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hekate/bootloader/hos/pkg2.c

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/*
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* Copyright (c) 2018 naehrwert
* Copyright (c) 2018 CTCaer
* Copyright (c) 2018 Atmosphère-NX
*
* 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/>.
*/
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#include <string.h>
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#include "pkg2.h"
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#include "../utils/aarch64_util.h"
#include "../mem/heap.h"
#include "../sec/se.h"
#include "../libs/compr/blz.h"
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#include "../gfx/gfx.h"
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extern gfx_con_t gfx_con;
/*#include "util.h"
#define DPRINTF(...) gfx_printf(&gfx_con, __VA_ARGS__)
#define DEBUG_PRINTING*/
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#define DPRINTF(...)
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//TODO: Replace hardcoded AArch64 instructions with instruction macros.
//TODO: Reduce hardcoded values without searching kernel for patterns?
// The process ID send/receive kernel patches were taken from Atmosphère's kernel patches.
// They should only be used when running Atmosphère.
#define FREE_CODE_OFF_1ST_100 0x4797C
#define FREE_CODE_OFF_1ST_200 0x6486C
#define FREE_CODE_OFF_1ST_300 0x494A4
#define FREE_CODE_OFF_1ST_302 0x494BC
#define FREE_CODE_OFF_1ST_400 0x52890
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#define FREE_CODE_OFF_1ST_500 0x5C020
#define ID_SND_OFF_100 0x23CC0
#define ID_SND_OFF_200 0x3F134
#define ID_SND_OFF_300 0x26080
#define ID_SND_OFF_302 0x26080
#define ID_SND_OFF_400 0x2AF64
#define ID_SND_OFF_500 0x2AD34
#define ID_RCV_OFF_100 0x219F0
#define ID_RCV_OFF_200 0x3D1A8
#define ID_RCV_OFF_300 0x240F0
#define ID_RCV_OFF_302 0x240F0
#define ID_RCV_OFF_400 0x28F6C
#define ID_RCV_OFF_500 0x28DAC
static u32 PRC_ID_SND_100[] =
{
0xA9BF2FEA, 0x2A0E03EB, 0xD37EF56B, 0xF86B6B8B, 0x92FFFFE9, 0x8A090168, 0xD2FFFFE9, 0x8A09016B,
0xD2FFFFC9, 0xEB09017F, 0x54000040, 0xF9412948, 0xA8C12FEA
};
#define FREE_CODE_OFF_2ND_100 (FREE_CODE_OFF_1ST_100 + sizeof(PRC_ID_SND_100) + 4)
static u32 PRC_ID_RCV_100[] =
{
0xA9BF2FEA, 0x2A1C03EA, 0xD37EF54A, 0xF86A69AA, 0x92FFFFE9, 0x8A090148, 0xD2FFFFE9, 0x8A09014A,
0xD2FFFFC9, 0xEB09015F, 0x54000040, 0xF9412968, 0xA8C12FEA
};
static u32 PRC_ID_SND_200[] =
{
0xA9BF2FEA, 0x2A1803EB, 0xD37EF56B, 0xF86B6B8B, 0x92FFFFE9, 0x8A090168, 0xD2FFFFE9, 0x8A09016B,
0xD2FFFFC9, 0xEB09017F, 0x54000040, 0xF9413148, 0xA8C12FEA
};
#define FREE_CODE_OFF_2ND_200 (FREE_CODE_OFF_1ST_200 + sizeof(PRC_ID_SND_200) + 4)
static u32 PRC_ID_RCV_200[] =
{
0xA9BF2FEA, 0x2A0F03EA, 0xD37EF54A, 0xF9405FEB, 0xF86A696A, 0xF9407BEB, 0x92FFFFE9, 0x8A090148,
0xD2FFFFE9, 0x8A09014A, 0xD2FFFFC9, 0xEB09015F, 0x54000040, 0xF9413168, 0xA8C12FEA
};
static u32 PRC_ID_SND_300[] =
{
0xA9BF2FEA, 0x2A1803EB, 0xD37EF56B, 0xF86B6B8B, 0x92FFFFE9, 0x8A090168, 0xD2FFFFE9, 0x8A09016B,
0xD2FFFFC9, 0xEB09017F, 0x54000040, 0xF9415548, 0xA8C12FEA
};
#define FREE_CODE_OFF_2ND_300 (FREE_CODE_OFF_1ST_300 + sizeof(PRC_ID_SND_300) + 4)
static u32 PRC_ID_RCV_300[] =
{
0xA9BF2FEA, 0x2A0F03EA, 0xD37EF54A, 0xF9405FEB, 0xF86A696A, 0xF9407BEB, 0x92FFFFE9, 0x8A090148,
0xD2FFFFE9, 0x8A09014A, 0xD2FFFFC9, 0xEB09015F, 0x54000040, 0xF9415568, 0xA8C12FEA
};
static u32 PRC_ID_SND_302[] =
{
0xA9BF2FEA, 0x2A1803EB, 0xD37EF56B, 0xF86B6B8B, 0x92FFFFE9, 0x8A090168, 0xD2FFFFE9, 0x8A09016B,
0xD2FFFFC9, 0xEB09017F, 0x54000040, 0xF9415548, 0xA8C12FEA
};
#define FREE_CODE_OFF_2ND_302 (FREE_CODE_OFF_1ST_302 + sizeof(PRC_ID_SND_302) + 4)
static u32 PRC_ID_RCV_302[] =
{
0xA9BF2FEA, 0x2A0F03EA, 0xD37EF54A, 0xF9405FEB, 0xF86A696A, 0xF9407BEB, 0x92FFFFE9, 0x8A090148,
0xD2FFFFE9, 0x8A09014A, 0xD2FFFFC9, 0xEB09015F, 0x54000040, 0xF9415568, 0xA8C12FEA
};
static u32 PRC_ID_SND_400[] =
{
0x2A1703EA, 0xD37EF54A, 0xF86A6B8A, 0x92FFFFE9, 0x8A090148, 0xD2FFFFE9, 0x8A09014A, 0xD2FFFFC9,
0xEB09015F, 0x54000060, 0xF94053EA, 0xF9415948, 0xF94053EA
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};
#define FREE_CODE_OFF_2ND_400 (FREE_CODE_OFF_1ST_400 + sizeof(PRC_ID_SND_400) + 4)
static u32 PRC_ID_RCV_400[] =
{
0xF9403BED, 0x2A0E03EA, 0xD37EF54A, 0xF86A69AA, 0x92FFFFE9, 0x8A090148, 0xD2FFFFE9, 0x8A09014A,
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0xD2FFFFC9, 0xEB09015F, 0x54000040, 0xF9415B28, 0xD503201F
};
static u32 PRC_ID_SND_500[] =
{
0x2A1703EA, 0xD37EF54A, 0xF86A6B6A, 0x92FFFFE9, 0x8A090148, 0xD2FFFFE9, 0x8A09014A, 0xD2FFFFC9,
0xEB09015F, 0x54000060, 0xF94043EA, 0xF9415948, 0xF94043EA
};
#define FREE_CODE_OFF_2ND_500 (FREE_CODE_OFF_1ST_500 + sizeof(PRC_ID_SND_500) + 4)
static u32 PRC_ID_RCV_500[] =
{
0xF9403BED, 0x2A1503EA, 0xD37EF54A, 0xF86A69AA, 0x92FFFFE9, 0x8A090148, 0xD2FFFFE9, 0x8A09014A,
0xD2FFFFC9, 0xEB09015F, 0x54000040, 0xF9415B08, 0xF9406FEA
};
// Include kernel patches here, so we can utilize pkg1 id
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KERNEL_PATCHSET_DEF(_kernel_1_patchset,
{ SVC_VERIFY_DS, 0x3764C, _NOP(), NULL }, // Disable SVC verifications
{ DEBUG_MODE_EN, 0x44074, _MOVZX(8, 1, 0), NULL }, // Enable Debug Patch
// Atmosphère kernel patches.
{ ATM_GEN_PATCH, ID_SND_OFF_100, _B(ID_SND_OFF_100, FREE_CODE_OFF_1ST_100), NULL}, // Send process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_1ST_100, sizeof(PRC_ID_SND_100) >> 2, PRC_ID_SND_100}, // Send process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_1ST_100 + sizeof(PRC_ID_SND_100), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_1ST_100 + sizeof(PRC_ID_SND_100), ID_SND_OFF_100 + 4), NULL},
{ ATM_GEN_PATCH, ID_RCV_OFF_100, _B(ID_RCV_OFF_100, FREE_CODE_OFF_2ND_100), NULL}, // Receive process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_2ND_100, sizeof(PRC_ID_RCV_100) >> 2, PRC_ID_RCV_100}, // Receive process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_2ND_100 + sizeof(PRC_ID_RCV_100), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_2ND_100 + sizeof(PRC_ID_RCV_100), ID_RCV_OFF_100 + 4), NULL}
);
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KERNEL_PATCHSET_DEF(_kernel_2_patchset,
{ SVC_VERIFY_DS, 0x54834, _NOP(), NULL }, // Disable SVC verifications
{ DEBUG_MODE_EN, 0x6086C, _MOVZX(8, 1, 0), NULL }, // Enable Debug Patch
// Atmosphère kernel patches.
{ ATM_GEN_PATCH, ID_SND_OFF_200, _B(ID_SND_OFF_200, FREE_CODE_OFF_1ST_200), NULL}, // Send process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_1ST_200, sizeof(PRC_ID_SND_200) >> 2, PRC_ID_SND_200}, // Send process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_1ST_200 + sizeof(PRC_ID_SND_200), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_1ST_200 + sizeof(PRC_ID_SND_200), ID_SND_OFF_200 + 4), NULL},
{ ATM_GEN_PATCH, ID_RCV_OFF_200, _B(ID_RCV_OFF_200, FREE_CODE_OFF_2ND_200), NULL}, // Receive process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_2ND_200, sizeof(PRC_ID_RCV_200) >> 2, PRC_ID_RCV_200}, // Receive process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_2ND_200 + sizeof(PRC_ID_RCV_200), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_2ND_200 + sizeof(PRC_ID_RCV_200), ID_RCV_OFF_200 + 4), NULL}
);
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KERNEL_PATCHSET_DEF(_kernel_3_patchset,
{ SVC_VERIFY_DS, 0x3BD24, _NOP(), NULL }, // Disable SVC verifications
{ DEBUG_MODE_EN, 0x483FC, _MOVZX(8, 1, 0), NULL }, // Enable Debug Patch
// Atmosphère kernel patches.
{ ATM_GEN_PATCH, ID_SND_OFF_300, _B(ID_SND_OFF_300, FREE_CODE_OFF_1ST_300), NULL}, // Send process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_1ST_300, sizeof(PRC_ID_SND_300) >> 2, PRC_ID_SND_300}, // Send process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_1ST_300 + sizeof(PRC_ID_SND_300), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_1ST_300 + sizeof(PRC_ID_SND_300), ID_SND_OFF_300 + 4), NULL},
{ ATM_GEN_PATCH, ID_RCV_OFF_300, _B(ID_RCV_OFF_300, FREE_CODE_OFF_2ND_300), NULL}, // Receive process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_2ND_300, sizeof(PRC_ID_RCV_300) >> 2, PRC_ID_RCV_300}, // Receive process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_2ND_300 + sizeof(PRC_ID_RCV_300), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_2ND_300 + sizeof(PRC_ID_RCV_300), ID_RCV_OFF_300 + 4), NULL}
);
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KERNEL_PATCHSET_DEF(_kernel_302_patchset,
{ SVC_VERIFY_DS, 0x3BD24, _NOP(), NULL }, // Disable SVC verifications
{ DEBUG_MODE_EN, 0x48414, _MOVZX(8, 1, 0), NULL }, // Enable Debug Patch
// Atmosphère kernel patches.
{ ATM_GEN_PATCH, ID_SND_OFF_302, _B(ID_SND_OFF_302, FREE_CODE_OFF_1ST_302), NULL}, // Send process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_1ST_302, sizeof(PRC_ID_SND_302) >> 2, PRC_ID_SND_302}, // Send process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_1ST_302 + sizeof(PRC_ID_SND_302), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_1ST_302 + sizeof(PRC_ID_SND_302), ID_SND_OFF_302 + 4), NULL},
{ ATM_GEN_PATCH, ID_RCV_OFF_302, _B(ID_RCV_OFF_302, FREE_CODE_OFF_2ND_302), NULL}, // Receive process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_2ND_302, sizeof(PRC_ID_RCV_302) >> 2, PRC_ID_RCV_302}, // Receive process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_2ND_302 + sizeof(PRC_ID_RCV_302), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_2ND_302 + sizeof(PRC_ID_RCV_302), ID_RCV_OFF_302 + 4), NULL}
);
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KERNEL_PATCHSET_DEF(_kernel_4_patchset,
{ SVC_VERIFY_DS, 0x41EB4, _NOP(), NULL }, // Disable SVC verifications
{ DEBUG_MODE_EN, 0x4EBFC, _MOVZX(8, 1, 0), NULL }, // Enable Debug Patch
// Atmosphère kernel patches.
{ ATM_GEN_PATCH, ID_SND_OFF_400, _B(ID_SND_OFF_400, FREE_CODE_OFF_1ST_400), NULL}, // Send process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_1ST_400, sizeof(PRC_ID_SND_400) >> 2, PRC_ID_SND_400}, // Send process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_1ST_400 + sizeof(PRC_ID_SND_400), // Branch back and skip 2 instructions.
_B(FREE_CODE_OFF_1ST_400 + sizeof(PRC_ID_SND_400), ID_SND_OFF_400 + 8), NULL},
{ ATM_GEN_PATCH, ID_RCV_OFF_400, _B(ID_RCV_OFF_400, FREE_CODE_OFF_2ND_400), NULL}, // Receive process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_2ND_400, sizeof(PRC_ID_RCV_400) >> 2, PRC_ID_RCV_400}, // Receive process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_2ND_400 + sizeof(PRC_ID_RCV_400), // Branch back and skip 1 instruction.
_B(FREE_CODE_OFF_2ND_400 + sizeof(PRC_ID_RCV_400), ID_RCV_OFF_400 + 4), NULL}
);
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KERNEL_PATCHSET_DEF(_kernel_5_patchset,
{ SVC_VERIFY_DS, 0x45E6C, _NOP(), NULL }, // Disable SVC verifications
{ DEBUG_MODE_EN, 0x5513C, _MOVZX(8, 1, 0), NULL }, // Enable Debug Patch
// Atmosphère kernel patches.
{ ATM_GEN_PATCH, ID_SND_OFF_500, _B(ID_SND_OFF_500, FREE_CODE_OFF_1ST_500), NULL}, // Send process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_1ST_500, sizeof(PRC_ID_SND_500) >> 2, PRC_ID_SND_500}, // Send process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_1ST_500 + sizeof(PRC_ID_SND_500), // Branch back and skip 2 instructions.
_B(FREE_CODE_OFF_1ST_500 + sizeof(PRC_ID_SND_500), ID_SND_OFF_500 + 8), NULL},
{ ATM_GEN_PATCH, ID_RCV_OFF_500, _B(ID_RCV_OFF_500, FREE_CODE_OFF_2ND_500), NULL}, // Receive process id branch.
{ ATM_ARR_PATCH, FREE_CODE_OFF_2ND_500, sizeof(PRC_ID_RCV_500) >> 2, PRC_ID_RCV_500}, // Receive process id code.
{ ATM_GEN_PATCH, FREE_CODE_OFF_2ND_500 + sizeof(PRC_ID_RCV_500), // Branch back and skip 2 instructions.
_B(FREE_CODE_OFF_2ND_500 + sizeof(PRC_ID_RCV_500), ID_RCV_OFF_500 + 8), NULL}
);
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static const pkg2_kernel_id_t _pkg2_kernel_ids[] =
{
{ 0x427f2647, _kernel_1_patchset }, //1.0.0
{ 0xae19cf1b, _kernel_2_patchset }, //2.0.0 - 2.3.0
{ 0x73c9e274, _kernel_3_patchset }, //3.0.0 - 3.0.1
{ 0xe0e8cdc4, _kernel_302_patchset }, //3.0.2
{ 0x485d0157, _kernel_4_patchset }, //4.0.0 - 4.1.0
{ 0xf3c363f2, _kernel_5_patchset }, //5.0.0 - 5.1.0
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{ 0, 0 } //End.
};
enum kip_offset_section
{
KIP_TEXT = 0,
KIP_RODATA = 1,
KIP_DATA = 2,
KIP_BSS = 3,
KIP_UNKSEC1 = 4,
KIP_UNKSEC2 = 5
};
#define KIP_PATCH_SECTION_SHIFT (29)
#define KIP_PATCH_SECTION_MASK (7 << KIP_PATCH_SECTION_SHIFT)
#define KIP_PATCH_OFFSET_MASK (~KIP_PATCH_SECTION_MASK)
#define GET_KIP_PATCH_SECTION(x) ((x >> KIP_PATCH_SECTION_SHIFT) & 7)
#define GET_KIP_PATCH_OFFSET(x) (x & KIP_PATCH_OFFSET_MASK)
#define KPS(x) ((u32)(x) << KIP_PATCH_SECTION_SHIFT)
static kip1_patch_t _fs_nosigchk_100[] =
{
{ KPS(KIP_TEXT) | 0x194A0, 4, "\xBA\x09\x00\x94", "\xE0\x03\x1F\x2A" },
{ KPS(KIP_TEXT) | 0x3A79C, 4, "\xE0\x06\x00\x36", "\x1F\x20\x03\xD5" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_100[] =
{
{ "nosigchk", _fs_nosigchk_100 },
{ "nogc", NULL },
{ NULL, NULL }
};
static kip1_patch_t _fs_nosigchk_200[] =
{
{ KPS(KIP_TEXT) | 0x15DF4, 4, "\xBC\x0A\x00\x94", "\xE0\x03\x1F\x2A" },
{ KPS(KIP_TEXT) | 0x3F720, 4, "\x00\x06\x00\x36", "\x1F\x20\x03\xD5" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_200[] =
{
{ "nosigchk", _fs_nosigchk_200 },
{ "nogc", NULL },
{ NULL, NULL }
};
static kip1_patch_t _fs_nosigchk_210[] =
{
{ KPS(KIP_TEXT) | 0x15F64, 4, "\xDF\x0A\x00\x94", "\xE0\x03\x1F\x2A" },
{ KPS(KIP_TEXT) | 0x3FAF8, 4, "\x00\x06\x00\x36", "\x1F\x20\x03\xD5" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_210[] =
{
{ "nosigchk", _fs_nosigchk_210 },
{ "nogc", NULL },
{ NULL, NULL }
};
static kip1_patch_t _fs_nosigchk_300[] =
{
{ KPS(KIP_TEXT) | 0x18E24, 4, "\x52\x0C\x00\x94", "\xE0\x03\x1F\x2A" },
{ KPS(KIP_TEXT) | 0x49EC8, 4, "\x40\x04\x00\x36", "\x1F\x20\x03\xD5" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_300[] =
{
{ "nosigchk", _fs_nosigchk_300 },
{ "nogc", NULL },
{ NULL, NULL }
};
static kip1_patch_t _fs_nosigchk_30x[] =
{
{ KPS(KIP_TEXT) | 0x18E90, 4, "\x52\x0C\x00\x94", "\xE0\x03\x1F\x2A" },
{ KPS(KIP_TEXT) | 0x49F34, 4, "\xE0\x03\x00\x36", "\x1F\x20\x03\xD5" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_30x[] =
{
{ "nosigchk", _fs_nosigchk_30x },
{ "nogc", NULL },
{ NULL, NULL }
};
static kip1_patch_t _fs_nosigchk_4xx[] =
{
{ KPS(KIP_TEXT) | 0x1C4FC, 4, "\x3C\x2F\x00\x94", "\xE0\x03\x1F\x2A" },
{ KPS(KIP_TEXT) | 0x57934, 4, "\xE0\x02\x00\x36", "\x1F\x20\x03\xD5" },
{ 0, 0, NULL, NULL }
};
static kip1_patch_t _fs_nogc_40x[] =
{
{ KPS(KIP_TEXT) | 0xA3458, 4, "\x14\x40\x80\x72", "\x14\x80\x80\x72" },
{ KPS(KIP_TEXT) | 0xAAB44, 8, "\xF4\x4F\xBE\xA9\xFD\x7B\x01\xA9", "\xE0\x03\x1F\x2A\xC0\x03\x5F\xD6" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_40x[] =
{
{ "nosigchk", _fs_nosigchk_4xx },
{ "nogc", _fs_nogc_40x },
{ NULL, NULL }
};
static kip1_patch_t _fs_nogc_410[] =
{
{ KPS(KIP_TEXT) | 0xA34BC, 4, "\x14\x40\x80\x72", "\x14\x80\x80\x72" },
{ KPS(KIP_TEXT) | 0xAABA8, 8, "\xF4\x4F\xBE\xA9\xFD\x7B\x01\xA9", "\xE0\x03\x1F\x2A\xC0\x03\x5F\xD6" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_410[] =
{
{ "nosigchk", _fs_nosigchk_4xx },
{ "nogc", _fs_nogc_410 },
{ NULL, NULL }
};
static kip1_patch_t _fs_nosigchk_50x[] =
{
{ KPS(KIP_TEXT) | 0x22DDC, 4, "\x7D\x3E\x00\x94", "\xE0\x03\x1F\x2A" },
{ KPS(KIP_TEXT) | 0x7D490, 4, "\x40\x03\x00\x36", "\x1F\x20\x03\xD5" },
{ 0, 0, NULL, NULL }
};
static kip1_patch_t _fs_nogc_50x[] =
{
{ KPS(KIP_TEXT) | 0xCF3C4, 4, "\x14\x40\x80\x52", "\x14\x80\x80\x52" },
{ KPS(KIP_TEXT) | 0xD73A0, 8, "\xF4\x4F\xBE\xA9\xFD\x7B\x01\xA9", "\xE0\x03\x1F\x2A\xC0\x03\x5F\xD6" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_50x[] =
{
{ "nosigchk", _fs_nosigchk_50x },
{ "nogc", _fs_nogc_50x },
{ NULL, NULL }
};
static kip1_patch_t _fs_nosigchk_510[] =
{
{ KPS(KIP_TEXT) | 0x22E0C, 4, "\x85\x3E\x00\x94", "\xE0\x03\x1F\x2A" },
{ KPS(KIP_TEXT) | 0x7D860, 4, "\x40\x03\x00\x36", "\x1F\x20\x03\xD5" },
{ 0, 0, NULL, NULL }
};
static kip1_patch_t _fs_nogc_510[] =
{
{ KPS(KIP_TEXT) | 0xCF794, 4, "\x14\x40\x80\x52", "\x14\x80\x80\x52" },
{ KPS(KIP_TEXT) | 0xD7770, 8, "\xF4\x4F\xBE\xA9\xFD\x7B\x01\xA9", "\xE0\x03\x1F\x2A\xC0\x03\x5F\xD6" },
{ 0, 0, NULL, NULL }
};
static kip1_patchset_t _fs_patches_510[] =
{
{ "nosigchk", _fs_nosigchk_510 },
{ "nogc", _fs_nogc_510 },
{ NULL, NULL }
};
static kip1_id_t _kip_ids[] =
{
{ "FS", "\xde\x9f\xdd\xa4\x08\x5d\xd5\xfe\x68\xdc\xb2\x0b\x41\x09\x5b\xb4", _fs_patches_100 }, // FS 1.0.0
{ "FS", "\xfc\x3e\x80\x99\x1d\xca\x17\x96\x4a\x12\x1f\x04\xb6\x1b\x17\x5e", _fs_patches_100 }, // FS 1.0.0 "exfat"
{ "FS", "\xcd\x7b\xbe\x18\xd6\x13\x0b\x28\xf6\x2f\x19\xfa\x79\x45\x53\x5b", _fs_patches_200 }, // FS 2.0.0
{ "FS", "\xe7\x66\x92\xdf\xaa\x04\x20\xe9\xfd\xd6\x8e\x43\x63\x16\x18\x18", _fs_patches_200 }, // FS 2.0.0 exfat
{ "FS", "\x0d\x70\x05\x62\x7b\x07\x76\x7c\x0b\x96\x3f\x9a\xff\xdd\xe5\x66", _fs_patches_210 }, // FS 2.1.0
{ "FS", "\xdb\xd8\x5f\xca\xcc\x19\x3d\xa8\x30\x51\xc6\x64\xe6\x45\x2d\x32", _fs_patches_210 }, // FS 2.1.0 exfat
{ "FS", "\xa8\x6d\xa5\xe8\x7e\xf1\x09\x7b\x23\xda\xb5\xb4\xdb\xba\xef\xe7", _fs_patches_300 }, // FS 3.0.0
{ "FS", "\x98\x1c\x57\xe7\xf0\x2f\x70\xf7\xbc\xde\x75\x31\x81\xd9\x01\xa6", _fs_patches_300 }, // FS 3.0.0 exfat
{ "FS", "\x57\x39\x7c\x06\x3f\x10\xb6\x31\x3f\x4d\x83\x76\x53\xcc\xc3\x71", _fs_patches_30x }, // FS 3.0.1
{ "FS", "\x07\x30\x99\xd7\xc6\xad\x7d\x89\x83\xbc\x7a\xdd\x93\x2b\xe3\xd1", _fs_patches_30x }, // FS 3.0.1 exfat
{ "FS", "\x06\xe9\x07\x19\x59\x5a\x01\x0c\x62\x46\xff\x70\x94\x6f\x10\xfb", _fs_patches_40x }, // FS 4.0.1
{ "FS", "\x54\x9b\x0f\x8d\x6f\x72\xc4\xe9\xf3\xfd\x1f\x19\xea\xce\x4a\x5a", _fs_patches_40x }, // FS 4.0.1 exfat
{ "FS", "\x80\x96\xaf\x7c\x6a\x35\xaa\x82\x71\xf3\x91\x69\x95\x41\x3b\x0b", _fs_patches_410 }, // FS 4.1.0
{ "FS", "\x02\xd5\xab\xaa\xfd\x20\xc8\xb0\x63\x3a\xa0\xdb\xae\xe0\x37\x7e", _fs_patches_410 }, // FS 4.1.0 exfat
{ "FS", "\xa6\xf2\x7a\xd9\xac\x7c\x73\xad\x41\x9b\x63\xb2\x3e\x78\x5a\x0c", _fs_patches_50x }, // FS 5.0.0
{ "FS", "\xce\x3e\xcb\xa2\xf2\xf0\x62\xf5\x75\xf8\xf3\x60\x84\x2b\x32\xb4", _fs_patches_50x }, // FS 5.0.0 exfat
{ "FS", "\x76\xf8\x74\x02\xc9\x38\x7c\x0f\x0a\x2f\xab\x1b\x45\xce\xbb\x93", _fs_patches_510 }, // FS 5.1.0
{ "FS", "\x10\xb2\xd8\x16\x05\x48\x85\x99\xdf\x22\x42\xcb\x6b\xac\x2d\xf1", _fs_patches_510 }, // FS 5.1.0 exfat
};
const pkg2_kernel_id_t *pkg2_identify(u32 id)
{
for (u32 i = 0; _pkg2_kernel_ids[i].crc32c_id; i++)
if (id == _pkg2_kernel_ids[i].crc32c_id)
return &_pkg2_kernel_ids[i];
return NULL;
}
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static u32 _pkg2_calc_kip1_size(pkg2_kip1_t *kip1)
{
u32 size = sizeof(pkg2_kip1_t);
for (u32 j = 0; j < KIP1_NUM_SECTIONS; j++)
size += kip1->sections[j].size_comp;
return size;
}
void pkg2_parse_kips(link_t *info, pkg2_hdr_t *pkg2)
{
u8 *ptr = pkg2->data + pkg2->sec_size[PKG2_SEC_KERNEL];
pkg2_ini1_t *ini1 = (pkg2_ini1_t *)ptr;
ptr += sizeof(pkg2_ini1_t);
for (u32 i = 0; i < ini1->num_procs; i++)
{
pkg2_kip1_t *kip1 = (pkg2_kip1_t *)ptr;
pkg2_kip1_info_t *ki = (pkg2_kip1_info_t *)malloc(sizeof(pkg2_kip1_info_t));
ki->kip1 = kip1;
ki->size = _pkg2_calc_kip1_size(kip1);
list_append(info, &ki->link);
ptr += ki->size;
DPRINTF(" kip1 %d:%s @ %08X (%08X)\n", i, kip1->name, (u32)kip1, ki->size);
}
}
int pkg2_has_kip(link_t *info, u64 tid)
{
LIST_FOREACH_ENTRY(pkg2_kip1_info_t, ki, info, link)
if(ki->kip1->tid == tid)
return 1;
return 0;
}
void pkg2_replace_kip(link_t *info, u64 tid, pkg2_kip1_t *kip1)
{
LIST_FOREACH_ENTRY(pkg2_kip1_info_t, ki, info, link)
if (ki->kip1->tid == tid)
{
ki->kip1 = kip1;
ki->size = _pkg2_calc_kip1_size(kip1);
DPRINTF("replaced kip (new size %08X)\n", ki->size);
return;
}
}
void pkg2_add_kip(link_t *info, pkg2_kip1_t *kip1)
{
pkg2_kip1_info_t *ki = (pkg2_kip1_info_t *)malloc(sizeof(pkg2_kip1_info_t));
ki->kip1 = kip1;
ki->size = _pkg2_calc_kip1_size(kip1);
DPRINTF("added kip (size %08X)\n", ki->size);
list_append(info, &ki->link);
}
void pkg2_merge_kip(link_t *info, pkg2_kip1_t *kip1)
{
if (pkg2_has_kip(info, kip1->tid))
pkg2_replace_kip(info, kip1->tid, kip1);
else
pkg2_add_kip(info, kip1);
}
int pkg2_decompress_kip(pkg2_kip1_info_t* ki, u32 sectsToDecomp)
{
u32 compClearMask = ~sectsToDecomp;
if ((ki->kip1->flags & compClearMask) == ki->kip1->flags)
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return 0; // Already decompressed, nothing to do.
pkg2_kip1_t hdr;
memcpy(&hdr, ki->kip1, sizeof(hdr));
unsigned int newKipSize = sizeof(hdr);
for (u32 sectIdx=0; sectIdx<KIP1_NUM_SECTIONS; sectIdx++)
{
u32 sectCompBit = 1u << sectIdx;
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// For compressed, cant get actual decompressed size without doing it, so use safe "output size".
if (sectIdx < 3 && (sectsToDecomp & sectCompBit) && (hdr.flags & sectCompBit))
newKipSize += hdr.sections[sectIdx].size_decomp;
else
newKipSize += hdr.sections[sectIdx].size_comp;
}
pkg2_kip1_t* newKip = malloc(newKipSize);
unsigned char* dstDataPtr = newKip->data;
const unsigned char* srcDataPtr = ki->kip1->data;
for (u32 sectIdx=0; sectIdx<KIP1_NUM_SECTIONS; sectIdx++)
{
u32 sectCompBit = 1u << sectIdx;
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// Easy copy path for uncompressed or ones we dont want to uncompress.
if (sectIdx >= 3 || !(sectsToDecomp & sectCompBit) || !(hdr.flags & sectCompBit))
{
unsigned int dataSize = hdr.sections[sectIdx].size_comp;
if (dataSize == 0)
continue;
memcpy(dstDataPtr, srcDataPtr, dataSize);
srcDataPtr += dataSize;
dstDataPtr += dataSize;
continue;
}
unsigned int compSize = hdr.sections[sectIdx].size_comp;
unsigned int outputSize = hdr.sections[sectIdx].size_decomp;
gfx_printf(&gfx_con, "Decomping %s KIP1 sect %d of size %d...\n", (const char*)hdr.name, sectIdx, compSize);
if (blz_uncompress_srcdest(srcDataPtr, compSize, dstDataPtr, outputSize) == 0)
{
gfx_printf(&gfx_con, "%kERROR decomping sect %d of %s KIP!%k\n", 0xFFFF0000, sectIdx, (char*)hdr.name, 0xFFCCCCCC);
free(newKip);
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return 1;
}
else
{
DPRINTF("Done! Decompressed size is %d!\n", outputSize);
}
hdr.sections[sectIdx].size_comp = outputSize;
srcDataPtr += compSize;
dstDataPtr += outputSize;
}
hdr.flags &= compClearMask;
memcpy(newKip, &hdr, sizeof(hdr));
newKipSize = dstDataPtr-(unsigned char*)(newKip);
free(ki->kip1);
ki->kip1 = newKip;
ki->size = newKipSize;
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return 0;
}
const char* pkg2_patch_kips(link_t *info, char* patchNames)
{
if (patchNames == NULL || patchNames[0] == 0)
return NULL;
static const u32 MAX_NUM_PATCHES_REQUESTED = sizeof(u32)*8;
char* patches[MAX_NUM_PATCHES_REQUESTED];
u32 numPatches=1;
patches[0] = patchNames;
{
for (char* p = patchNames; *p != 0; p++)
{
if (*p == ',')
{
*p = 0;
patches[numPatches++] = p+1;
if (numPatches >= MAX_NUM_PATCHES_REQUESTED)
return "too_many_patches";
}
else if (*p >= 'A' && *p <= 'Z')
*p += 0x20;
}
}
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u32 patchesApplied = 0; // Bitset over patches.
for (u32 i=0; i<numPatches; i++)
{
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// Eliminate leading spaces.
for (const char* p=patches[i]; *p!=0; p++)
{
if (*p == ' ' || *p == '\t' || *p == '\r' || *p == '\n')
patches[i]++;
else
break;
}
int valueLen = strlen(patches[i]);
if (valueLen == 0)
continue;
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// Eliminate trailing spaces.
for (int chIdx=valueLen-1; chIdx>=0; chIdx--)
{
const char* p = patches[i] + chIdx;
if (*p == ' ' || *p == '\t' || *p == '\r' || *p == '\n')
valueLen = chIdx;
else
break;
}
patches[i][valueLen] = 0;
DPRINTF("Requested patch: '%s'\n", patches[i]);
}
u32 shaBuf[32/sizeof(u32)];
LIST_FOREACH_ENTRY(pkg2_kip1_info_t, ki, info, link)
{
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shaBuf[0] = 0; // sha256 for this kip not yet calculated.
for (u32 currKipIdx=0; currKipIdx<(sizeof(_kip_ids)/sizeof(_kip_ids[0])); currKipIdx++)
{
if (strncmp((const char*)ki->kip1->name, _kip_ids[currKipIdx].name, sizeof(ki->kip1->name)) != 0)
continue;
u32 bitsAffected = 0;
kip1_patchset_t* currPatchset = _kip_ids[currKipIdx].patchset;
while (currPatchset != NULL && currPatchset->name != NULL)
{
for (u32 i=0; i<numPatches; i++)
{
if (strcmp(currPatchset->name, patches[i]) != 0)
{
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bitsAffected = i + 1;
break;
}
}
currPatchset++;
}
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// Dont bother even hashing this KIP if we dont have any patches enabled for it.
if (bitsAffected == 0)
continue;
if (shaBuf[0] == 0)
{
if (!se_calc_sha256(shaBuf, ki->kip1, ki->size))
memset(shaBuf, 0, sizeof(shaBuf));
}
if (memcmp(shaBuf, _kip_ids[currKipIdx].hash, sizeof(_kip_ids[0].hash)) != 0)
continue;
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// Find out which sections are affected by the enabled patches, to know which to decompress.
bitsAffected = 0;
currPatchset = _kip_ids[currKipIdx].patchset;
while (currPatchset != NULL && currPatchset->name != NULL)
{
if (currPatchset->patches != NULL)
{
for (u32 currEnabIdx=0; currEnabIdx<numPatches; currEnabIdx++)
{
if (strcmp(currPatchset->name, patches[currEnabIdx]))
continue;
for (const kip1_patch_t* currPatch=currPatchset->patches; currPatch != NULL && currPatch->length != 0; currPatch++)
bitsAffected |= 1u << GET_KIP_PATCH_SECTION(currPatch->offset);
}
}
currPatchset++;
}
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// Got patches to apply to this kip, have to decompress it.
#ifdef DEBUG_PRINTING
u32 preDecompTime = get_tmr_us();
#endif
if (pkg2_decompress_kip(ki, bitsAffected))
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return (const char*)ki->kip1->name; // Failed to decompress.
#ifdef DEBUG_PRINTING
u32 postDecompTime = get_tmr_us();
if (!se_calc_sha256(shaBuf, ki->kip1, ki->size))
memset(shaBuf, 0, sizeof(shaBuf));
DPRINTF("%dms %s KIP1 size %d hash %08X\n", (postDecompTime-preDecompTime)/1000, ki->kip1->name, (int)ki->size, __builtin_bswap32(shaBuf[0]));
#endif
currPatchset = _kip_ids[currKipIdx].patchset;
while (currPatchset != NULL && currPatchset->name != NULL)
{
for (u32 currEnabIdx=0; currEnabIdx<numPatches; currEnabIdx++)
{
if (strcmp(currPatchset->name, patches[currEnabIdx]))
continue;
u32 appliedMask = 1u << currEnabIdx;
if (currPatchset->patches == NULL)
{
gfx_printf(&gfx_con, "Patch '%s' not necessary for %s KIP1\n", currPatchset->name, (const char*)ki->kip1->name);
patchesApplied |= appliedMask;
break;
}
unsigned char* kipSectData = ki->kip1->data;
for (u32 currSectIdx=0; currSectIdx<KIP1_NUM_SECTIONS; currSectIdx++)
{
if (bitsAffected & (1u << currSectIdx))
{
gfx_printf(&gfx_con, "Applying patch '%s' on %s KIP1 sect %d\n", currPatchset->name, (const char*)ki->kip1->name, currSectIdx);
for (const kip1_patch_t* currPatch=currPatchset->patches;currPatch != NULL && currPatch->length != 0; currPatch++)
{
if (GET_KIP_PATCH_SECTION(currPatch->offset) != currSectIdx)
continue;
u32 currOffset = GET_KIP_PATCH_OFFSET(currPatch->offset);
if (memcmp(&kipSectData[currOffset], currPatch->srcData, currPatch->length) != 0)
{
gfx_printf(&gfx_con, "%kDATA MISMATCH FOR PATCH AT OFFSET 0x%x!!!%k\n", 0xFFFF0000, currOffset, 0xFFCCCCCC);
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return currPatchset->name; // MUST stop here as kip is likely corrupt.
}
else
{
DPRINTF("Patching %d bytes at offset 0x%x\n", currPatch->length, currOffset);
memcpy(&kipSectData[currOffset], currPatch->dstData, currPatch->length);
}
}
}
kipSectData += ki->kip1->sections[currSectIdx].size_comp;
}
patchesApplied |= appliedMask;
break;
}
currPatchset++;
}
}
}
for (u32 i=0; i<numPatches; i++)
{
if ((patchesApplied & (1u << i)) == 0)
return patches[i];
}
return NULL;
}
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pkg2_hdr_t *pkg2_decrypt(void *data)
{
u8 *pdata = (u8 *)data;
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// Skip signature.
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pdata += 0x100;
pkg2_hdr_t *hdr = (pkg2_hdr_t *)pdata;
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// Skip header.
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pdata += sizeof(pkg2_hdr_t);
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// Decrypt header.
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se_aes_crypt_ctr(8, hdr, sizeof(pkg2_hdr_t), hdr, sizeof(pkg2_hdr_t), hdr);
//gfx_hexdump(&gfx_con, (u32)hdr, hdr, 0x100);
if (hdr->magic != PKG2_MAGIC)
return NULL;
for (u32 i = 0; i < 4; i++)
{
DPRINTF("sec %d has size %08X\n", i, hdr->sec_size[i]);
if (!hdr->sec_size[i])
continue;
se_aes_crypt_ctr(8, pdata, hdr->sec_size[i], pdata, hdr->sec_size[i], &hdr->sec_ctr[i * 0x10]);
//gfx_hexdump(&gfx_con, (u32)pdata, pdata, 0x100);
pdata += hdr->sec_size[i];
}
return hdr;
}
void pkg2_build_encrypt(void *dst, void *kernel, u32 kernel_size, link_t *kips_info)
{
u8 *pdst = (u8 *)dst;
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// Signature.
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memset(pdst, 0, 0x100);
pdst += 0x100;
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// Header.
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pkg2_hdr_t *hdr = (pkg2_hdr_t *)pdst;
memset(hdr, 0, sizeof(pkg2_hdr_t));
pdst += sizeof(pkg2_hdr_t);
hdr->magic = PKG2_MAGIC;
hdr->base = 0x10000000;
DPRINTF("kernel @ %08X (%08X)\n", (u32)kernel, kernel_size);
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// Kernel.
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memcpy(pdst, kernel, kernel_size);
hdr->sec_size[PKG2_SEC_KERNEL] = kernel_size;
hdr->sec_off[PKG2_SEC_KERNEL] = 0x10000000;
se_aes_crypt_ctr(8, pdst, kernel_size, pdst, kernel_size, &hdr->sec_ctr[PKG2_SEC_KERNEL * 0x10]);
pdst += kernel_size;
DPRINTF("kernel encrypted\n");
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// INI1.
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u32 ini1_size = sizeof(pkg2_ini1_t);
pkg2_ini1_t *ini1 = (pkg2_ini1_t *)pdst;
memset(ini1, 0, sizeof(pkg2_ini1_t));
ini1->magic = INI1_MAGIC;
pdst += sizeof(pkg2_ini1_t);
LIST_FOREACH_ENTRY(pkg2_kip1_info_t, ki, kips_info, link)
{
DPRINTF("adding kip1 '%s' @ %08X (%08X)\n", ki->kip1->name, (u32)ki->kip1, ki->size);
memcpy(pdst, ki->kip1, ki->size);
pdst += ki->size;
ini1_size += ki->size;
ini1->num_procs++;
}
ini1->size = ini1_size;
hdr->sec_size[PKG2_SEC_INI1] = ini1_size;
hdr->sec_off[PKG2_SEC_INI1] = 0x14080000;
se_aes_crypt_ctr(8, ini1, ini1_size, ini1, ini1_size, &hdr->sec_ctr[PKG2_SEC_INI1 * 0x10]);
DPRINTF("INI1 encrypted\n");
//Encrypt header.
*(u32 *)hdr->ctr = 0x100 + sizeof(pkg2_hdr_t) + kernel_size + ini1_size;
se_aes_crypt_ctr(8, hdr, sizeof(pkg2_hdr_t), hdr, sizeof(pkg2_hdr_t), hdr);
memset(hdr->ctr, 0 , 0x10);
*(u32 *)hdr->ctr = 0x100 + sizeof(pkg2_hdr_t) + kernel_size + ini1_size;
}