)cmd,
                     (uint8_t *)&cctx->c_payload, sizeof(*cmd));
        EVP_DigestUpdate(md_ctx, &cctx->c_payload, sizeof(*cmd));
}

static int sb_encrypt_image(struct sb_image_ctx *ictx)
{
        /* Start image-wide crypto. */
        ictx->md_ctx = EVP_MD_CTX_new();
        EVP_DigestInit(ictx->md_ctx, EVP_sha1());

        /*
         * SB image header.
         */
        sb_aes_init(ictx, NULL, 1);
        sb_encrypt_sb_header(ictx);

        /*
         * SB sections header.
         */
        sb_encrypt_sb_sections_header(ictx);

        /*
         * Key dictionary.
         */
        sb_aes_reinit(ictx, 1);
        sb_encrypt_key_dictionary_key(ictx);

        /*
         * Section tags.
         */
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;
        struct sb_section_ctx *sctx = ictx->sect_head;

        while (sctx) {
                cctx = sctx->cmd_head;

                sb_aes_reinit(ictx, 1);

                while (cctx) {
                        ccmd = &cctx->payload;

                        sb_encrypt_tag(ictx, cctx);

                        if (ccmd->header.tag == ROM_TAG_CMD) {
                                sb_aes_reinit(ictx, 1);
                        } else if (ccmd->header.tag == ROM_LOAD_CMD) {
                                sb_aes_crypt(ictx, cctx->data, cctx->data,
                                             cctx->length);
                                EVP_DigestUpdate(ictx->md_ctx, cctx->data,
                                                 cctx->length);
                        }

                        cctx = cctx->cmd;
                }

                sctx = sctx->sect;
        };

        /*
         * Dump the SHA1 of the whole image.
         */
        sb_aes_reinit(ictx, 1);

        EVP_DigestFinal(ictx->md_ctx, ictx->digest, NULL);
        EVP_MD_CTX_free(ictx->md_ctx);
        sb_aes_crypt(ictx, ictx->digest, ictx->digest, sizeof(ictx->digest));

        /* Stop the encryption session. */
        sb_aes_deinit(ictx->cipher_ctx);

        return 0;
}

static int sb_load_file(struct sb_cmd_ctx *cctx, char *filename)
{
        long real_size, roundup_size;
        uint8_t *data;
        long ret;
        unsigned long size;
        FILE *fp;

        if (!filename) {
                fprintf(stderr, "ERR: Missing filename!\n");
                return -EINVAL;
        }

        fp = fopen(filename, "r");
        if (!fp)
                goto err_open;

        ret = fseek(fp, 0, SEEK_END);
        if (ret < 0)
                goto err_file;

        real_size = ftell(fp);
        if (real_size < 0)
                goto err_file;

        ret = fseek(fp, 0, SEEK_SET);
        if (ret < 0)
                goto err_file;

        roundup_size = roundup(real_size, SB_BLOCK_SIZE);
        data = calloc(1, roundup_size);
        if (!data)
                goto err_file;

        size = fread(data, 1, real_size, fp);
        if (size != (unsigned long)real_size)
                goto err_alloc;

        cctx->data = data;
        cctx->length = roundup_size;

        fclose(fp);
        return 0;

err_alloc:
        free(data);
err_file:
        fclose(fp);
err_open:
        fprintf(stderr, "ERR: Failed to load file \"%s\"\n", filename);
        return -EINVAL;
}

static uint8_t sb_command_checksum(struct sb_command *inst)
{
        uint8_t *inst_ptr = (uint8_t *)inst;
        uint8_t csum = 0;
        unsigned int i;

        for (i = 0; i < sizeof(struct sb_command); i++)
                csum += inst_ptr[i];

        return csum;
}

static int sb_token_to_long(char *tok, uint32_t *rid)
{
        char *endptr;
        unsigned long id;

        if (tok[0] != '0' || tok[1] != 'x') {
                fprintf(stderr, "ERR: Invalid hexadecimal number!\n");
                return -EINVAL;
        }

        tok += 2;

        errno = 0;
        id = strtoul(tok, &endptr, 16);
        if ((errno == ERANGE && id == ULONG_MAX) || (errno != 0 && id == 0)) {
                fprintf(stderr, "ERR: Value can't be decoded!\n");
                return -EINVAL;
        }

        /* Check for 32-bit overflow. */
        if (id > 0xffffffff) {
                fprintf(stderr, "ERR: Value too big!\n");
                return -EINVAL;
        }

        if (endptr == tok) {
                fprintf(stderr, "ERR: Deformed value!\n");
                return -EINVAL;
        }

        *rid = (uint32_t)id;
        return 0;
}

static int sb_grow_dcd(struct sb_dcd_ctx *dctx, unsigned int inc_size)
{
        uint32_t *tmp;

        if (!inc_size)
                return 0;

        dctx->size += inc_size;
        tmp = realloc(dctx->payload, dctx->size);
        if (!tmp)
                return -ENOMEM;

        dctx->payload = tmp;

        /* Assemble and update the HAB DCD header. */
        dctx->payload[0] = htonl((SB_HAB_DCD_TAG << 24) |
                                 (dctx->size << 8) |
                                 SB_HAB_VERSION);

        return 0;
}

static int sb_build_dcd(struct sb_image_ctx *ictx, struct sb_cmd_list *cmd)
{
        struct sb_dcd_ctx *dctx;

        char *tok;
        uint32_t id;
        int ret;

        dctx = calloc(1, sizeof(*dctx));
        if (!dctx)
                return -ENOMEM;

        ret = sb_grow_dcd(dctx, 4);
        if (ret)
                goto err_dcd;

        /* Read DCD block number. */
        tok = strtok(cmd->cmd, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: DCD block without number!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err_dcd;
        }

        /* Parse the DCD block number. */
        ret = sb_token_to_long(tok, &id);
        if (ret) {
                fprintf(stderr, "#%i ERR: Malformed DCD block number!\n",
                        cmd->lineno);
                goto err_dcd;
        }

        dctx->id = id;

        /*
         * The DCD block is now constructed. Append it to the list.
         * WARNING: The DCD size is still not computed and will be
         * updated while parsing it's commands.
         */
        if (!ictx->dcd_head) {
                ictx->dcd_head = dctx;
                ictx->dcd_tail = dctx;
        } else {
                ictx->dcd_tail->dcd = dctx;
                ictx->dcd_tail = dctx;
        }

        return 0;

err_dcd:
        free(dctx->payload);
        free(dctx);
        return ret;
}

static int sb_build_dcd_block(struct sb_image_ctx *ictx,
                              struct sb_cmd_list *cmd,
                              uint32_t type)
{
        char *tok;
        uint32_t address, value, length;
        int ret;

        struct sb_dcd_ctx *dctx = ictx->dcd_tail;
        uint32_t *dcd;

        if (dctx->prev_dcd_head && (type != SB_DCD_NOOP) &&
            ((dctx->prev_dcd_head[0] & 0xff0000ff) == type)) {
                /* Same instruction as before, just append it. */
                ret = sb_grow_dcd(dctx, 8);
                if (ret)
                        return ret;
        } else if (type == SB_DCD_NOOP) {
                ret = sb_grow_dcd(dctx, 4);
                if (ret)
                        return ret;

                /* Update DCD command block pointer. */
                dctx->prev_dcd_head = dctx->payload +
                                dctx->size / sizeof(*dctx->payload) - 1;

                /* NOOP has only 4 bytes and no payload. */
                goto noop;
        } else {
                /*
                 * Either a different instruction block started now
                 * or this is the first instruction block.
                 */
                ret = sb_grow_dcd(dctx, 12);
                if (ret)
                        return ret;

                /* Update DCD command block pointer. */
                dctx->prev_dcd_head = dctx->payload +
                                dctx->size / sizeof(*dctx->payload) - 3;
        }

        dcd = dctx->payload + dctx->size / sizeof(*dctx->payload) - 2;

        /*
         * Prepare the command.
         */
        tok = strtok(cmd->cmd, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: Missing DCD address!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        /* Read DCD destination address. */
        ret = sb_token_to_long(tok, &address);
        if (ret) {
                fprintf(stderr, "#%i ERR: Incorrect DCD address!\n",
                        cmd->lineno);
                goto err;
        }

        tok = strtok(NULL, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: Missing DCD value!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        /* Read DCD operation value. */
        ret = sb_token_to_long(tok, &value);
        if (ret) {
                fprintf(stderr, "#%i ERR: Incorrect DCD value!\n",
                        cmd->lineno);
                goto err;
        }

        /* Fill in the new DCD entry. */
        dcd[0] = htonl(address);
        dcd[1] = htonl(value);

noop:
        /* Update the DCD command block. */
        length = dctx->size -
                 ((dctx->prev_dcd_head - dctx->payload) *
                 sizeof(*dctx->payload));
        dctx->prev_dcd_head[0] = htonl(type | (length << 8));

err:
        return ret;
}

static int sb_build_section(struct sb_image_ctx *ictx, struct sb_cmd_list *cmd)
{
        struct sb_section_ctx *sctx;
        struct sb_sections_header *shdr;
        char *tok;
        uint32_t bootable = 0;
        uint32_t id;
        int ret;

        sctx = calloc(1, sizeof(*sctx));
        if (!sctx)
                return -ENOMEM;

        /* Read section number. */
        tok = strtok(cmd->cmd, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: Section without number!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err_sect;
        }

        /* Parse the section number. */
        ret = sb_token_to_long(tok, &id);
        if (ret) {
                fprintf(stderr, "#%i ERR: Malformed section number!\n",
                        cmd->lineno);
                goto err_sect;
        }

        /* Read section's BOOTABLE flag. */
        tok = strtok(NULL, " ");
        if (tok && (strlen(tok) == 8) && !strncmp(tok, "BOOTABLE", 8))
                bootable = SB_SECTION_FLAG_BOOTABLE;

        sctx->boot = bootable;

        shdr = &sctx->payload;
        shdr->section_number = id;
        shdr->section_flags = bootable;

        /*
         * The section is now constructed. Append it to the list.
         * WARNING: The section size is still not computed and will
         * be updated while parsing it's commands.
         */
        ictx->sect_count++;

        /* Mark that this section is bootable one. */
        if (bootable) {
                if (ictx->sect_boot_found) {
                        fprintf(stderr,
                                "#%i WARN: Multiple bootable section!\n",
                                cmd->lineno);
                } else {
                        ictx->sect_boot = id;
                        ictx->sect_boot_found = 1;
                }
        }

        if (!ictx->sect_head) {
                ictx->sect_head = sctx;
                ictx->sect_tail = sctx;
        } else {
                ictx->sect_tail->sect = sctx;
                ictx->sect_tail = sctx;
        }

        return 0;

err_sect:
        free(sctx);
        return ret;
}

static int sb_build_command_nop(struct sb_image_ctx *ictx)
{
        struct sb_section_ctx *sctx = ictx->sect_tail;
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;

        cctx = calloc(1, sizeof(*cctx));
        if (!cctx)
                return -ENOMEM;

        ccmd = &cctx->payload;

        /*
         * Construct the command.
         */
        ccmd->header.checksum   = 0x5a;
        ccmd->header.tag        = ROM_NOP_CMD;

        cctx->size = sizeof(*ccmd);

        /*
         * Append the command to the last section.
         */
        if (!sctx->cmd_head) {
                sctx->cmd_head = cctx;
                sctx->cmd_tail = cctx;
        } else {
                sctx->cmd_tail->cmd = cctx;
                sctx->cmd_tail = cctx;
        }

        return 0;
}

static int sb_build_command_tag(struct sb_image_ctx *ictx,
                                struct sb_cmd_list *cmd)
{
        struct sb_section_ctx *sctx = ictx->sect_tail;
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;
        char *tok;

        cctx = calloc(1, sizeof(*cctx));
        if (!cctx)
                return -ENOMEM;

        ccmd = &cctx->payload;

        /*
         * Prepare the command.
         */
        /* Check for the LAST keyword. */
        tok = strtok(cmd->cmd, " ");
        if (tok && !strcmp(tok, "LAST"))
                ccmd->header.flags = ROM_TAG_CMD_FLAG_ROM_LAST_TAG;

        /*
         * Construct the command.
         */
        ccmd->header.checksum   = 0x5a;
        ccmd->header.tag        = ROM_TAG_CMD;

        cctx->size = sizeof(*ccmd);

        /*
         * Append the command to the last section.
         */
        if (!sctx->cmd_head) {
                sctx->cmd_head = cctx;
                sctx->cmd_tail = cctx;
        } else {
                sctx->cmd_tail->cmd = cctx;
                sctx->cmd_tail = cctx;
        }

        return 0;
}

static int sb_build_command_load(struct sb_image_ctx *ictx,
                                 struct sb_cmd_list *cmd)
{
        struct sb_section_ctx *sctx = ictx->sect_tail;
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;
        char *tok;
        int ret, is_ivt = 0, is_dcd = 0;
        uint32_t dest, dcd = 0;

        cctx = calloc(1, sizeof(*cctx));
        if (!cctx)
                return -ENOMEM;

        ccmd = &cctx->payload;

        /*
         * Prepare the command.
         */
        tok = strtok(cmd->cmd, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: Missing LOAD address or 'IVT'!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        /* Check for "IVT" flag. */
        if (!strcmp(tok, "IVT"))
                is_ivt = 1;
        if (!strcmp(tok, "DCD"))
                is_dcd = 1;
        if (is_ivt || is_dcd) {
                tok = strtok(NULL, " ");
                if (!tok) {
                        fprintf(stderr, "#%i ERR: Missing LOAD address!\n",
                                cmd->lineno);
                        ret = -EINVAL;
                        goto err;
                }
        }

        /* Read load destination address. */
        ret = sb_token_to_long(tok, &dest);
        if (ret) {
                fprintf(stderr, "#%i ERR: Incorrect LOAD address!\n",
                        cmd->lineno);
                goto err;
        }

        /* Read filename or IVT entrypoint or DCD block ID. */
        tok = strtok(NULL, " ");
        if (!tok) {
                fprintf(stderr,
                        "#%i ERR: Missing LOAD filename or IVT ep or DCD block ID!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        if (is_ivt) {
                /* Handle IVT. */
                struct sb_ivt_header *ivt;
                uint32_t ivtep;
                ret = sb_token_to_long(tok, &ivtep);

                if (ret) {
                        fprintf(stderr,
                                "#%i ERR: Incorrect IVT entry point!\n",
                                cmd->lineno);
                        goto err;
                }

                ivt = calloc(1, sizeof(*ivt));
                if (!ivt) {
                        ret = -ENOMEM;
                        goto err;
                }

                ivt->header = sb_hab_ivt_header();
                ivt->entry = ivtep;
                ivt->self = dest;

                cctx->data = (uint8_t *)ivt;
                cctx->length = sizeof(*ivt);
        } else if (is_dcd) {
                struct sb_dcd_ctx *dctx = ictx->dcd_head;
                uint32_t dcdid;
                uint8_t *payload;
                uint32_t asize;
                ret = sb_token_to_long(tok, &dcdid);

                if (ret) {
                        fprintf(stderr,
                                "#%i ERR: Incorrect DCD block ID!\n",
                                cmd->lineno);
                        goto err;
                }

                while (dctx) {
                        if (dctx->id == dcdid)
                                break;
                        dctx = dctx->dcd;
                }

                if (!dctx) {
                        fprintf(stderr, "#%i ERR: DCD block %08x not found!\n",
                                cmd->lineno, dcdid);
                        goto err;
                }

                asize = roundup(dctx->size, SB_BLOCK_SIZE);
                payload = calloc(1, asize);
                if (!payload) {
                        ret = -ENOMEM;
                        goto err;
                }

                memcpy(payload, dctx->payload, dctx->size);

                cctx->data = payload;
                cctx->length = asize;

                /* Set the Load DCD flag. */
                dcd = ROM_LOAD_CMD_FLAG_DCD_LOAD;
        } else {
                /* Regular LOAD of a file. */
                ret = sb_load_file(cctx, tok);
                if (ret) {
                        fprintf(stderr, "#%i ERR: Cannot load '%s'!\n",
                                cmd->lineno, tok);
                        goto err;
                }
        }

        if (cctx->length & (SB_BLOCK_SIZE - 1)) {
                fprintf(stderr, "#%i ERR: Unaligned payload!\n",
                        cmd->lineno);
        }

        /*
         * Construct the command.
         */
        ccmd->header.checksum   = 0x5a;
        ccmd->header.tag        = ROM_LOAD_CMD;
        ccmd->header.flags      = dcd;

        ccmd->load.address      = dest;
        ccmd->load.count        = cctx->length;
        ccmd->load.crc32        = pbl_crc32(0,
                                            (const char *)cctx->data,
                                            cctx->length);

        cctx->size = sizeof(*ccmd) + cctx->length;

        /*
         * Append the command to the last section.
         */
        if (!sctx->cmd_head) {
                sctx->cmd_head = cctx;
                sctx->cmd_tail = cctx;
        } else {
                sctx->cmd_tail->cmd = cctx;
                sctx->cmd_tail = cctx;
        }

        return 0;

err:
        free(cctx);
        return ret;
}

static int sb_build_command_fill(struct sb_image_ctx *ictx,
                                 struct sb_cmd_list *cmd)
{
        struct sb_section_ctx *sctx = ictx->sect_tail;
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;
        char *tok;
        uint32_t address, pattern, length;
        int ret;

        cctx = calloc(1, sizeof(*cctx));
        if (!cctx)
                return -ENOMEM;

        ccmd = &cctx->payload;

        /*
         * Prepare the command.
         */
        tok = strtok(cmd->cmd, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: Missing FILL address!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        /* Read fill destination address. */
        ret = sb_token_to_long(tok, &address);
        if (ret) {
                fprintf(stderr, "#%i ERR: Incorrect FILL address!\n",
                        cmd->lineno);
                goto err;
        }

        tok = strtok(NULL, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: Missing FILL pattern!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        /* Read fill pattern address. */
        ret = sb_token_to_long(tok, &pattern);
        if (ret) {
                fprintf(stderr, "#%i ERR: Incorrect FILL pattern!\n",
                        cmd->lineno);
                goto err;
        }

        tok = strtok(NULL, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: Missing FILL length!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        /* Read fill pattern address. */
        ret = sb_token_to_long(tok, &length);
        if (ret) {
                fprintf(stderr, "#%i ERR: Incorrect FILL length!\n",
                        cmd->lineno);
                goto err;
        }

        /*
         * Construct the command.
         */
        ccmd->header.checksum   = 0x5a;
        ccmd->header.tag        = ROM_FILL_CMD;

        ccmd->fill.address      = address;
        ccmd->fill.count        = length;
        ccmd->fill.pattern      = pattern;

        cctx->size = sizeof(*ccmd);

        /*
         * Append the command to the last section.
         */
        if (!sctx->cmd_head) {
                sctx->cmd_head = cctx;
                sctx->cmd_tail = cctx;
        } else {
                sctx->cmd_tail->cmd = cctx;
                sctx->cmd_tail = cctx;
        }

        return 0;

err:
        free(cctx);
        return ret;
}

static int sb_build_command_jump_call(struct sb_image_ctx *ictx,
                                      struct sb_cmd_list *cmd,
                                      unsigned int is_call)
{
        struct sb_section_ctx *sctx = ictx->sect_tail;
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;
        char *tok;
        uint32_t dest, arg = 0x0;
        uint32_t hab = 0;
        int ret;
        const char *cmdname = is_call ? "CALL" : "JUMP";

        cctx = calloc(1, sizeof(*cctx));
        if (!cctx)
                return -ENOMEM;

        ccmd = &cctx->payload;

        /*
         * Prepare the command.
         */
        tok = strtok(cmd->cmd, " ");
        if (!tok) {
                fprintf(stderr,
                        "#%i ERR: Missing %s address or 'HAB'!\n",
                        cmd->lineno, cmdname);
                ret = -EINVAL;
                goto err;
        }

        /* Check for "HAB" flag. */
        if (!strcmp(tok, "HAB")) {
                hab = is_call ? ROM_CALL_CMD_FLAG_HAB : ROM_JUMP_CMD_FLAG_HAB;
                tok = strtok(NULL, " ");
                if (!tok) {
                        fprintf(stderr, "#%i ERR: Missing %s address!\n",
                                cmd->lineno, cmdname);
                        ret = -EINVAL;
                        goto err;
                }
        }
        /* Read load destination address. */
        ret = sb_token_to_long(tok, &dest);
        if (ret) {
                fprintf(stderr, "#%i ERR: Incorrect %s address!\n",
                        cmd->lineno, cmdname);
                goto err;
        }

        tok = strtok(NULL, " ");
        if (tok) {
                ret = sb_token_to_long(tok, &arg);
                if (ret) {
                        fprintf(stderr,
                                "#%i ERR: Incorrect %s argument!\n",
                                cmd->lineno, cmdname);
                        goto err;
                }
        }

        /*
         * Construct the command.
         */
        ccmd->header.checksum   = 0x5a;
        ccmd->header.tag        = is_call ? ROM_CALL_CMD : ROM_JUMP_CMD;
        ccmd->header.flags      = hab;

        ccmd->call.address      = dest;
        ccmd->call.argument     = arg;

        cctx->size = sizeof(*ccmd);

        /*
         * Append the command to the last section.
         */
        if (!sctx->cmd_head) {
                sctx->cmd_head = cctx;
                sctx->cmd_tail = cctx;
        } else {
                sctx->cmd_tail->cmd = cctx;
                sctx->cmd_tail = cctx;
        }

        return 0;

err:
        free(cctx);
        return ret;
}

static int sb_build_command_jump(struct sb_image_ctx *ictx,
                                 struct sb_cmd_list *cmd)
{
        return sb_build_command_jump_call(ictx, cmd, 0);
}

static int sb_build_command_call(struct sb_image_ctx *ictx,
                                 struct sb_cmd_list *cmd)
{
        return sb_build_command_jump_call(ictx, cmd, 1);
}

static int sb_build_command_mode(struct sb_image_ctx *ictx,
                                 struct sb_cmd_list *cmd)
{
        struct sb_section_ctx *sctx = ictx->sect_tail;
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;
        char *tok;
        int ret;
        unsigned int i;
        uint32_t mode = 0xffffffff;

        cctx = calloc(1, sizeof(*cctx));
        if (!cctx)
                return -ENOMEM;

        ccmd = &cctx->payload;

        /*
         * Prepare the command.
         */
        tok = strtok(cmd->cmd, " ");
        if (!tok) {
                fprintf(stderr, "#%i ERR: Missing MODE boot mode argument!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        for (i = 0; i < ARRAY_SIZE(modetable); i++) {
                if (!strcmp(tok, modetable[i].name)) {
                        mode = modetable[i].mode;
                        break;
                }

                if (!modetable[i].altname)
                        continue;

                if (!strcmp(tok, modetable[i].altname)) {
                        mode = modetable[i].mode;
                        break;
                }
        }

        if (mode == 0xffffffff) {
                fprintf(stderr, "#%i ERR: Invalid MODE boot mode argument!\n",
                        cmd->lineno);
                ret = -EINVAL;
                goto err;
        }

        /*
         * Construct the command.
         */
        ccmd->header.checksum   = 0x5a;
        ccmd->header.tag        = ROM_MODE_CMD;

        ccmd->mode.mode         = mode;

        cctx->size = sizeof(*ccmd);

        /*
         * Append the command to the last section.
         */
        if (!sctx->cmd_head) {
                sctx->cmd_head = cctx;
                sctx->cmd_tail = cctx;
        } else {
                sctx->cmd_tail->cmd = cctx;
                sctx->cmd_tail = cctx;
        }

        return 0;

err:
        free(cctx);
        return ret;
}

static int sb_prefill_image_header(struct sb_image_ctx *ictx)
{
        struct sb_boot_image_header *hdr = &ictx->payload;

        /* Fill signatures */
        memcpy(hdr->signature1, "STMP", 4);
        memcpy(hdr->signature2, "sgtl", 4);

        /* SB Image version 1.1 */
        hdr->major_version = SB_VERSION_MAJOR;
        hdr->minor_version = SB_VERSION_MINOR;

        /* Boot image major version */
        hdr->product_version.major = htons(0x999);
        hdr->product_version.minor = htons(0x999);
        hdr->product_version.revision = htons(0x999);
        /* Boot image major version */
        hdr->component_version.major = htons(0x999);
        hdr->component_version.minor = htons(0x999);
        hdr->component_version.revision = htons(0x999);

        /* Drive tag must be 0x0 for i.MX23 */
        hdr->drive_tag = 0;

        hdr->header_blocks =
                sizeof(struct sb_boot_image_header) / SB_BLOCK_SIZE;
        hdr->section_header_size =
                sizeof(struct sb_sections_header) / SB_BLOCK_SIZE;
        hdr->timestamp_us = sb_get_timestamp() * 1000000;

        hdr->flags = ictx->display_progress ?
                SB_IMAGE_FLAG_DISPLAY_PROGRESS : 0;

        /* FIXME -- We support only default key */
        hdr->key_count = 1;

        return 0;
}

static int sb_postfill_image_header(struct sb_image_ctx *ictx)
{
        struct sb_boot_image_header *hdr = &ictx->payload;
        struct sb_section_ctx *sctx = ictx->sect_head;
        uint32_t kd_size, sections_blocks;
        EVP_MD_CTX *md_ctx;

        /* The main SB header size in blocks. */
        hdr->image_blocks = hdr->header_blocks;

        /* Size of the key dictionary, which has single zero entry. */
        kd_size = hdr->key_count * sizeof(struct sb_key_dictionary_key);
        hdr->image_blocks += kd_size / SB_BLOCK_SIZE;

        /* Now count the payloads. */
        hdr->section_count = ictx->sect_count;
        while (sctx) {
                hdr->image_blocks += sctx->size / SB_BLOCK_SIZE;
                sctx = sctx->sect;
        }

        if (!ictx->sect_boot_found) {
                fprintf(stderr, "ERR: No bootable section selected!\n");
                return -EINVAL;
        }
        hdr->first_boot_section_id = ictx->sect_boot;

        /* The n * SB section size in blocks. */
        sections_blocks = hdr->section_count * hdr->section_header_size;
        hdr->image_blocks += sections_blocks;

        /* Key dictionary offset. */
        hdr->key_dictionary_block = hdr->header_blocks + sections_blocks;

        /* Digest of the whole image. */
        hdr->image_blocks += 2;

        /* Pointer past the dictionary. */
        hdr->first_boot_tag_block =
                hdr->key_dictionary_block + kd_size / SB_BLOCK_SIZE;

        /* Compute header digest. */
        md_ctx = EVP_MD_CTX_new();

        EVP_DigestInit(md_ctx, EVP_sha1());
        EVP_DigestUpdate(md_ctx, hdr->signature1,
                         sizeof(struct sb_boot_image_header) -
                         sizeof(hdr->digest));
        EVP_DigestFinal(md_ctx, hdr->digest, NULL);
        EVP_MD_CTX_free(md_ctx);

        return 0;
}

static int sb_fixup_sections_and_tags(struct sb_image_ctx *ictx)
{
        /* Fixup the placement of sections. */
        struct sb_boot_image_header *ihdr = &ictx->payload;
        struct sb_section_ctx *sctx = ictx->sect_head;
        struct sb_sections_header *shdr;
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;
        uint32_t offset = ihdr->first_boot_tag_block;

        while (sctx) {
                shdr = &sctx->payload;

                /* Fill in the section TAG offset. */
                shdr->section_offset = offset + 1;
                offset += shdr->section_size;

                /* Section length is measured from the TAG block. */
                shdr->section_size--;

                /* Fixup the TAG command. */
                cctx = sctx->cmd_head;
                while (cctx) {
                        ccmd = &cctx->payload;
                        if (ccmd->header.tag == ROM_TAG_CMD) {
                                ccmd->tag.section_number = shdr->section_number;
                                ccmd->tag.section_length = shdr->section_size;
                                ccmd->tag.section_flags = shdr->section_flags;
                        }

                        /* Update the command checksum. */
                        ccmd->header.checksum = sb_command_checksum(ccmd);

                        cctx = cctx->cmd;
                }

                sctx = sctx->sect;
        }

        return 0;
}

static int sb_parse_line(struct sb_image_ctx *ictx, struct sb_cmd_list *cmd)
{
        char *tok;
        char *line = cmd->cmd;
        char *rptr = NULL;
        int ret;

        /* Analyze the identifier on this line first. */
        tok = strtok_r(line, " ", &rptr);
        if (!tok || (strlen(tok) == 0)) {
                fprintf(stderr, "#%i ERR: Invalid line!\n", cmd->lineno);
                return -EINVAL;
        }

        cmd->cmd = rptr;

        /* set DISPLAY_PROGRESS flag */
        if (!strcmp(tok, "DISPLAYPROGRESS")) {
                ictx->display_progress = 1;
                return 0;
        }

        /* DCD */
        if (!strcmp(tok, "DCD")) {
                ictx->in_section = 0;
                ictx->in_dcd = 1;
                sb_build_dcd(ictx, cmd);
                return 0;
        }

        /* Section */
        if (!strcmp(tok, "SECTION")) {
                ictx->in_section = 1;
                ictx->in_dcd = 0;
                sb_build_section(ictx, cmd);
                return 0;
        }

        if (!ictx->in_section && !ictx->in_dcd) {
                fprintf(stderr, "#%i ERR: Data outside of a section!\n",
                        cmd->lineno);
                return -EINVAL;
        }

        if (ictx->in_section) {
                /* Section commands */
                if (!strcmp(tok, "NOP")) {
                        ret = sb_build_command_nop(ictx);
                } else if (!strcmp(tok, "TAG")) {
                        ret = sb_build_command_tag(ictx, cmd);
                } else if (!strcmp(tok, "LOAD")) {
                        ret = sb_build_command_load(ictx, cmd);
                } else if (!strcmp(tok, "FILL")) {
                        ret = sb_build_command_fill(ictx, cmd);
                } else if (!strcmp(tok, "JUMP")) {
                        ret = sb_build_command_jump(ictx, cmd);
                } else if (!strcmp(tok, "CALL")) {
                        ret = sb_build_command_call(ictx, cmd);
                } else if (!strcmp(tok, "MODE")) {
                        ret = sb_build_command_mode(ictx, cmd);
                } else {
                        fprintf(stderr,
                                "#%i ERR: Unsupported instruction '%s'!\n",
                                cmd->lineno, tok);
                        return -ENOTSUP;
                }
        } else if (ictx->in_dcd) {
                char *lptr;
                uint32_t ilen = '1';

                tok = strtok_r(tok, ".", &lptr);
                if (!tok || (strlen(tok) == 0) || (lptr && strlen(lptr) != 1)) {
                        fprintf(stderr, "#%i ERR: Invalid line!\n",
                                cmd->lineno);
                        return -EINVAL;
                }

                if (lptr &&
                    (lptr[0] != '1' && lptr[0] != '2' && lptr[0] != '4')) {
                        fprintf(stderr, "#%i ERR: Invalid instruction width!\n",
                                cmd->lineno);
                        return -EINVAL;
                }

                if (lptr)
                        ilen = lptr[0] - '1';

                /* DCD commands */
                if (!strcmp(tok, "WRITE")) {
                        ret = sb_build_dcd_block(ictx, cmd,
                                                 SB_DCD_WRITE | ilen);
                } else if (!strcmp(tok, "ANDC")) {
                        ret = sb_build_dcd_block(ictx, cmd,
                                                 SB_DCD_ANDC | ilen);
                } else if (!strcmp(tok, "ORR")) {
                        ret = sb_build_dcd_block(ictx, cmd,
                                                 SB_DCD_ORR | ilen);
                } else if (!strcmp(tok, "EQZ")) {
                        ret = sb_build_dcd_block(ictx, cmd,
                                                 SB_DCD_CHK_EQZ | ilen);
                } else if (!strcmp(tok, "EQ")) {
                        ret = sb_build_dcd_block(ictx, cmd,
                                                 SB_DCD_CHK_EQ | ilen);
                } else if (!strcmp(tok, "NEQ")) {
                        ret = sb_build_dcd_block(ictx, cmd,
                                                 SB_DCD_CHK_NEQ | ilen);
                } else if (!strcmp(tok, "NEZ")) {
                        ret = sb_build_dcd_block(ictx, cmd,
                                                 SB_DCD_CHK_NEZ | ilen);
                } else if (!strcmp(tok, "NOOP")) {
                        ret = sb_build_dcd_block(ictx, cmd, SB_DCD_NOOP);
                } else {
                        fprintf(stderr,
                                "#%i ERR: Unsupported instruction '%s'!\n",
                                cmd->lineno, tok);
                        return -ENOTSUP;
                }
        } else {
                fprintf(stderr, "#%i ERR: Unsupported instruction '%s'!\n",
                        cmd->lineno, tok);
                return -ENOTSUP;
        }

        /*
         * Here we have at least one section with one command, otherwise we
         * would have failed already higher above.
         *
         * FIXME -- should the updating happen here ?
         */
        if (ictx->in_section && !ret) {
                ictx->sect_tail->size += ictx->sect_tail->cmd_tail->size;
                ictx->sect_tail->payload.section_size =
                        ictx->sect_tail->size / SB_BLOCK_SIZE;
        }

        return ret;
}

static int sb_load_cmdfile(struct sb_image_ctx *ictx)
{
        struct sb_cmd_list cmd;
        int lineno = 1;
        FILE *fp;
        char *line = NULL;
        ssize_t rlen;
        size_t len;

        fp = fopen(ictx->cfg_filename, "r");
        if (!fp)
                goto err_file;

        while ((rlen = getline(&line, &len, fp)) > 0) {
                memset(&cmd, 0, sizeof(cmd));

                /* Strip the trailing newline. */
                line[rlen - 1] = '\0';

                cmd.cmd = line;
                cmd.len = rlen;
                cmd.lineno = lineno++;

                sb_parse_line(ictx, &cmd);
        }

        free(line);

        fclose(fp);

        return 0;

err_file:
        fclose(fp);
        fprintf(stderr, "ERR: Failed to load file \"%s\"\n",
                ictx->cfg_filename);
        return -EINVAL;
}

static int sb_build_tree_from_cfg(struct sb_image_ctx *ictx)
{
        int ret;

        ret = sb_load_cmdfile(ictx);
        if (ret)
                return ret;

        ret = sb_prefill_image_header(ictx);
        if (ret)
                return ret;

        ret = sb_postfill_image_header(ictx);
        if (ret)
                return ret;

        ret = sb_fixup_sections_and_tags(ictx);
        if (ret)
                return ret;

        return 0;
}

static int sb_verify_image_header(struct sb_image_ctx *ictx,
                                  FILE *fp, long fsize)
{
        /* Verify static fields in the image header. */
        struct sb_boot_image_header *hdr = &ictx->payload;
        const char *stat[2] = { "[PASS]", "[FAIL]" };
        struct tm tm;
        int sz, ret = 0;
        unsigned char digest[20];
        EVP_MD_CTX *md_ctx;
        unsigned long size;

        /* Start image-wide crypto. */
        ictx->md_ctx = EVP_MD_CTX_new();
        EVP_DigestInit(ictx->md_ctx, EVP_sha1());

        soprintf(ictx, "---------- Verifying SB Image Header ----------\n");

        size = fread(&ictx->payload, 1, sizeof(ictx->payload), fp);
        if (size != sizeof(ictx->payload)) {
                fprintf(stderr, "ERR: SB image header too short!\n");
                return -EINVAL;
        }

        /* Compute header digest. */
        md_ctx = EVP_MD_CTX_new();
        EVP_DigestInit(md_ctx, EVP_sha1());
        EVP_DigestUpdate(md_ctx, hdr->signature1,
                         sizeof(struct sb_boot_image_header) -
                         sizeof(hdr->digest));
        EVP_DigestFinal(md_ctx, digest, NULL);
        EVP_MD_CTX_free(md_ctx);

        sb_aes_init(ictx, NULL, 1);
        sb_encrypt_sb_header(ictx);

        if (memcmp(digest, hdr->digest, 20))
                ret = -EINVAL;
        soprintf(ictx, "%s Image header checksum:        %s\n", stat[!!ret],
                 ret ? "BAD" : "OK");
        if (ret)
                return ret;

        if (memcmp(hdr->signature1, "STMP", 4) ||
            memcmp(hdr->signature2, "sgtl", 4))
                ret = -EINVAL;
        soprintf(ictx, "%s Signatures:                   '%.4s' '%.4s'\n",
                 stat[!!ret], hdr->signature1, hdr->signature2);
        if (ret)
                return ret;

        if ((hdr->major_version != SB_VERSION_MAJOR) ||
            ((hdr->minor_version != 1) && (hdr->minor_version != 2)))
                ret = -EINVAL;
        soprintf(ictx, "%s Image version:                v%i.%i\n", stat[!!ret],
                 hdr->major_version, hdr->minor_version);
        if (ret)
                return ret;

        ret = sb_get_time(hdr->timestamp_us / 1000000, &tm);
        soprintf(ictx,
                 "%s Creation time:                %02i:%02i:%02i %02i/%02i/%04i\n",
                 stat[!!ret], tm.tm_hour, tm.tm_min, tm.tm_sec,
                 tm.tm_mday, tm.tm_mon, tm.tm_year + 2000);
        if (ret)
                return ret;

        soprintf(ictx, "%s Product version:              %x.%x.%x\n", stat[0],
                 ntohs(hdr->product_version.major),
                 ntohs(hdr->product_version.minor),
                 ntohs(hdr->product_version.revision));
        soprintf(ictx, "%s Component version:            %x.%x.%x\n", stat[0],
                 ntohs(hdr->component_version.major),
                 ntohs(hdr->component_version.minor),
                 ntohs(hdr->component_version.revision));

        if (hdr->flags & ~SB_IMAGE_FLAGS_MASK)
                ret = -EINVAL;
        soprintf(ictx, "%s Image flags:                  %s\n", stat[!!ret],
                 hdr->flags & SB_IMAGE_FLAG_DISPLAY_PROGRESS ?
                 "Display_progress" : "");
        if (ret)
                return ret;

        if (hdr->drive_tag != 0)
                ret = -EINVAL;
        soprintf(ictx, "%s Drive tag:                    %i\n", stat[!!ret],
                 hdr->drive_tag);
        if (ret)
                return ret;

        sz = sizeof(struct sb_boot_image_header) / SB_BLOCK_SIZE;
        if (hdr->header_blocks != sz)
                ret = -EINVAL;
        soprintf(ictx, "%s Image header size (blocks):   %i\n", stat[!!ret],
                 hdr->header_blocks);
        if (ret)
                return ret;

        sz = sizeof(struct sb_sections_header) / SB_BLOCK_SIZE;
        if (hdr->section_header_size != sz)
                ret = -EINVAL;
        soprintf(ictx, "%s Section header size (blocks): %i\n", stat[!!ret],
                 hdr->section_header_size);
        if (ret)
                return ret;

        soprintf(ictx, "%s Sections count:               %i\n", stat[!!ret],
                 hdr->section_count);
        soprintf(ictx, "%s First bootable section        %i\n", stat[!!ret],
                 hdr->first_boot_section_id);

        if (hdr->image_blocks != fsize / SB_BLOCK_SIZE)
                ret = -EINVAL;
        soprintf(ictx, "%s Image size (blocks):          %i\n", stat[!!ret],
                 hdr->image_blocks);
        if (ret)
                return ret;

        sz = hdr->header_blocks + hdr->section_header_size * hdr->section_count;
        if (hdr->key_dictionary_block != sz)
                ret = -EINVAL;
        soprintf(ictx, "%s Key dict offset (blocks):     %i\n", stat[!!ret],
                 hdr->key_dictionary_block);
        if (ret)
                return ret;

        if (hdr->key_count != 1)
                ret = -EINVAL;
        soprintf(ictx, "%s Number of encryption keys:    %i\n", stat[!!ret],
                 hdr->key_count);
        if (ret)
                return ret;

        sz = hdr->header_blocks + hdr->section_header_size * hdr->section_count;
        sz += hdr->key_count *
                sizeof(struct sb_key_dictionary_key) / SB_BLOCK_SIZE;
        if (hdr->first_boot_tag_block != (unsigned)sz)
                ret = -EINVAL;
        soprintf(ictx, "%s First TAG block (blocks):     %i\n", stat[!!ret],
                 hdr->first_boot_tag_block);
        if (ret)
                return ret;

        return 0;
}

static void sb_decrypt_tag(struct sb_image_ctx *ictx,
                struct sb_cmd_ctx *cctx)
{
        EVP_MD_CTX *md_ctx = ictx->md_ctx;
        struct sb_command *cmd = &cctx->payload;

        sb_aes_crypt(ictx, (uint8_t *)&cctx->c_payload,
                     (uint8_t *)&cctx->payload, sizeof(*cmd));
        EVP_DigestUpdate(md_ctx, &cctx->c_payload, sizeof(*cmd));
}

static int sb_verify_command(struct sb_image_ctx *ictx,
                             struct sb_cmd_ctx *cctx, FILE *fp,
                             unsigned long *tsize)
{
        struct sb_command *ccmd = &cctx->payload;
        unsigned long size, asize;
        char *csum, *flag = "";
        int ret;
        unsigned int i;
        uint8_t csn, csc = ccmd->header.checksum;
        ccmd->header.checksum = 0x5a;
        csn = sb_command_checksum(ccmd);
        ccmd->header.checksum = csc;

        if (csc == csn)
                ret = 0;
        else
                ret = -EINVAL;
        csum = ret ? "checksum BAD" : "checksum OK";

        switch (ccmd->header.tag) {
        case ROM_NOP_CMD:
                soprintf(ictx, " NOOP # %s\n", csum);
                return ret;
        case ROM_TAG_CMD:
                if (ccmd->header.flags & ROM_TAG_CMD_FLAG_ROM_LAST_TAG)
                        flag = "LAST";
                soprintf(ictx, " TAG %s # %s\n", flag, csum);
                sb_aes_reinit(ictx, 0);
                return ret;
        case ROM_LOAD_CMD:
                soprintf(ictx, " LOAD addr=0x%08x length=0x%08x # %s\n",
                         ccmd->load.address, ccmd->load.count, csum);

                cctx->length = ccmd->load.count;
                asize = roundup(cctx->length, SB_BLOCK_SIZE);
                cctx->data = malloc(asize);
                if (!cctx->data)
                        return -ENOMEM;

                size = fread(cctx->data, 1, asize, fp);
                if (size != asize) {
                        fprintf(stderr,
                                "ERR: SB LOAD command payload too short!\n");
                        return -EINVAL;
                }

                *tsize += size;

                EVP_DigestUpdate(ictx->md_ctx, cctx->data, asize);
                sb_aes_crypt(ictx, cctx->data, cctx->data, asize);

                if (ccmd->load.crc32 != pbl_crc32(0,
                                                  (const char *)cctx->data,
                                                  asize)) {
                        fprintf(stderr,
                                "ERR: SB LOAD command payload CRC32 invalid!\n");
                        return -EINVAL;
                }
                return 0;
        case ROM_FILL_CMD:
                soprintf(ictx,
                         " FILL addr=0x%08x length=0x%08x pattern=0x%08x # %s\n",
                         ccmd->fill.address, ccmd->fill.count,
                         ccmd->fill.pattern, csum);
                return 0;
        case ROM_JUMP_CMD:
                if (ccmd->header.flags & ROM_JUMP_CMD_FLAG_HAB)
                        flag = " HAB";
                soprintf(ictx,
                         " JUMP%s addr=0x%08x r0_arg=0x%08x # %s\n",
                         flag, ccmd->fill.address, ccmd->jump.argument, csum);
                return 0;
        case ROM_CALL_CMD:
                if (ccmd->header.flags & ROM_CALL_CMD_FLAG_HAB)
                        flag = " HAB";
                soprintf(ictx,
                         " CALL%s addr=0x%08x r0_arg=0x%08x # %s\n",
                         flag, ccmd->fill.address, ccmd->jump.argument, csum);
                return 0;
        case ROM_MODE_CMD:
                for (i = 0; i < ARRAY_SIZE(modetable); i++) {
                        if (ccmd->mode.mode == modetable[i].mode) {
                                soprintf(ictx, " MODE %s # %s\n",
                                         modetable[i].name, csum);
                                break;
                        }
                }
                fprintf(stderr, " MODE !INVALID! # %s\n", csum);
                return 0;
        }

        return ret;
}

static int sb_verify_commands(struct sb_image_ctx *ictx,
                              struct sb_section_ctx *sctx, FILE *fp)
{
        unsigned long size, tsize = 0;
        struct sb_cmd_ctx *cctx;
        int ret;

        sb_aes_reinit(ictx, 0);

        while (tsize < sctx->size) {
                cctx = calloc(1, sizeof(*cctx));
                if (!cctx)
                        return -ENOMEM;
                if (!sctx->cmd_head) {
                        sctx->cmd_head = cctx;
                        sctx->cmd_tail = cctx;
                } else {
                        sctx->cmd_tail->cmd = cctx;
                        sctx->cmd_tail = cctx;
                }

                size = fread(&cctx->c_payload, 1, sizeof(cctx->c_payload), fp);
                if (size != sizeof(cctx->c_payload)) {
                        fprintf(stderr, "ERR: SB command header too short!\n");
                        return -EINVAL;
                }

                tsize += size;

                sb_decrypt_tag(ictx, cctx);

                ret = sb_verify_command(ictx, cctx, fp, &tsize);
                if (ret)
                        return -EINVAL;
        }

        return 0;
}

static int sb_verify_sections_cmds(struct sb_image_ctx *ictx, FILE *fp)
{
        struct sb_boot_image_header *hdr = &ictx->payload;
        struct sb_sections_header *shdr;
        unsigned int i;
        int ret;
        struct sb_section_ctx *sctx;
        unsigned long size;
        char *bootable = "";

        soprintf(ictx, "----- Verifying  SB Sections and Commands -----\n");

        for (i = 0; i < hdr->section_count; i++) {
                sctx = calloc(1, sizeof(*sctx));
                if (!sctx)
                        return -ENOMEM;
                if (!ictx->sect_head) {
                        ictx->sect_head = sctx;
                        ictx->sect_tail = sctx;
                } else {
                        ictx->sect_tail->sect = sctx;
                        ictx->sect_tail = sctx;
                }

                size = fread(&sctx->payload, 1, sizeof(sctx->payload), fp);
                if (size != sizeof(sctx->payload)) {
                        fprintf(stderr, "ERR: SB section header too short!\n");
                        return -EINVAL;
                }
        }

        size = fread(&ictx->sb_dict_key, 1, sizeof(ictx->sb_dict_key), fp);
        if (size != sizeof(ictx->sb_dict_key)) {
                fprintf(stderr, "ERR: SB key dictionary too short!\n");
                return -EINVAL;
        }

        sb_encrypt_sb_sections_header(ictx);
        sb_aes_reinit(ictx, 0);
        sb_decrypt_key_dictionary_key(ictx);

        sb_aes_reinit(ictx, 0);

        sctx = ictx->sect_head;
        while (sctx) {
                shdr = &sctx->payload;

                if (shdr->section_flags & SB_SECTION_FLAG_BOOTABLE) {
                        sctx->boot = 1;
                        bootable = " BOOTABLE";
                }

                sctx->size = (shdr->section_size * SB_BLOCK_SIZE) +
                             sizeof(struct sb_command);
                soprintf(ictx, "SECTION 0x%x%s # size = %i bytes\n",
                         shdr->section_number, bootable, sctx->size);

                if (shdr->section_flags & ~SB_SECTION_FLAG_BOOTABLE)
                        fprintf(stderr, " WARN: Unknown section flag(s) %08x\n",
                                shdr->section_flags);

                if ((shdr->section_flags & SB_SECTION_FLAG_BOOTABLE) &&
                    (hdr->first_boot_section_id != shdr->section_number)) {
                        fprintf(stderr,
                                " WARN: Bootable section does ID not match image header ID!\n");
                }

                ret = sb_verify_commands(ictx, sctx, fp);
                if (ret)
                        return ret;

                sctx = sctx->sect;
        }

        /*
         * FIXME IDEA:
         * check if the first TAG command is at sctx->section_offset
         */
        return 0;
}

static int sb_verify_image_end(struct sb_image_ctx *ictx,
                               FILE *fp, off_t filesz)
{
        uint8_t digest[32];
        unsigned long size;
        off_t pos;
        int ret;

        soprintf(ictx, "------------- Verifying image end -------------\n");

        size = fread(digest, 1, sizeof(digest), fp);
        if (size != sizeof(digest)) {
                fprintf(stderr, "ERR: SB key dictionary too short!\n");
                return -EINVAL;
        }

        pos = ftell(fp);
        if (pos != filesz) {
                fprintf(stderr, "ERR: Trailing data past the image!\n");
                return -EINVAL;
        }

        /* Check the image digest. */
        EVP_DigestFinal(ictx->md_ctx, ictx->digest, NULL);
        EVP_MD_CTX_free(ictx->md_ctx);

        /* Decrypt the image digest from the input image. */
        sb_aes_reinit(ictx, 0);
        sb_aes_crypt(ictx, digest, digest, sizeof(digest));

        /* Check all of 20 bytes of the SHA1 hash. */
        ret = memcmp(digest, ictx->digest, 20) ? -EINVAL : 0;

        if (ret)
                soprintf(ictx, "[FAIL] Full-image checksum:          BAD\n");
        else
                soprintf(ictx, "[PASS] Full-image checksum:          OK\n");

        return ret;
}


static int sb_build_tree_from_img(struct sb_image_ctx *ictx)
{
        long filesize;
        int ret;
        FILE *fp;

        if (!ictx->input_filename) {
                fprintf(stderr, "ERR: Missing filename!\n");
                return -EINVAL;
        }

        fp = fopen(ictx->input_filename, "r");
        if (!fp)
                goto err_open;

        ret = fseek(fp, 0, SEEK_END);
        if (ret < 0)
                goto err_file;

        filesize = ftell(fp);
        if (filesize < 0)
                goto err_file;

        ret = fseek(fp, 0, SEEK_SET);
        if (ret < 0)
                goto err_file;

        if (filesize < (signed)sizeof(ictx->payload)) {
                fprintf(stderr, "ERR: File too short!\n");
                goto err_file;
        }

        if (filesize & (SB_BLOCK_SIZE - 1)) {
                fprintf(stderr, "ERR: The file is not aligned!\n");
                goto err_file;
        }

        /* Load and verify image header */
        ret = sb_verify_image_header(ictx, fp, filesize);
        if (ret)
                goto err_verify;

        /* Load and verify sections and commands */
        ret = sb_verify_sections_cmds(ictx, fp);
        if (ret)
                goto err_verify;

        ret = sb_verify_image_end(ictx, fp, filesize);
        if (ret)
                goto err_verify;

        ret = 0;

err_verify:
        soprintf(ictx, "-------------------- Result -------------------\n");
        soprintf(ictx, "Verification %s\n", ret ? "FAILED" : "PASSED");

        /* Stop the encryption session. */
        sb_aes_deinit(ictx->cipher_ctx);

        fclose(fp);
        return ret;

err_file:
        fclose(fp);
err_open:
        fprintf(stderr, "ERR: Failed to load file \"%s\"\n",
                ictx->input_filename);
        return -EINVAL;
}

static void sb_free_image(struct sb_image_ctx *ictx)
{
        struct sb_section_ctx *sctx = ictx->sect_head, *s_head;
        struct sb_dcd_ctx *dctx = ictx->dcd_head, *d_head;
        struct sb_cmd_ctx *cctx, *c_head;

        while (sctx) {
                s_head = sctx;
                c_head = sctx->cmd_head;

                while (c_head) {
                        cctx = c_head;
                        c_head = c_head->cmd;
                        if (cctx->data)
                                free(cctx->data);
                        free(cctx);
                }

                sctx = sctx->sect;
                free(s_head);
        }

        while (dctx) {
                d_head = dctx;
                dctx = dctx->dcd;
                free(d_head->payload);
                free(d_head);
        }
}

/*
 * MXSSB-MKIMAGE glue code.
 */
static int mxsimage_check_image_types(uint8_t type)
{
        if (type == IH_TYPE_MXSIMAGE)
                return EXIT_SUCCESS;
        else
                return EXIT_FAILURE;
}

static void mxsimage_set_header(void *ptr, struct stat *sbuf, int ifd,
                                struct image_tool_params *params)
{
}

int mxsimage_check_params(struct image_tool_params *params)
{
        if (!params)
                return -1;
        if (!strlen(params->imagename)) {
                fprintf(stderr,
                        "Error: %s - Configuration file not specified, it is needed for mxsimage generation\n",
                        params->cmdname);
                return -1;
        }

        /*
         * Check parameters:
         * XIP is not allowed and verify that incompatible
         * parameters are not sent at the same time
         * For example, if list is required a data image must not be provided
         */
        return  (params->dflag && (params->fflag || params->lflag)) ||
                (params->fflag && (params->dflag || params->lflag)) ||
                (params->lflag && (params->dflag || params->fflag)) ||
                (params->xflag) || !(strlen(params->imagename));
}

static int mxsimage_verify_print_header(char *file, int silent)
{
        int ret;
        struct sb_image_ctx ctx;

        memset(&ctx, 0, sizeof(ctx));

        ctx.input_filename = file;
        ctx.silent_dump = silent;

        ret = sb_build_tree_from_img(&ctx);
        sb_free_image(&ctx);

        return ret;
}

char *imagefile;
static int mxsimage_verify_header(unsigned char *ptr, int image_size,
                        struct image_tool_params *params)
{
        struct sb_boot_image_header *hdr;

        if (!ptr)
                return -EINVAL;

        hdr = (struct sb_boot_image_header *)ptr;

        /*
         * Check if the header contains the MXS image signatures,
         * if so, do a full-image verification.
         */
        if (memcmp(hdr->signature1, "STMP", 4) ||
            memcmp(hdr->signature2, "sgtl", 4))
                return -EINVAL;

        imagefile = params->imagefile;

        return mxsimage_verify_print_header(params->imagefile, 1);
}

static void mxsimage_print_header(const void *hdr)
{
        if (imagefile)
                mxsimage_verify_print_header(imagefile, 0);
}

static int sb_build_image(struct sb_image_ctx *ictx,
                          struct image_type_params *tparams)
{
        struct sb_boot_image_header *sb_header = &ictx->payload;
        struct sb_section_ctx *sctx;
        struct sb_cmd_ctx *cctx;
        struct sb_command *ccmd;
        struct sb_key_dictionary_key *sb_dict_key = &ictx->sb_dict_key;

        uint8_t *image, *iptr;

        /* Calculate image size. */
        uint32_t size = sizeof(*sb_header) +
                ictx->sect_count * sizeof(struct sb_sections_header) +
                sizeof(*sb_dict_key) + sizeof(ictx->digest);

        sctx = ictx->sect_head;
        while (sctx) {
                size += sctx->size;
                sctx = sctx->sect;
        };

        image = malloc(size);
        if (!image)
                return -ENOMEM;
        iptr = image;

        memcpy(iptr, sb_header, sizeof(*sb_header));
        iptr += sizeof(*sb_header);

        sctx = ictx->sect_head;
        while (sctx) {
                memcpy(iptr, &sctx->payload, sizeof(struct sb_sections_header));
                iptr += sizeof(struct sb_sections_header);
                sctx = sctx->sect;
        };

        memcpy(iptr, sb_dict_key, sizeof(*sb_dict_key));
        iptr += sizeof(*sb_dict_key);

        sctx = ictx->sect_head;
        while (sctx) {
                cctx = sctx->cmd_head;
                while (cctx) {
                        ccmd = &cctx->payload;

                        memcpy(iptr, &cctx->c_payload, sizeof(cctx->payload));
                        iptr += sizeof(cctx->payload);

                        if (ccmd->header.tag == ROM_LOAD_CMD) {
                                memcpy(iptr, cctx->data, cctx->length);
                                iptr += cctx->length;
                        }

                        cctx = cctx->cmd;
                }

                sctx = sctx->sect;
        };

        memcpy(iptr, ictx->digest, sizeof(ictx->digest));
        iptr += sizeof(ictx->digest);

        /* Configure the mkimage */
        tparams->hdr = image;
        tparams->header_size = size;

        return 0;
}

static int mxsimage_generate(struct image_tool_params *params,
        struct image_type_params *tparams)
{
        int ret;
        struct sb_image_ctx ctx;

        /* Do not copy the U-Boot image! */
        params->skipcpy = 1;

        memset(&ctx, 0, sizeof(ctx));

        ctx.cfg_filename = params->imagename;
        ctx.output_filename = params->imagefile;

        ret = sb_build_tree_from_cfg(&ctx);
        if (ret)
                goto fail;

        ret = sb_encrypt_image(&ctx);
        if (!ret)
                ret = sb_build_image(&ctx, tparams);

fail:
        sb_free_image(&ctx);

        return ret;
}

/*
 * mxsimage parameters
 */
U_BOOT_IMAGE_TYPE(
        mxsimage,
        "Freescale MXS Boot Image support",
        0,
        NULL,
        mxsimage_check_params,
        mxsimage_verify_header,
        mxsimage_print_header,
        mxsimage_set_header,
        NULL,
        mxsimage_check_image_types,
        NULL,
        mxsimage_generate
);
#endif