hekate/bootloader/hos/pkg1.c
2020-07-04 21:58:21 +03:00

405 lines
13 KiB
C

/*
* Copyright (c) 2018 naehrwert
* Copyright (c) 2018 st4rk
* Copyright (c) 2018-2020 CTCaer
* Copyright (c) 2018 balika011
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope 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, see <http://www.gnu.org/licenses/>.
*/
#include <string.h>
#include <stdlib.h>
#include "hos.h"
#include "pkg1.h"
#include "../config.h"
#include <gfx_utils.h>
#include <libs/compr/lz4.h>
#include <mem/heap.h>
#include <soc/fuse.h>
#include <sec/se.h>
#include <soc/pmc.h>
#include <soc/t210.h>
#include <storage/nx_sd.h>
#include <utils/aarch64_util.h>
extern hekate_config h_cfg;
// Secmon package2 signature/hash checks patches for Erista.
#define SM_100_ADR 0x4002B020 // Original: 0x40014020.
PATCHSET_DEF(_secmon_1_patchset,
// Patch the relocator to be able to run from SM_100_ADR.
{ 0x1E0, _ADRP(0, 0x7C013000 - _PAGEOFF(SM_100_ADR)) },
// Patch package2 signature/hash checks.
{ 0x9F0 + 0xADC, _NOP() }
);
PATCHSET_DEF(_secmon_2_patchset,
// Patch package2 signature/hash checks.
{ 0xAC8 + 0xAAC, _NOP() }
);
PATCHSET_DEF(_secmon_3_patchset,
// Patch package2 signature/hash checks.
{ 0xAC8 + 0xA30, _NOP() }
);
PATCHSET_DEF(_secmon_4_patchset,
// Patch package2 signature/hash checks.
{ 0x2300 + 0x5EFC, _NOP() }
);
PATCHSET_DEF(_secmon_5_patchset,
// Patch package2 signature/hash checks.
{ 0xDA8 + 0xC9C, _NOP() }
);
PATCHSET_DEF(_secmon_6_patchset,
// Patch package2 signature/hash checks.
{ 0xDC8 + 0xE90, _NOP() }
// Fix sleep mode for debug.
// { 0x1A68 + 0x3854, 0x94000E45 }, //gpio_config_for_uart.
// { 0x1A68 + 0x3858, 0x97FFFC0F }, //clkrst_reboot_uarta.
// { 0x1A68 + 0x385C, 0x52A00021 }, //MOV W1, #0x10000 ; baudrate.
// { 0x1A68 + 0x3860, 0x2A1F03E0 }, //MOV W0, WZR ; uart_port -> A.
// { 0x1A68 + 0x3864, 0x72984001 }, //MOVK W1, #0xC200 ; baudrate.
// { 0x1A68 + 0x3868, 0x94000C8C }, //uart_configure.
// { 0x1A68 + 0x3A6C, _NOP() } // warmboot UARTA cfg.
);
PATCHSET_DEF(_secmon_620_patchset,
// Patch package2 signature/hash checks.
{ 0xDC8 + 0xC74, _NOP() }
// Fix sleep mode for debug.
// { 0x2AC8 + 0x3854, 0x94000F42 }, //gpio_config_for_uart.
// { 0x2AC8 + 0x3858, 0x97FFFC0F }, //clkrst_reboot_uarta.
// { 0x2AC8 + 0x385C, 0x52A00021 }, //MOV W1, #0x10000 ; baudrate.
// { 0x2AC8 + 0x3860, 0x2A1F03E0 }, //MOV W0, WZR ; uart_port -> A.
// { 0x2AC8 + 0x3864, 0x72984001 }, //MOVK W1, #0xC200 ; baudrate.
// { 0x2AC8 + 0x3868, 0x94000D89 }, //uart_configure.
// { 0x2AC8 + 0x3A6C, _NOP() } // warmboot UARTA cfg.
);
// Secmon patches for Mariko.
#define TZRAM_PROG_ADDR (TZRAM_BASE + 0x800)
#define TZRAM_COMPR_PROG_OFF 0xE04
#define TZRAM_PROG_PK2_SIG_PATCH (TZRAM_PROG_ADDR + 0xC10)
#define TZRAM_PROG_PK2_SIG_PATCH_1000 (TZRAM_PROG_ADDR + 0xD70)
PATCHSET_DEF(_secmon_6_mariko_patchset,
// Patch package2 decryption and signature/hash checks.
{ 0xDC8 + 0xE94, _NOP() }
);
PATCHSET_DEF(_secmon_620_mariko_patchset,
// Patch package2 decryption and signature/hash checks.
{ 0xDC8 + 0xC78, _NOP() }
);
// From 7.0.0 and above secmon is compressed.
PATCHSET_DEF(_secmon_7_mariko_patchset,
// Patch out decompression of program payload.
{ 0x82C, _NOP() }
);
const u16 _secmon_mariko_prog_comp_size[] = {
0x6B03, // 7.0.0. Patch offset: 0xC10.
0x6B16, // 7.0.1. Patch offset: 0xC10.
0x6B23, // 8.0.0. Patch offset: 0xC10.
0x6B84, // 8.1.0. Patch offset: 0xC10.
0x6C90, // 9.0.0. Patch offset: 0xC10.
0x6CE5, // 9.1.0. Patch offset: 0xC10.
0x6EE9, // 10.0.0. Patch offset: 0xD70.
};
// Erista fuse check warmboot patches.
#define _NOPv7() 0xE320F000
PATCHSET_DEF(_warmboot_1_patchset,
{ 0x4DC, _NOPv7() } // Fuse check.
);
PATCHSET_DEF(_warmboot_2_patchset,
{ 0x4DC, _NOPv7() } // Fuse check.
);
PATCHSET_DEF(_warmboot_3_patchset,
{ 0x4DC, _NOPv7() }, // Fuse check.
{ 0x4F0, _NOPv7() } // Segment id check.
);
PATCHSET_DEF(_warmboot_4_patchset,
{ 0x544, _NOPv7() }, // Fuse check.
{ 0x558, _NOPv7() } // Segment id check.
);
/*
* package1.1 header: <wb, ldr, sm>
* package1.1 layout:
* 1.0: {sm, ldr, wb} { 2, 1, 0 }
* 2.0+: {wb, ldr, sm} { 0, 1, 2 }
* 4.0+: {ldr, sm, wb} { 1, 2, 0 }
*/
static const u8 sec_map_100[3] = { PK11_SECTION_SM, PK11_SECTION_LD, PK11_SECTION_WB };
static const u8 sec_map_2xx[3] = { PK11_SECTION_WB, PK11_SECTION_LD, PK11_SECTION_SM };
static const u8 sec_map_4xx[3] = { PK11_SECTION_LD, PK11_SECTION_SM, PK11_SECTION_WB };
static const pkg1_id_t _pkg1_ids[] = {
{ "20161121183008", 0, 0x1900, 0x3FE0, SM_100_ADR, 0x8000D000, _secmon_1_patchset, _warmboot_1_patchset }, // 1.0.0 (Patched relocator).
{ "20170210155124", 0, 0x1900, 0x3FE0, 0x4002D000, 0x8000D000, _secmon_2_patchset, _warmboot_2_patchset }, // 2.0.0 - 2.3.0.
{ "20170519101410", 1, 0x1A00, 0x3FE0, 0x4002D000, 0x8000D000, _secmon_3_patchset, _warmboot_3_patchset }, // 3.0.0.
{ "20170710161758", 2, 0x1A00, 0x3FE0, 0x4002D000, 0x8000D000, _secmon_3_patchset, _warmboot_3_patchset }, // 3.0.1 - 3.0.2.
{ "20170921172629", 3, 0x1800, 0x3FE0, 0x4002B000, 0x4003B000, _secmon_4_patchset, _warmboot_4_patchset }, // 4.0.0 - 4.1.0.
{ "20180220163747", 4, 0x1900, 0x3FE0, 0x4002B000, 0x4003B000, _secmon_5_patchset, _warmboot_4_patchset }, // 5.0.0 - 5.1.0.
{ "20180802162753", 5, 0x1900, 0x3FE0, 0x4002B000, 0x4003D800, _secmon_6_patchset, _warmboot_4_patchset }, // 6.0.0 - 6.1.0.
{ "20181107105733", 6, 0x0E00, 0x6FE0, 0x4002B000, 0x4003D800, _secmon_620_patchset, _warmboot_4_patchset }, // 6.2.0.
{ "20181218175730", 7, 0x0F00, 0x6FE0, 0x40030000, 0x4003E000, NULL, NULL }, // 7.0.0.
{ "20190208150037", 7, 0x0F00, 0x6FE0, 0x40030000, 0x4003E000, NULL, NULL }, // 7.0.1.
{ "20190314172056", 7, 0x0E00, 0x6FE0, 0x40030000, 0x4003E000, NULL, NULL }, // 8.0.0 - 8.0.1.
{ "20190531152432", 8, 0x0E00, 0x6FE0, 0x40030000, 0x4003E000, NULL, NULL }, // 8.1.0.
{ "20190809135709", 9, 0x0E00, 0x6FE0, 0x40030000, 0x4003E000, NULL, NULL }, // 9.0.0 - 9.0.1.
{ "20191021113848", 10, 0x0E00, 0x6FE0, 0x40030000, 0x4003E000, NULL, NULL }, // 9.1.0.
{ "20200303104606", 10, 0x0E00, 0x6FE0, 0x40030000, 0x4003E000, NULL, NULL }, // 10.0.0.
{ NULL } // End.
};
const pkg1_id_t *pkg1_get_latest()
{
return &_pkg1_ids[ARRAY_SIZE(_pkg1_ids) - 2];
}
const pkg1_id_t *pkg1_identify(u8 *pkg1)
{
char build_date[15];
memcpy(build_date, (char *)(pkg1 + 0x10), 14);
build_date[14] = 0;
gfx_printf("Found pkg1 ('%s').\n\n", build_date);
for (u32 i = 0; _pkg1_ids[i].id; i++)
if (!memcmp(pkg1 + 0x10, _pkg1_ids[i].id, 8))
return &_pkg1_ids[i];
return NULL;
}
int pkg1_decrypt(const pkg1_id_t *id, u8 *pkg1)
{
// Decrypt package1.
pk11_hdr_t *hdr;
u8 *pkg11 = pkg1 + id->pkg11_off;
u32 pkg11_size = *(u32 *)pkg11;
if (!h_cfg.t210b01)
{
hdr = (pk11_hdr_t *)(pkg11 + 0x20);
se_aes_crypt_ctr(11, hdr, pkg11_size, hdr, pkg11_size, pkg11 + 0x10);
}
else
{
bl_hdr_t210b01_t *oem_hdr = (bl_hdr_t210b01_t *)pkg1;
pkg1 += sizeof(bl_hdr_t210b01_t);
hdr = (pk11_hdr_t *)(pkg1 + id->pkg11_off + 0x20);
// Use BEK for T210B01.
se_aes_iv_clear(13);
se_aes_crypt_cbc(13, 0, pkg1 + 0x20, oem_hdr->size - 0x20, pkg1 + 0x20, oem_hdr->size - 0x20);
}
// Return if header is valid.
return (hdr->magic == PKG1_MAGIC);
}
const u8 *pkg1_unpack(void *wm_dst, u32 *wb_sz, void *sm_dst, void *ldr_dst, const pkg1_id_t *id, u8 *pkg1)
{
const u8 *sec_map;
const pk11_hdr_t *hdr = (pk11_hdr_t *)(pkg1 + id->pkg11_off + 0x20);
u32 sec_size[3] = { hdr->wb_size, hdr->ldr_size, hdr->sm_size };
//u32 sec_off[3] = { hdr->wb_off, hdr->ldr_off, hdr->sm_off };
// Get correct header mapping.
if (id->kb == KB_FIRMWARE_VERSION_100_200 && !strcmp(id->id, "20161121183008"))
sec_map = sec_map_100;
else if (id->kb >= KB_FIRMWARE_VERSION_100_200 && id->kb <= KB_FIRMWARE_VERSION_301)
sec_map = sec_map_2xx;
else
sec_map = sec_map_4xx;
// Copy secmon, warmboot and nx bootloader payloads.
u8 *pdata = (u8 *)hdr + sizeof(pk11_hdr_t);
for (u32 i = 0; i < 3; i++)
{
if (sec_map[i] == PK11_SECTION_WB && wm_dst)
{
memcpy(wm_dst, pdata, sec_size[sec_map[i]]);
if (wb_sz)
*wb_sz = sec_size[sec_map[i]];
}
else if (sec_map[i] == PK11_SECTION_LD && ldr_dst)
memcpy(ldr_dst, pdata, sec_size[sec_map[i]]);
else if (sec_map[i] == PK11_SECTION_SM && sm_dst)
memcpy(sm_dst, pdata, sec_size[sec_map[i]]);
pdata += sec_size[sec_map[i]];
}
return sec_map;
}
void pkg1_secmon_patch(void *hos_ctxt, u32 secmon_base, bool t210b01)
{
patch_t *secmon_patchset;
launch_ctxt_t *ctxt = (launch_ctxt_t *)hos_ctxt;
// Patch Secmon to allow for an unsigned package2 and patched kernel.
if (!t210b01 && ctxt->pkg1_id->secmon_patchset)
{
// For T210 till 6.2.0 the patching is used as is, because of no compression.
secmon_patchset = ctxt->pkg1_id->secmon_patchset;
}
else if (t210b01)
{
// For T210B01 we patch 6.X.X as is. Otherwise we decompress the program payload.
if (ctxt->pkg1_id->kb == KB_FIRMWARE_VERSION_600)
secmon_patchset = _secmon_6_mariko_patchset;
else if (ctxt->pkg1_id->kb == KB_FIRMWARE_VERSION_620)
secmon_patchset = _secmon_620_mariko_patchset;
else
{
// Patch uncompress of program payload clear TZRAM.
secmon_patchset = _secmon_7_mariko_patchset;
memset((void *)TZRAM_PROG_ADDR, 0, 0x38800);
// Get size of compressed program payload and set patch offset.
u32 idx = ctxt->pkg1_id->kb - KB_FIRMWARE_VERSION_700;
u32 patch_offset = TZRAM_PROG_PK2_SIG_PATCH;
if (ctxt->pkg1_id->kb > KB_FIRMWARE_VERSION_910 || !memcmp(ctxt->pkg1_id->id, "20200303104606", 8))
{
idx++;
patch_offset = TZRAM_PROG_PK2_SIG_PATCH_1000;
}
// Uncompress directly to TZRAM.
LZ4_decompress_fast((const char*)(secmon_base + TZRAM_COMPR_PROG_OFF),
(char *)TZRAM_PROG_ADDR, _secmon_mariko_prog_comp_size[idx]);
// Patch package2 signature/hash checks.
*(vu32 *)patch_offset = _NOP();
}
}
else
return;
// Patch Secmon.
gfx_printf("%kPatching Secure Monitor%k\n", 0xFFFFBA00, 0xFFCCCCCC);
for (u32 i = 0; secmon_patchset[i].off != 0xFFFFFFFF; i++)
*(vu32 *)(secmon_base + secmon_patchset[i].off) = secmon_patchset[i].val;
}
void pkg1_warmboot_patch(void *hos_ctxt)
{
launch_ctxt_t *ctxt = (launch_ctxt_t *)hos_ctxt;
// Patch warmboot on T210 to allow downgrading.
patch_t *warmboot_patchset = ctxt->pkg1_id->warmboot_patchset;
gfx_printf("%kPatching Warmboot%k\n", 0xFFFFBA00, 0xFFCCCCCC);
for (u32 i = 0; warmboot_patchset[i].off != 0xFFFFFFFF; i++)
*(vu32 *)(ctxt->pkg1_id->warmboot_base + warmboot_patchset[i].off) = warmboot_patchset[i].val;
}
static void _warmboot_filename(char *out, u32 fuses)
{
if (fuses < 16)
{
out[19] = '0';
itoa(fuses, &out[19 + 1], 10);
}
else
itoa(fuses, &out[19], 10);
strcat(out, ".bin");
}
void pkg1_warmboot_config(void *hos_ctxt, u32 kb, u32 warmboot_base)
{
launch_ctxt_t *ctxt = (launch_ctxt_t *)hos_ctxt;
// Set warmboot address in PMC if required.
if (kb <= KB_FIRMWARE_VERSION_301)
PMC(APBDEV_PMC_SCRATCH1) = warmboot_base;
if (h_cfg.t210b01)
{
u32 pa_id;
u32 fuses_fw = kb + 2;
u32 fuses_max = KB_FIRMWARE_VERSION_MAX + 3;
u8 burnt_fuses = fuse_count_burnt(fuse_read_odm(7));
// Add one more fuse for high versions.
if (kb > KB_FIRMWARE_VERSION_910 || !memcmp(ctxt->pkg1_id->id, "20200303104606", 8))
fuses_fw++;
// Save current warmboot in storage cache and check if another one is needed.
if (!ctxt->warmboot)
{
char path[128];
f_mkdir("warmboot_mariko");
strcpy(path, "warmboot_mariko/wb_");
_warmboot_filename(path, fuses_fw);
if (f_stat(path, NULL))
sd_save_to_file((void *)warmboot_base, ctxt->warmboot_size, path);
// Load warmboot fw from storage if not matched.
if (burnt_fuses > fuses_fw)
{
u32 tmp_fuses = burnt_fuses;
while (true)
{
_warmboot_filename(path, burnt_fuses);
if (!f_stat(path, NULL))
{
ctxt->warmboot = sd_file_read(path, &ctxt->warmboot_size);
burnt_fuses = tmp_fuses;
break;
}
if (tmp_fuses >= fuses_max)
break;
tmp_fuses++;
}
}
}
// Configure Warmboot parameters.
switch (burnt_fuses)
{
case KB_FIRMWARE_VERSION_600 + 2: // 7 fuses burnt.
pa_id = 0x87;
break;
case KB_FIRMWARE_VERSION_620 + 2: // 8 fuses burnt. 0x21 raise.
pa_id = 0xA8;
break;
default: // From 7.0.0 and up PA id raises by 0x21 with a static base.
pa_id = 0x129;
pa_id += 0x21 * (burnt_fuses - KB_FIRMWARE_VERSION_700 - 2);
break;
}
// Set Warmboot Physical Address ID and lock SECURE_SCRATCH32 register.
PMC(APBDEV_PMC_SECURE_SCRATCH32) = pa_id;
PMC(APBDEV_PMC_SEC_DISABLE3) |= BIT(16);
}
else
{
// Set Warmboot Physical Address ID for 3.0.0 - 3.0.2.
if (kb == KB_FIRMWARE_VERSION_300)
PMC(APBDEV_PMC_SECURE_SCRATCH32) = 0xE3; // Warmboot 3.0.0 PA address id.
else if (kb == KB_FIRMWARE_VERSION_301)
PMC(APBDEV_PMC_SECURE_SCRATCH32) = 0x104; // Warmboot 3.0.1/.2 PA address id.
}
}