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https://github.com/Atmosphere-NX/Atmosphere.git
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3f3aaa01fa
subrepo: subdir: "emummc" merged: "c6717b93" upstream: origin: "https://github.com/m4xw/emummc" branch: "develop" commit: "c6717b93" git-subrepo: version: "0.4.1" origin: "???" commit: "???"
525 lines
14 KiB
C
Vendored
525 lines
14 KiB
C
Vendored
/*
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* Copyright (c) 2019 m4xw <m4x@m4xw.net>
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* Copyright (c) 2019 Atmosphere-NX
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* Copyright (c) 2019 CTCaer
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*
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* This program is free software; you can redistribute it and/or modify it
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* under the terms and conditions of the GNU General Public License,
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* version 2, as published by the Free Software Foundation.
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*
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* This program is distributed in the hope it will be useful, but WITHOUT
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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* more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <stdlib.h>
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#include "emummc.h"
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#include "emummc_ctx.h"
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#include "../utils/fatal.h"
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#include "../libs/fatfs/diskio.h"
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static bool sdmmc_first_init = false;
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static bool storageSDinitialized = false;
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// hekate sdmmmc vars
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sdmmc_t sdmmc;
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sdmmc_storage_t storage;
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sdmmc_t sd_sdmmc;
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sdmmc_storage_t sd_storage;
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// init vars
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bool init_done = false;
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bool custom_driver = true;
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// FS funcs
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_sdmmc_accessor_gc sdmmc_accessor_gc;
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_sdmmc_accessor_sd sdmmc_accessor_sd;
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_sdmmc_accessor_nand sdmmc_accessor_nand;
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_lock_mutex lock_mutex;
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_unlock_mutex unlock_mutex;
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// FS misc
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void *sd_mutex;
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void *nand_mutex;
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volatile int *active_partition;
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volatile Handle *sdmmc_das_handle;
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// FatFS
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file_based_ctxt f_emu;
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static bool fat_mounted = false;
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static void _sdmmc_ensure_device_attached(void)
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{
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// This ensures that the sd device address space handle is always attached,
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// even if FS hasn't attached it
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static bool did_attach = false;
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if (!did_attach)
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{
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svcAttachDeviceAddressSpace(DeviceName_SDMMC1A, *sdmmc_das_handle);
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did_attach = true;
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}
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}
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static void _sdmmc_ensure_initialized(void)
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{
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// First Initial init
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if (!sdmmc_first_init)
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{
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sdmmc_initialize();
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sdmmc_first_init = true;
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}
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else
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{
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// The boot sysmodule will eventually kill power to SD.
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// Detect this, and reinitialize when it happens.
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if (!init_done)
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{
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if (sdmmc_get_sd_power_enabled() == 0)
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{
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sdmmc_finalize();
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sdmmc_initialize();
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init_done = true;
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}
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}
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}
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}
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static void _file_based_update_filename(char *outFilename, u32 sd_path_len, u32 part_idx)
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{
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snprintf(outFilename + sd_path_len, 3, "%02d", part_idx);
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}
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static void _file_based_emmc_finalize(void)
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{
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if ((emuMMC_ctx.EMMC_Type == emuMMC_SD_File) && fat_mounted)
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{
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// Close all open handles.
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f_close(&f_emu.fp_boot0);
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f_close(&f_emu.fp_boot1);
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for (int i = 0; i < f_emu.parts; i++)
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{
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f_close(&f_emu.fp_gpp[i]);
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}
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// Force unmount FAT volume.
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f_mount(NULL, "", 1);
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fat_mounted = false;
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}
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}
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void sdmmc_finalize(void)
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{
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if (!sdmmc_storage_end(&sd_storage))
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{
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fatal_abort(Fatal_InitSD);
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}
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storageSDinitialized = false;
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}
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static void _file_based_emmc_initialize(void)
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{
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char path[sizeof(emuMMC_ctx.storagePath) + 0x20];
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memset(&path, 0, sizeof(path));
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memcpy(path, (void *)emuMMC_ctx.storagePath, sizeof(emuMMC_ctx.storagePath));
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strcat(path, "/eMMC/");
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int path_len = strlen(path);
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// Open BOOT0 physical partition.
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memcpy(path + path_len, "BOOT0", 6);
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if (f_open(&f_emu.fp_boot0, path, FA_READ | FA_WRITE) != FR_OK)
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fatal_abort(Fatal_FatfsFileOpen);
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if (!f_expand_cltbl(&f_emu.fp_boot0, 0x400, f_emu.clmt_boot0, f_size(&f_emu.fp_boot0)))
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fatal_abort(Fatal_FatfsMemExhaustion);
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// Open BOOT1 physical partition.
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memcpy(path + path_len, "BOOT1", 6);
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if (f_open(&f_emu.fp_boot1, path, FA_READ | FA_WRITE) != FR_OK)
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fatal_abort(Fatal_FatfsFileOpen);
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if (!f_expand_cltbl(&f_emu.fp_boot1, 0x400, f_emu.clmt_boot1, f_size(&f_emu.fp_boot1)))
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fatal_abort(Fatal_FatfsMemExhaustion);
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// Open handles for GPP physical partition files.
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_file_based_update_filename(path, path_len, 00);
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if (f_open(&f_emu.fp_gpp[0], path, FA_READ | FA_WRITE) != FR_OK)
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fatal_abort(Fatal_FatfsFileOpen);
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if (!f_expand_cltbl(&f_emu.fp_gpp[0], 0x400, &f_emu.clmt_gpp[0], f_size(&f_emu.fp_gpp[0])))
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fatal_abort(Fatal_FatfsMemExhaustion);
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f_emu.part_size = f_size(&f_emu.fp_gpp[0]) >> 9;
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// Iterate folder for split parts and stop if next doesn't exist.
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// Supports up to 32 parts of any size.
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// TODO: decide on max parts and define them. (hekate produces up to 30 parts on 1GB mode.)
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for (f_emu.parts = 1; f_emu.parts < 32; f_emu.parts++)
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{
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_file_based_update_filename(path, path_len, f_emu.parts);
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if (f_open(&f_emu.fp_gpp[f_emu.parts], path, FA_READ | FA_WRITE) != FR_OK)
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{
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// Check if single file.
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if (f_emu.parts == 1)
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f_emu.parts = 0;
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return;
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}
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if (!f_expand_cltbl(&f_emu.fp_gpp[f_emu.parts], 0x400, &f_emu.clmt_gpp[f_emu.parts * 0x400], f_size(&f_emu.fp_gpp[f_emu.parts])))
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fatal_abort(Fatal_FatfsMemExhaustion);
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}
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}
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bool sdmmc_initialize(void)
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{
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if (!storageSDinitialized)
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{
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int retries = 3;
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while (retries)
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{
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if (nx_sd_initialize(false))
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{
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storageSDinitialized = true;
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// File based emummc.
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if ((emuMMC_ctx.EMMC_Type == emuMMC_SD_File) && !fat_mounted)
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{
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if (f_mount(&f_emu.sd_fs, "", 1) != FR_OK)
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fatal_abort(Fatal_InitSD);
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else
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fat_mounted = true;
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_file_based_emmc_initialize();
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}
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break;
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}
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retries--;
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}
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if (!storageSDinitialized)
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{
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fatal_abort(Fatal_InitSD);
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}
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}
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return storageSDinitialized;
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}
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sdmmc_accessor_t *sdmmc_accessor_get(int mmc_id)
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{
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sdmmc_accessor_t *_this;
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switch (mmc_id)
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{
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case FS_SDMMC_EMMC:
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_this = sdmmc_accessor_nand();
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break;
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case FS_SDMMC_SD:
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_this = sdmmc_accessor_sd();
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break;
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case FS_SDMMC_GC:
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_this = sdmmc_accessor_gc();
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break;
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default:
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fatal_abort(Fatal_InvalidAccessor);
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}
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return _this;
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}
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void mutex_lock_handler(int mmc_id)
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{
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if (custom_driver)
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{
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lock_mutex(sd_mutex);
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}
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lock_mutex(nand_mutex);
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}
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void mutex_unlock_handler(int mmc_id)
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{
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unlock_mutex(nand_mutex);
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if (custom_driver)
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{
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unlock_mutex(sd_mutex);
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}
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}
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int sdmmc_nand_get_active_partition_index()
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{
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switch (*active_partition)
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{
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case FS_EMMC_PARTITION_GPP:
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return 2;
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case FS_EMMC_PARTITION_BOOT1:
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return 1;
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case FS_EMMC_PARTITION_BOOT0:
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return 0;
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}
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fatal_abort(Fatal_InvalidAccessor);
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}
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static uint64_t emummc_read_write_inner(void *buf, unsigned int sector, unsigned int num_sectors, bool is_write)
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{
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if ((emuMMC_ctx.EMMC_Type == emuMMC_SD_Raw))
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{
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// raw partition sector offset: emuMMC_ctx.EMMC_StoragePartitionOffset.
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sector += emuMMC_ctx.EMMC_StoragePartitionOffset;
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// Set physical partition offset.
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sector += (sdmmc_nand_get_active_partition_index() * BOOT_PARTITION_SIZE);
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if (!is_write)
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return sdmmc_storage_read(&sd_storage, sector, num_sectors, buf);
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else
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return sdmmc_storage_write(&sd_storage, sector, num_sectors, buf);
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}
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// File based emummc.
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FIL *fp = NULL;
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switch (*active_partition)
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{
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case FS_EMMC_PARTITION_GPP:
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if (f_emu.parts)
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{
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fp = &f_emu.fp_gpp[sector / f_emu.part_size];
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sector = sector % f_emu.part_size;
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// Special handling for reads/writes which cross file-boundaries.
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if (__builtin_expect(sector + num_sectors > f_emu.part_size, 0))
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{
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unsigned int remaining = num_sectors;
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while (remaining > 0) {
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const unsigned int cur_sectors = MIN(remaining, f_emu.part_size - sector);
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if (f_lseek(fp, (u64)sector << 9) != FR_OK)
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return 0; // Out of bounds.
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if (is_write)
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{
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if (f_write_fast(fp, buf, (u64)cur_sectors << 9) != FR_OK)
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return 0;
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}
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else
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{
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if (f_read_fast(fp, buf, (u64)cur_sectors << 9) != FR_OK)
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return 0;
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}
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buf = (char *)buf + ((u64)cur_sectors << 9);
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remaining -= cur_sectors;
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sector = 0;
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++fp;
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}
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return 1;
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}
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}
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else
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{
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fp = &f_emu.fp_gpp[0];
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}
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break;
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case FS_EMMC_PARTITION_BOOT1:
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fp = &f_emu.fp_boot1;
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break;
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case FS_EMMC_PARTITION_BOOT0:
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fp = &f_emu.fp_boot0;
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break;
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}
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if (f_lseek(fp, (u64)sector << 9) != FR_OK)
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return 0; // Out of bounds.
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uint64_t res = 0;
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if (!is_write)
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res = !f_read_fast(fp, buf, (u64)num_sectors << 9);
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else
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res = !f_write_fast(fp, buf, (u64)num_sectors << 9);
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return res;
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}
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// Controller open wrapper
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uint64_t sdmmc_wrapper_controller_open(int mmc_id)
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{
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uint64_t result;
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sdmmc_accessor_t *_this;
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_this = sdmmc_accessor_get(mmc_id);
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if (_this != NULL)
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{
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// Lock eMMC xfer while SD card is being initialized by FS.
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if (mmc_id == FS_SDMMC_SD)
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mutex_lock_handler(FS_SDMMC_EMMC); // Recursive Mutex, handler will lock SD as well if custom_driver
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result = _this->vtab->sdmmc_accessor_controller_open(_this);
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// Unlock eMMC.
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if (mmc_id == FS_SDMMC_SD)
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mutex_unlock_handler(FS_SDMMC_EMMC);
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return result;
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}
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fatal_abort(Fatal_OpenAccessor);
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}
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// Controller close wrapper
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uint64_t sdmmc_wrapper_controller_close(int mmc_id)
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{
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sdmmc_accessor_t *_this;
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_this = sdmmc_accessor_get(mmc_id);
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if (_this != NULL)
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{
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if (mmc_id == FS_SDMMC_SD)
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{
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return 0;
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}
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if (mmc_id == FS_SDMMC_EMMC)
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{
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// Close file handles and unmount
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_file_based_emmc_finalize();
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// Close SD
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sdmmc_accessor_get(FS_SDMMC_SD)->vtab->sdmmc_accessor_controller_close(sdmmc_accessor_get(FS_SDMMC_SD));
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// Close eMMC
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return _this->vtab->sdmmc_accessor_controller_close(_this);
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}
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return _this->vtab->sdmmc_accessor_controller_close(_this);
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}
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fatal_abort(Fatal_CloseAccessor);
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}
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// FS read wrapper.
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uint64_t sdmmc_wrapper_read(void *buf, uint64_t bufSize, int mmc_id, unsigned int sector, unsigned int num_sectors)
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{
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sdmmc_accessor_t *_this;
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uint64_t read_res;
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_this = sdmmc_accessor_get(mmc_id);
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if (_this != NULL)
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{
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if (mmc_id == FS_SDMMC_EMMC || mmc_id == FS_SDMMC_SD)
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{
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mutex_lock_handler(mmc_id);
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// Assign FS accessor to the SDMMC driver
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_current_accessor = _this;
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// Make sure we're attached to the device address space.
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_sdmmc_ensure_device_attached();
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// Make sure we're still initialized if boot killed sd card power.
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_sdmmc_ensure_initialized();
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}
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if (mmc_id == FS_SDMMC_EMMC)
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{
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// Call hekates driver.
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if (emummc_read_write_inner(buf, sector, num_sectors, false))
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{
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mutex_unlock_handler(mmc_id);
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return 0;
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}
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mutex_unlock_handler(mmc_id);
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return FS_READ_WRITE_ERROR;
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}
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if (mmc_id == FS_SDMMC_SD)
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{
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static bool first_sd_read = true;
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if (first_sd_read)
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{
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first_sd_read = false;
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if (emuMMC_ctx.EMMC_Type == emuMMC_SD_Raw)
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{
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// Because some SD cards have issues with emuMMC's driver
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// we currently swap to FS's driver after first SD read
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// for raw based emuMMC
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custom_driver = false;
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// FS will handle sd mutex w/o custom driver from here on
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unlock_mutex(sd_mutex);
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}
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}
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// Call hekate's driver.
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if (sdmmc_storage_read(&sd_storage, sector, num_sectors, buf))
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{
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mutex_unlock_handler(mmc_id);
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return 0;
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}
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mutex_unlock_handler(mmc_id);
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return FS_READ_WRITE_ERROR;
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}
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read_res = _this->vtab->read_write(_this, sector, num_sectors, buf, bufSize, 1);
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return read_res;
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}
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fatal_abort(Fatal_ReadNoAccessor);
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}
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// FS write wrapper.
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uint64_t sdmmc_wrapper_write(int mmc_id, unsigned int sector, unsigned int num_sectors, void *buf, uint64_t bufSize)
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{
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sdmmc_accessor_t *_this;
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uint64_t write_res;
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_this = sdmmc_accessor_get(mmc_id);
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if (_this != NULL)
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{
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if (mmc_id == FS_SDMMC_EMMC)
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{
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mutex_lock_handler(mmc_id);
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_current_accessor = _this;
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// Call hekates driver.
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if (emummc_read_write_inner(buf, sector, num_sectors, true))
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{
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mutex_unlock_handler(mmc_id);
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return 0;
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}
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mutex_unlock_handler(mmc_id);
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return FS_READ_WRITE_ERROR;
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}
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if (mmc_id == FS_SDMMC_SD)
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{
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mutex_lock_handler(mmc_id);
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_current_accessor = _this;
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sector += 0;
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// Call hekates driver.
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if (sdmmc_storage_write(&sd_storage, sector, num_sectors, buf))
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{
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mutex_unlock_handler(mmc_id);
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return 0;
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}
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mutex_unlock_handler(mmc_id);
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return FS_READ_WRITE_ERROR;
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}
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write_res = _this->vtab->read_write(_this, sector, num_sectors, buf, bufSize, 0);
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return write_res;
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}
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fatal_abort(Fatal_WriteNoAccessor);
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}
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