Files
Project_CTR/ctrtool/ivfc.c
T

248 lines
6.1 KiB
C

#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include "types.h"
#include "utils.h"
#include "ivfc.h"
#include "ctr.h"
void ivfc_init(ivfc_context* ctx)
{
memset(ctx, 0, sizeof(ivfc_context));
}
void ivfc_set_usersettings(ivfc_context* ctx, settings* usersettings)
{
ctx->usersettings = usersettings;
}
void ivfc_set_offset(ivfc_context* ctx, u64 offset)
{
ctx->offset = offset;
}
void ivfc_set_size(ivfc_context* ctx, u64 size)
{
ctx->size = size;
}
void ivfc_set_file(ivfc_context* ctx, FILE* file)
{
ctx->file = file;
}
void ivfc_set_encrypted(ivfc_context* ctx, u32 encrypted)
{
ctx->encrypted = encrypted;
}
void ivfc_set_key(ivfc_context* ctx, u8 key[16])
{
ctr_init_key(&ctx->aes, key);
}
void ivfc_set_counter(ivfc_context* ctx, u8 counter[16])
{
memcpy(ctx->counter, counter, 16);
}
void ivfc_fseek(ivfc_context* ctx, u64 offset)
{
u64 data_pos = offset - ctx->offset;
fseeko64(ctx->file, offset, SEEK_SET);
if (ctx->encrypted) {
//printf("start fseek encrypted prep\n");
ctr_init_counter(&ctx->aes, ctx->counter);
//printf("middle fseek encrypted prep\n");
ctr_add_counter(&ctx->aes, (u32)(data_pos / 0x10));
//printf("finish fseek encrypted prep\n");
}
}
size_t ivfc_fread(ivfc_context* ctx, void* buffer, size_t size, size_t count)
{
size_t read;
if ((read = fread(buffer, size, count, ctx->file)) != count) {
//printf("ivfc_fread() fail\n");
return read;
}
if (ctx->encrypted) {
ctr_crypt_counter(&ctx->aes, buffer, buffer, size*read);
}
return read;
}
void ivfc_process(ivfc_context* ctx, u32 actions)
{
ivfc_fseek(ctx, ctx->offset);
ivfc_fread(ctx, &ctx->header, 1, sizeof(ivfc_header));
if (getle32(ctx->header.magic) != MAGIC_IVFC)
{
fprintf(stdout, "Error, IVFC segment corrupted\n");
return;
}
if (getle32(ctx->header.id) == 0x10000)
{
ctx->levelcount = 3;
ctx->level[2].hashblocksize = 1 << getle32(ctx->header.level3.blocksize);
ctx->level[1].hashblocksize = 1 << getle32(ctx->header.level2.blocksize);
ctx->level[0].hashblocksize = 1 << getle32(ctx->header.level1.blocksize);
ctx->bodyoffset = align64(IVFC_HEADER_SIZE + getle32(ctx->header.masterhashsize), ctx->level[2].hashblocksize);
ctx->bodysize = getle64(ctx->header.level3.hashdatasize);
ctx->level[2].dataoffset = ctx->bodyoffset;
ctx->level[2].datasize = align64(ctx->bodysize, ctx->level[2].hashblocksize);
ctx->level[0].dataoffset = ctx->level[2].dataoffset + ctx->level[2].datasize;
ctx->level[0].datasize = align64(getle64(ctx->header.level1.hashdatasize), ctx->level[0].hashblocksize);
ctx->level[1].dataoffset = ctx->level[0].dataoffset + ctx->level[0].datasize;
ctx->level[1].datasize = align64(getle64(ctx->header.level2.hashdatasize), ctx->level[1].hashblocksize);
ctx->level[0].hashoffset = IVFC_HEADER_SIZE;
ctx->level[1].hashoffset = ctx->level[0].dataoffset;
ctx->level[2].hashoffset = ctx->level[1].dataoffset;
}
if (actions & VerifyFlag)
ivfc_verify(ctx, actions);
if (actions & InfoFlag)
ivfc_print(ctx);
}
void ivfc_verify(ivfc_context* ctx, u32 flags)
{
u32 i, j;
u32 blockcount;
for(i=0; i<ctx->levelcount; i++)
{
ivfc_level* level = ctx->level + i;
level->hashcheck = Fail;
}
// Import IVFC level hashes
uint8_t *levelhash[IVFC_MAX_LEVEL] = { NULL };
for (i=0; i<ctx->levelcount; i++)
{
blockcount = (u32)(ctx->level[i].datasize / ctx->level[i].hashblocksize);
u32 read_size = align(blockcount * 0x20, ctx->level[i].hashblocksize);
levelhash[i] = malloc(read_size);
ivfc_read(ctx, ctx->level[i].hashoffset, read_size, levelhash[i]);
}
// Verify blocks
for (i=0; i<ctx->levelcount; i++)
{
blockcount = (u32) (ctx->level[i].datasize / ctx->level[i].hashblocksize);
if (ctx->level[i].datasize % ctx->level[i].hashblocksize != 0)
{
fprintf(stderr, "Error, IVFC block size mismatch\n");
return;
}
ctx->level[i].hashcheck = Good;
for (j=0; j<blockcount; j++)
{
u8 calchash[32];
// a hash level
if (i < 2) {
ctr_sha_256(levelhash[i+1] + ctx->level[i].hashblocksize * j, ctx->level[i].hashblocksize, calchash);
}
// a data level
else {
ivfc_read(ctx, ctx->level[i].dataoffset + j * ctx->level[i].hashblocksize, ctx->level[i].hashblocksize, ctx->buffer);
ctr_sha_256(ctx->buffer, (u32)ctx->level[i].hashblocksize, calchash);
}
if (memcmp(calchash, levelhash[i] + 0x20 * j, 0x20) != 0) {
ctx->level[i].hashcheck = Fail;
}
}
}
// Free level hashes
for (int i = 0; i < 3; i++) {
free(levelhash[i]);
}
}
void ivfc_read(ivfc_context* ctx, u64 offset, u64 size, u8* buffer)
{
if ( (offset > ctx->size) || (offset+size > ctx->size) )
{
fprintf(stderr, "Error, IVFC offset out of range (offset=0x%08"PRIx64", size=0x%08"PRIx64")\n", offset, size);
return;
}
ivfc_fseek(ctx, ctx->offset + offset);
if (size != ivfc_fread(ctx, buffer, 1, (size_t) size))
{
fprintf(stderr, "Error, IVFC could not read file\n");
return;
}
}
void ivfc_hash(ivfc_context* ctx, u64 offset, u64 size, u8* hash)
{
if (size > IVFC_MAX_BUFFERSIZE)
{
fprintf(stderr, "Error, IVFC hash block size too big.\n");
return;
}
ivfc_read(ctx, offset, size, ctx->buffer);
ctr_sha_256(ctx->buffer, (u32) size, hash);
}
void ivfc_print(ivfc_context* ctx)
{
u32 i;
ivfc_header* header = &ctx->header;
fprintf(stdout, "\nIVFC:\n");
fprintf(stdout, "Header: %.4s\n", header->magic);
fprintf(stdout, "Id: %08x\n", getle32(header->id));
for(i=0; i<ctx->levelcount; i++)
{
ivfc_level* level = ctx->level + i;
fprintf(stdout, "\n");
if (level->hashcheck == Unchecked)
fprintf(stdout, "Level %d: \n", i);
else
fprintf(stdout, "Level %d (%s): \n", i, level->hashcheck == Good? "GOOD" : "FAIL");
fprintf(stdout, " Data offset: 0x%08"PRIx64"\n", ctx->offset + level->dataoffset);
fprintf(stdout, " Data size: 0x%08"PRIx64"\n", level->datasize);
fprintf(stdout, " Hash offset: 0x%08"PRIx64"\n", ctx->offset + level->hashoffset);
fprintf(stdout, " Hash block size: 0x%08x\n", level->hashblocksize);
}
}
u64 ivfc_get_body_offset(ivfc_context* ctx)
{
return ctx->bodyoffset;
}
u64 ivfc_get_body_size(ivfc_context* ctx)
{
return ctx->bodysize;
}