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hekate/nyx/nyx_gui/frontend/gui_info.c
2021-01-11 21:39:44 +02:00

2204 lines
63 KiB
C

/*
* Copyright (c) 2018 naehrwert
* 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 "gui.h"
#include <display/di.h>
#include "../config.h"
#include "../hos/hos.h"
#include "../hos/pkg1.h"
#include "../hos/sept.h"
#include <libs/fatfs/ff.h>
#include <input/touch.h>
#include <mem/emc.h>
#include <mem/heap.h>
#include <mem/sdram.h>
#include <mem/smmu.h>
#include <power/bm92t36.h>
#include <power/bq24193.h>
#include <power/max17050.h>
#include <power/max77620.h>
#include <power/max7762x.h>
#include <power/max77812.h>
#include <sec/se.h>
#include <sec/tsec.h>
#include <soc/fuse.h>
#include <soc/kfuse.h>
#include <soc/i2c.h>
#include <soc/t210.h>
#include <storage/mmc.h>
#include "../storage/nx_emmc_bis.h"
#include <storage/nx_sd.h>
#include <storage/sdmmc.h>
#include <utils/btn.h>
#include <utils/sprintf.h>
#include <utils/util.h>
#define SECTORS_TO_MIB_COEFF 11
extern hekate_config h_cfg;
extern volatile boot_cfg_t *b_cfg;
extern volatile nyx_storage_t *nyx_str;
extern char *emmcsn_path_impl(char *path, char *sub_dir, char *filename, sdmmc_storage_t *storage);
static u8 *cal0_buf = NULL;
static lv_res_t _create_window_dump_done(int error, char *dump_filenames)
{
lv_obj_t *dark_bg = lv_obj_create(lv_scr_act(), NULL);
lv_obj_set_style(dark_bg, &mbox_darken);
lv_obj_set_size(dark_bg, LV_HOR_RES, LV_VER_RES);
static const char * mbox_btn_map[] = { "\211", "\222OK", "\211", "" };
lv_obj_t * mbox = lv_mbox_create(dark_bg, NULL);
lv_mbox_set_recolor_text(mbox, true);
lv_obj_set_width(mbox, LV_HOR_RES / 9 * 5);
char *txt_buf = (char *)malloc(0x1000);
if (error)
s_printf(txt_buf, "#FFDD00 Failed to dump to# %s#FFDD00 !#\nError: %d", dump_filenames, error);
else
{
char *sn = emmcsn_path_impl(NULL, NULL, NULL, NULL);
s_printf(txt_buf, "Dumping to SD card finished!\nFiles: #C7EA46 backup/%s/dumps/#\n%s", sn, dump_filenames);
}
lv_mbox_set_text(mbox, txt_buf);
lv_mbox_add_btns(mbox, mbox_btn_map, mbox_action); // Important. After set_text.
lv_obj_align(mbox, NULL, LV_ALIGN_CENTER, 0, 0);
lv_obj_set_top(mbox, true);
return LV_RES_OK;
}
static lv_res_t _cal0_dump_window_action(lv_obj_t *btns, const char * txt)
{
int btn_idx = lv_btnm_get_pressed(btns);
mbox_action(btns, txt);
if (btn_idx == 1)
{
int error = !sd_mount();
if (!error)
{
char path[64];
emmcsn_path_impl(path, "/dumps", "cal0.bin", NULL);
error = sd_save_to_file((u8 *)cal0_buf, 0x8000, path);
sd_unmount();
}
_create_window_dump_done(error, "cal0.bin");
}
return LV_RES_INV;
}
static lv_res_t _battery_dump_window_action(lv_obj_t * btn)
{
int error = !sd_mount();
if (!error)
{
char path[64];
u8 *buf = (u8 *)malloc(0x100 * 2);
// Unlock model table.
u16 unlock = 0x59;
i2c_send_buf_small(I2C_1, MAXIM17050_I2C_ADDR, MAX17050_MODELEnable1, (u8 *)&unlock, 2);
unlock = 0xC4;
i2c_send_buf_small(I2C_1, MAXIM17050_I2C_ADDR, MAX17050_MODELEnable2, (u8 *)&unlock, 2);
// Dump all battery fuel gauge registers.
for (int i = 0; i < 0x200; i += 2)
{
i2c_recv_buf_small(buf + i, 2, I2C_1, MAXIM17050_I2C_ADDR, i >> 1);
msleep(1);
}
// Lock model table.
unlock = 0;
i2c_send_buf_small(I2C_1, MAXIM17050_I2C_ADDR, MAX17050_MODELEnable1, (u8 *)&unlock, 2);
i2c_send_buf_small(I2C_1, MAXIM17050_I2C_ADDR, MAX17050_MODELEnable2, (u8 *)&unlock, 2);
emmcsn_path_impl(path, "/dumps", "fuel_gauge.bin", NULL);
error = sd_save_to_file((u8 *)buf, 0x200, path);
sd_unmount();
}
_create_window_dump_done(error, "fuel_gauge.bin");
return LV_RES_OK;
}
static lv_res_t _bootrom_dump_window_action(lv_obj_t * btn)
{
static const u32 BOOTROM_SIZE = 0x18000;
int error = !sd_mount();
if (!error)
{
char path[64];
u32 iram_evp_thunks[0x200];
u32 iram_evp_thunks_len = sizeof(iram_evp_thunks);
error = fuse_read_evp_thunk(iram_evp_thunks, &iram_evp_thunks_len);
if (!error)
{
emmcsn_path_impl(path, "/dumps", "evp_thunks.bin", NULL);
error = sd_save_to_file((u8 *)iram_evp_thunks, iram_evp_thunks_len, path);
}
else
error = 255;
emmcsn_path_impl(path, "/dumps", "bootrom_patched.bin", NULL);
int res = sd_save_to_file((u8 *)BOOTROM_BASE, BOOTROM_SIZE, path);
if (!error)
error = res;
u32 ipatch_backup[14];
memcpy(ipatch_backup, (void *)IPATCH_BASE, sizeof(ipatch_backup));
memset((void*)IPATCH_BASE, 0, sizeof(ipatch_backup));
emmcsn_path_impl(path, "/dumps", "bootrom_unpatched.bin", NULL);
res = sd_save_to_file((u8 *)BOOTROM_BASE, BOOTROM_SIZE, path);
if (!error)
error = res;
memcpy((void*)IPATCH_BASE, ipatch_backup, sizeof(ipatch_backup));
sd_unmount();
}
_create_window_dump_done(error, "evp_thunks.bin, bootrom_patched.bin, bootrom_unpatched.bin");
return LV_RES_OK;
}
static lv_res_t _fuse_dump_window_action(lv_obj_t * btn)
{
const u32 fuse_array_size_t210 = 192 * sizeof(u32);
const u32 fuse_array_size_t210b01 = 256 * sizeof(u32);
int error = !sd_mount();
if (!error)
{
char path[128];
if (!h_cfg.t210b01)
{
emmcsn_path_impl(path, "/dumps", "fuse_cached_t210.bin", NULL);
error = sd_save_to_file((u8 *)0x7000F900, 0x300, path);
}
else
{
emmcsn_path_impl(path, "/dumps", "fuse_cached_t210b01_x898.bin", NULL);
error = sd_save_to_file((u8 *)0x7000F898, 0x68, path);
emmcsn_path_impl(path, "/dumps", "fuse_cached_t210b01_x900.bin", NULL);
if (!error)
error = sd_save_to_file((u8 *)0x7000F900, 0x300, path);
}
u32 words[fuse_array_size_t210b01 / sizeof(u32)];
fuse_read_array(words);
if (!h_cfg.t210b01)
emmcsn_path_impl(path, "/dumps", "fuse_array_raw_t210.bin", NULL);
else
emmcsn_path_impl(path, "/dumps", "fuse_array_raw_t210b01.bin", NULL);
int res = sd_save_to_file((u8 *)words, h_cfg.t210b01 ? fuse_array_size_t210b01 : fuse_array_size_t210, path);
if (!error)
error = res;
sd_unmount();
}
if (!h_cfg.t210b01)
_create_window_dump_done(error, "fuse_cached_t210.bin, fuse_array_raw_t210.bin");
else
_create_window_dump_done(error, "fuse_cached_t210b01_partX.bin, fuse_array_raw_t210b01.bin");
return LV_RES_OK;
}
static lv_res_t _kfuse_dump_window_action(lv_obj_t * btn)
{
u32 buf[KFUSE_NUM_WORDS];
int error = !kfuse_read(buf);
if (!error)
error = !sd_mount();
if (!error)
{
char path[64];
emmcsn_path_impl(path, "/dumps", "kfuses.bin", NULL);
error = sd_save_to_file((u8 *)buf, KFUSE_NUM_WORDS * 4, path);
sd_unmount();
}
_create_window_dump_done(error, "kfuses.bin");
return LV_RES_OK;
}
static u32 tsec_keys[8];
static lv_res_t _tsec_keys_dump_window_action(lv_obj_t * btn)
{
int error = !sd_mount();
if (!error)
{
char path[64];
emmcsn_path_impl(path, "/dumps", "tsec_keys.bin", NULL);
error = sd_save_to_file(tsec_keys, 0x10 * 2, path);
sd_unmount();
}
_create_window_dump_done(error, "tsec_keys.bin");
return LV_RES_OK;
}
static lv_res_t _create_mbox_cal0(lv_obj_t *btn)
{
lv_obj_t *dark_bg = lv_obj_create(lv_scr_act(), NULL);
lv_obj_set_style(dark_bg, &mbox_darken);
lv_obj_set_size(dark_bg, LV_HOR_RES, LV_VER_RES);
static const char * mbox_btn_map[] = { "\211", "\222Dump", "\222Close", "\211", "" };
lv_obj_t * mbox = lv_mbox_create(dark_bg, NULL);
lv_mbox_set_recolor_text(mbox, true);
lv_obj_set_width(mbox, LV_HOR_RES / 9 * 5);
lv_mbox_set_text(mbox, "#C7EA46 CAL0 Info#");
char *txt_buf = (char *)malloc(0x4000);
txt_buf[0] = 0;
lv_obj_t * lb_desc = lv_label_create(mbox, NULL);
lv_label_set_long_mode(lb_desc, LV_LABEL_LONG_BREAK);
lv_label_set_recolor(lb_desc, true);
lv_label_set_style(lb_desc, &monospace_text);
lv_obj_set_width(lb_desc, LV_HOR_RES / 9 * 3);
sd_mount();
// Read package1.
static const u32 BOOTLOADER_SIZE = 0x40000;
static const u32 BOOTLOADER_MAIN_OFFSET = 0x100000;
static const u32 BOOTLOADER_BACKUP_OFFSET = 0x140000;
static const u32 HOS_KEYBLOBS_OFFSET = 0x180000;
u8 kb = 0;
u32 bootloader_offset = BOOTLOADER_MAIN_OFFSET;
u32 pk1_offset = h_cfg.t210b01 ? sizeof(bl_hdr_t210b01_t) : 0; // Skip T210B01 OEM header.
u8 *pkg1 = (u8 *)malloc(BOOTLOADER_SIZE);
sdmmc_storage_init_mmc(&emmc_storage, &emmc_sdmmc, SDMMC_BUS_WIDTH_8, SDHCI_TIMING_MMC_HS400);
sdmmc_storage_set_mmc_partition(&emmc_storage, EMMC_BOOT0);
try_load:
sdmmc_storage_read(&emmc_storage, bootloader_offset / NX_EMMC_BLOCKSIZE, BOOTLOADER_SIZE / NX_EMMC_BLOCKSIZE, pkg1);
char *build_date = malloc(32);
const pkg1_id_t *pkg1_id = pkg1_identify(pkg1 + pk1_offset, build_date);
s_printf(txt_buf + strlen(txt_buf), "#00DDFF Found pkg1 ('%s')#\n", build_date);
free(build_date);
if (!pkg1_id)
{
strcat(txt_buf, "#FFDD00 Unknown pkg1 version for reading#\n#FFDD00 TSEC firmware!#\n");
// Try backup bootloader.
if (bootloader_offset != BOOTLOADER_BACKUP_OFFSET)
{
strcat(txt_buf, "Trying backup bootloader...\n");
bootloader_offset = BOOTLOADER_BACKUP_OFFSET;
goto try_load;
}
lv_label_set_text(lb_desc, txt_buf);
goto out;
}
kb = pkg1_id->kb;
// Skip if Mariko.
if (h_cfg.t210b01)
goto t210b01;
tsec_ctxt_t tsec_ctxt;
tsec_ctxt.fw = (u8 *)pkg1 + pkg1_id->tsec_off;
tsec_ctxt.pkg1 = pkg1;
tsec_ctxt.pkg11_off = pkg1_id->pkg11_off;
tsec_ctxt.secmon_base = pkg1_id->secmon_base;
// Get keys.
hos_eks_get();
if (kb >= KB_FIRMWARE_VERSION_700 && !h_cfg.sept_run)
{
u32 key_idx = 0;
if (kb >= KB_FIRMWARE_VERSION_810)
key_idx = 1;
if (h_cfg.eks && h_cfg.eks->enabled[key_idx] >= kb)
h_cfg.sept_run = true;
else
{
b_cfg->autoboot = 0;
b_cfg->autoboot_list = 0;
b_cfg->extra_cfg = EXTRA_CFG_NYX_BIS;
if (!reboot_to_sept((u8 *)tsec_ctxt.fw, kb))
{
lv_label_set_text(lb_desc, "#FFDD00 Failed to run sept#\n");
goto out;
}
}
}
t210b01:;
// Read the correct keyblob.
u8 *keyblob = (u8 *)calloc(NX_EMMC_BLOCKSIZE, 1);
sdmmc_storage_read(&emmc_storage, HOS_KEYBLOBS_OFFSET / NX_EMMC_BLOCKSIZE + kb, 1, keyblob);
// Generate BIS keys
hos_bis_keygen(keyblob, kb, &tsec_ctxt);
free(keyblob);
if (!cal0_buf)
cal0_buf = malloc(0x10000);
// Read and decrypt CAL0.
sdmmc_storage_set_mmc_partition(&emmc_storage, EMMC_GPP);
LIST_INIT(gpt);
nx_emmc_gpt_parse(&gpt, &emmc_storage);
emmc_part_t *cal0_part = nx_emmc_part_find(&gpt, "PRODINFO"); // check if null
nx_emmc_bis_init(cal0_part);
nx_emmc_bis_read(0, 0x40, cal0_buf);
// Clear BIS keys slots.
hos_bis_keys_clear();
nx_emmc_cal0_t *cal0 = (nx_emmc_cal0_t *)cal0_buf;
// If successful, save BIS keys.
if (memcmp(&cal0->magic, "CAL0", 4))
{
free(cal0_buf);
cal0_buf = NULL;
hos_eks_bis_clear();
lv_label_set_text(lb_desc, "#FFDD00 CAL0 is corrupt or wrong keys!#\n");
goto out;
}
else
hos_eks_bis_save();
u32 hash[8];
se_calc_sha256_oneshot(hash, (u8 *)cal0 + 0x40, cal0->body_size);
s_printf(txt_buf,
"#FF8000 CAL0 Version:# %d\n"
"#FF8000 Update Count:# %d\n"
"#FF8000 Serial Number:# %s\n"
"#FF8000 WLAN MAC:# %02X:%02X:%02X:%02X:%02X:%02X\n"
"#FF8000 Bluetooth MAC:# %02X:%02X:%02X:%02X:%02X:%02X\n"
"#FF8000 Battery LOT:# %s\n"
"#FF8000 LCD Vendor:# ",
cal0->version, cal0->update_cnt, cal0->serial_number,
cal0->wlan_mac[0], cal0->wlan_mac[1], cal0->wlan_mac[2], cal0->wlan_mac[3], cal0->wlan_mac[4], cal0->wlan_mac[5],
cal0->bd_mac[0], cal0->bd_mac[1], cal0->bd_mac[2], cal0->bd_mac[3], cal0->bd_mac[4], cal0->bd_mac[5],
cal0->battery_lot);
u8 display_rev = (nyx_str->info.disp_id >> 8) & 0xFF;
u32 display_id = (cal0->lcd_vendor & 0xFF) << 8 | (cal0->lcd_vendor & 0xFF0000) >> 16;
switch (display_id)
{
case PANEL_JDI_LAM062M109A:
strcat(txt_buf, "JDI LAM062M109A");
break;
case PANEL_JDI_LPM062M326A:
strcat(txt_buf, "JDI LPM062M326A");
break;
case PANEL_INL_P062CCA_AZ1:
strcat(txt_buf, "InnoLux P062CCA-AZ");
switch (display_rev)
{
case 0x93:
strcat(txt_buf, "1");
break;
case 0x95:
strcat(txt_buf, "2");
break;
case 0x96:
strcat(txt_buf, "3");
break;
default:
strcat(txt_buf, "X");
break;
}
break;
case PANEL_AUO_A062TAN01:
strcat(txt_buf, "AUO A062TAN0");
switch (display_rev)
{
case 0x94:
strcat(txt_buf, "1");
break;
case 0x95:
strcat(txt_buf, "2");
break;
default:
strcat(txt_buf, "X");
break;
}
break;
case PANEL_INL_2J055IA_27A:
strcat(txt_buf, "InnoLux 2J055IA-27A");
break;
case PANEL_AUO_A055TAN01:
strcat(txt_buf, "AUO A055TAN01");
break;
default:
switch (cal0->lcd_vendor & 0xFF)
{
case 0:
case PANEL_JDI_XXX062M:
strcat(txt_buf, "JDI ");
break;
case (PANEL_INL_P062CCA_AZ1 & 0xFF):
strcat(txt_buf, "InnoLux ");
break;
case (PANEL_AUO_A062TAN01 & 0xFF):
strcat(txt_buf, "AUO ");
break;
}
strcat(txt_buf, "Unknown");
break;
}
bool valid_cal0 = !memcmp(hash, cal0->body_sha256, 0x20);
s_printf(txt_buf + strlen(txt_buf), " (%06X)\n#FF8000 SHA256 Hash Match:# %s", cal0->lcd_vendor, valid_cal0 ? "Pass" : "Failed");
lv_label_set_text(lb_desc, txt_buf);
out:
free(pkg1);
free(txt_buf);
sd_unmount();
sdmmc_storage_end(&emmc_storage);
lv_mbox_add_btns(mbox, mbox_btn_map, _cal0_dump_window_action);
lv_obj_align(mbox, NULL, LV_ALIGN_CENTER, 0, 0);
lv_obj_set_top(mbox, true);
return LV_RES_OK;
}
static lv_res_t _create_window_fuses_info_status(lv_obj_t *btn)
{
lv_obj_t *win = nyx_create_standard_window(SYMBOL_CHIP" HW & Cached Fuses Info");
lv_win_add_btn(win, NULL, SYMBOL_DOWNLOAD" Dump fuses", _fuse_dump_window_action);
lv_win_add_btn(win, NULL, SYMBOL_INFO" CAL0 Info", _create_mbox_cal0);
lv_obj_t *desc = lv_cont_create(win, NULL);
lv_obj_set_size(desc, LV_HOR_RES / 2 / 5 * 2, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_desc = lv_label_create(desc, NULL);
lv_label_set_long_mode(lb_desc, LV_LABEL_LONG_BREAK);
lv_label_set_recolor(lb_desc, true);
lv_label_set_style(lb_desc, &monospace_text);
lv_label_set_static_text(lb_desc,
"SKU:\n"
"DRAM ID:\n"
"#FF8000 Burnt Fuses (ODM 7/6):#\n"
"ODM Fields (4, 6, 7):\n"
"Secure Boot key (SBK):\n"
"Device key (DK):\n"
"USB Stack:\n"
"Final Test Revision:\n"
"Chip Probing Revision:\n"
"Bootrom ipatches size:\n"
"CPU Speedo 0 (CPU Val):\n"
"CPU Speedo 1:\n"
"CPU Speedo 2 (GPU Val):\n"
"SoC Speedo 0 (SoC Val):\n"
"SoC Speedo 1 (BROM rev):\n"
"SoC Speedo 2:\n"
"CPU IDDQ Val:\n"
"SoC IDDQ Val:\n"
"Gpu IDDQ Val:\n"
"Vendor Code:\n"
"FAB Code:\n"
"LOT Code 0:\n"
"LOT Code 1:\n"
"Wafer ID:\n"
"X Coordinate:\n"
"Y Coordinate:\n"
"#FF8000 Chip ID Revision:#"
);
lv_obj_set_width(lb_desc, lv_obj_get_width(desc));
lv_obj_t *val = lv_cont_create(win, NULL);
lv_obj_set_size(val, LV_HOR_RES / 11 * 3, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_val = lv_label_create(val, lb_desc);
char *txt_buf = (char *)malloc(0x4000);
// Decode fuses.
char *sku;
char dram_man[32];
char fuses_hos_version[64];
u8 dram_id = fuse_read_dramid(true);
switch (fuse_read_hw_type())
{
case FUSE_NX_HW_TYPE_ICOSA:
sku = "Icosa (Erista)";
break;
case FUSE_NX_HW_TYPE_IOWA:
sku = "Iowa (Mariko)";
break;
case FUSE_NX_HW_TYPE_HOAG:
sku = "Hoag (Mariko)";
break;
default:
sku = "#FF8000 Unknown#";
break;
}
switch (dram_id)
{
// LPDDR4 3200Mbps.
case LPDDR4_ICOSA_4GB_SAMSUNG_K4F6E304HB_MGCH:
case LPDDR4_COPPER_4GB_SAMSUNG_K4F6E304HB_MGCH:
strcpy(dram_man, "Samsung K4F6E304HB-MGCH 4GB");
break;
case LPDDR4_ICOSA_4GB_HYNIX_H9HCNNNBPUMLHR_NLE:
case LPDDR4_COPPER_4GB_HYNIX_H9HCNNNBPUMLHR_NLE:
strcpy(dram_man, "Hynix H9HCNNNBPUMLHR-NLE 4GB");
break;
case LPDDR4_ICOSA_4GB_MICRON_MT53B512M32D2NP_062_WT:
case LPDDR4_COPPER_4GB_MICRON_MT53B512M32D2NP_062_WT:
strcpy(dram_man, "Micron MT53B512M32D2NP-062");
break;
case LPDDR4_ICOSA_6GB_SAMSUNG_K4FHE3D4HM_MGCH:
strcpy(dram_man, "Samsung K4FHE3D4HM-MGCH 6GB");
break;
// LPDDR4X 3733Mbps.
case LPDDR4X_IOWA_4GB_SAMSUNG_X1X2:
strcpy(dram_man, "Samsung X1X2 4GB");
break;
case LPDDR4X_IOWA_4GB_SAMSUNG_K4U6E3S4AM_MGCJ:
case LPDDR4X_HOAG_4GB_SAMSUNG_K4U6E3S4AM_MGCJ:
strcpy(dram_man, "Samsung K4U6E3S4AM-MGCJ 4GB");
break;
case LPDDR4X_IOWA_8GB_SAMSUNG_K4UBE3D4AM_MGCJ:
case LPDDR4X_HOAG_8GB_SAMSUNG_K4UBE3D4AM_MGCJ:
strcpy(dram_man, "Samsung K4UBE3D4AM-MGCJ 8GB");
break;
case LPDDR4X_IOWA_4GB_HYNIX_H9HCNNNBKMMLHR_NME:
case LPDDR4X_HOAG_4GB_HYNIX_H9HCNNNBKMMLHR_NME:
strcpy(dram_man, "Hynix H9HCNNNBKMMLHR-NME 4GB");
break;
case LPDDR4X_IOWA_4GB_MICRON_MT53E512M32D2NP_046_WT: // 4266Mbps.
case LPDDR4X_HOAG_4GB_MICRON_MT53E512M32D2NP_046_WT: // 4266Mbps.
strcpy(dram_man, "Micron MT53E512M32D2NP-046 4GB");
break;
// LPDDR4X 4266Mbps?
case LPDDR4X_IOWA_4GB_SAMSUNG_Y:
strcpy(dram_man, "Samsung Y 4GB");
break;
case LPDDR4X_IOWA_4GB_SAMSUNG_1Y_X:
case LPDDR4X_HOAG_4GB_SAMSUNG_1Y_X:
case LPDDR4X_AULA_4GB_SAMSUNG_1Y_X:
strcpy(dram_man, "Samsung 1y X 4GB");
break;
case LPDDR4X_IOWA_8GB_SAMSUNG_1Y_X:
case LPDDR4X_AULA_8GB_SAMSUNG_1Y_X:
strcpy(dram_man, "Samsung 1y X 8GB");
break;
case LPDDR4X_IOWA_4GB_SAMSUNG_1Y_Y:
strcpy(dram_man, "Samsung 1y Y 4GB");
break;
case LPDDR4X_IOWA_8GB_SAMSUNG_1Y_Y:
strcpy(dram_man, "Samsung 1y Y 8GB");
break;
case LPDDR4X_AULA_4GB_SAMSUNG_1Y_A:
strcpy(dram_man, "Samsung 1y A 4GB");
break;
case LPDDR4X_IOWA_4GB_MICRON_1Y_A:
case LPDDR4X_HOAG_4GB_MICRON_1Y_A:
case LPDDR4X_AULA_4GB_MICRON_1Y_A:
strcpy(dram_man, "Micron 1y A 4GB");
break;
default:
strcpy(dram_man, "#FF8000 Unknown#");
break;
}
// Count burnt fuses.
u8 burnt_fuses_7 = fuse_count_burnt(fuse_read_odm(7));
u8 burnt_fuses_6 = fuse_count_burnt(fuse_read_odm(6));
switch (burnt_fuses_7)
{
case 1:
strcpy(fuses_hos_version, "1.0.0");
break;
case 2:
strcpy(fuses_hos_version, "2.0.0 - 2.3.0");
break;
case 3:
strcpy(fuses_hos_version, "3.0.0");
break;
case 4:
strcpy(fuses_hos_version, "3.0.1 - 3.0.2");
break;
case 5:
strcpy(fuses_hos_version, "4.0.0 - 4.1.0");
break;
case 6:
strcpy(fuses_hos_version, "5.0.0 - 5.1.0");
break;
case 7:
strcpy(fuses_hos_version, "6.0.0 - 6.1.0");
break;
case 8:
strcpy(fuses_hos_version, "6.2.0");
break;
case 9:
strcpy(fuses_hos_version, "7.0.0 - 8.0.1");
break;
case 10:
strcpy(fuses_hos_version, "8.1.0 - 8.1.1");
break;
case 11:
strcpy(fuses_hos_version, "9.0.0 - 9.0.1");
break;
case 12:
strcpy(fuses_hos_version, "9.1.0 - 9.2.0");
break;
case 13:
strcpy(fuses_hos_version, "10.0.0 - 10.2.0");
break;
case 14:
strcpy(fuses_hos_version, "11.0.0+");
break;
default:
strcpy(fuses_hos_version, "#FF8000 Unknown#");
break;
}
// Calculate LOT.
u32 lot_code0 = (FUSE(FUSE_OPT_LOT_CODE_0) & 0xFFFFFFF) << 2;
u32 lot_bin = 0;
for (int i = 0; i < 5; ++i)
{
u32 digit = (lot_code0 & 0xFC000000) >> 26;
lot_bin *= 36;
lot_bin += digit;
lot_code0 <<= 6;
}
u32 chip_id = APB_MISC(APB_MISC_GP_HIDREV);
// Parse fuses and display them.
s_printf(txt_buf,
"%X - %s - %s\n%02d: %s\n%d - %d (HOS: %s)\n%08X %08X %08X\n%08X%08X%08X%08X\n%08X\n"
"%s\n%d.%02d (0x%X)\n%d.%02d (0x%X)\n%d\n%d\n%d\n%d\n%d\n0x%X\n%d\n%d\n%d\n%d\n"
"%d\n%d\n%d (0x%X)\n%d\n%d\n%d\n%d\n"
"ID: %02X, Major: A0%d, Minor: %d",
FUSE(FUSE_SKU_INFO), sku, fuse_read_hw_state() ? "Dev" : "Retail",
dram_id, dram_man, burnt_fuses_7, burnt_fuses_6, fuses_hos_version,
fuse_read_odm(4), fuse_read_odm(6), fuse_read_odm(7),
byte_swap_32(FUSE(FUSE_PRIVATE_KEY0)), byte_swap_32(FUSE(FUSE_PRIVATE_KEY1)),
byte_swap_32(FUSE(FUSE_PRIVATE_KEY2)), byte_swap_32(FUSE(FUSE_PRIVATE_KEY3)),
byte_swap_32(FUSE(FUSE_PRIVATE_KEY4)),
((FUSE(FUSE_RESERVED_SW) & 0x80) || h_cfg.t210b01) ? "XUSB" : "USB2",
(FUSE(FUSE_OPT_FT_REV) >> 5) & 0x3F, FUSE(FUSE_OPT_FT_REV) & 0x1F, FUSE(FUSE_OPT_FT_REV),
(FUSE(FUSE_OPT_CP_REV) >> 5) & 0x3F, FUSE(FUSE_OPT_CP_REV) & 0x1F, FUSE(FUSE_OPT_CP_REV),
FUSE(FUSE_FIRST_BOOTROM_PATCH_SIZE) & 0x7F,
FUSE(FUSE_CPU_SPEEDO_0_CALIB), FUSE(FUSE_CPU_SPEEDO_1_CALIB), FUSE(FUSE_CPU_SPEEDO_2_CALIB),
FUSE(FUSE_SOC_SPEEDO_0_CALIB), FUSE(FUSE_SOC_SPEEDO_1_CALIB), FUSE(FUSE_SOC_SPEEDO_2_CALIB),
FUSE(FUSE_CPU_IDDQ_CALIB), FUSE(FUSE_SOC_IDDQ_CALIB), FUSE(FUSE_GPU_IDDQ_CALIB),
FUSE(FUSE_OPT_VENDOR_CODE), FUSE(FUSE_OPT_FAB_CODE), lot_bin, FUSE(FUSE_OPT_LOT_CODE_0),
FUSE(FUSE_OPT_LOT_CODE_1), FUSE(FUSE_OPT_WAFER_ID), FUSE(FUSE_OPT_X_COORDINATE), FUSE(FUSE_OPT_Y_COORDINATE),
(chip_id >> 8) & 0xFF, (chip_id >> 4) & 0xF, (chip_id >> 16) & 0xF);
lv_label_set_text(lb_val, txt_buf);
lv_obj_set_width(lb_val, lv_obj_get_width(val));
lv_obj_align(val, desc, LV_ALIGN_OUT_RIGHT_MID, 0, 0);
lv_obj_t *desc2 = lv_cont_create(win, NULL);
lv_obj_set_size(desc2, LV_HOR_RES / 2 / 5 * 4, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_desc2 = lv_label_create(desc2, NULL);
lv_label_set_long_mode(lb_desc2, LV_LABEL_LONG_BREAK);
lv_label_set_recolor(lb_desc2, true);
// DRAM info.
emc_mr_data_t ram_vendor = sdram_read_mrx(MR5_MAN_ID);
emc_mr_data_t ram_rev0 = sdram_read_mrx(MR6_REV_ID1);
emc_mr_data_t ram_rev1 = sdram_read_mrx(MR7_REV_ID2);
emc_mr_data_t ram_density = sdram_read_mrx(MR8_DENSITY);
u32 ranks = EMC(EMC_ADR_CFG) + 1;
u32 channels = (EMC(EMC_FBIO_CFG7) >> 1) & 3;
u32 die_channels = ranks * ((channels & 1) + ((channels & 2) >> 1));
s_printf(txt_buf, "#00DDFF %s SDRAM ##FF8000 (Ch 0 | Ch 1):#\n#FF8000 Vendor:# ", dram_id > 6 ? "LPDDR4X" : "LPDDR4");
switch (ram_vendor.rank0_ch0)
{
case 1:
strcat(txt_buf, "Samsung");
break;
case 6:
strcat(txt_buf, "Hynix");
break;
case 255:
strcat(txt_buf, "Micron");
break;
default:
s_printf(txt_buf + strlen(txt_buf), "#FF8000 Unknown# (%d)", ram_vendor.rank0_ch0);
break;
}
strcat(txt_buf, " #FF8000 |# ");
switch (ram_vendor.rank0_ch1)
{
case 1:
strcat(txt_buf, "Samsung");
break;
case 6:
strcat(txt_buf, "Hynix");
break;
case 255:
strcat(txt_buf, "Micron");
break;
default:
s_printf(txt_buf + strlen(txt_buf), "#FF8000 Unknown# (%d)", ram_vendor.rank0_ch1);
break;
}
s_printf(txt_buf + strlen(txt_buf), "\n#FF8000 Rev ID:# %X.%02X #FF8000 |# %X.%02X\n#FF8000 Density:# %d",
ram_rev0.rank0_ch0, ram_rev1.rank0_ch0, ram_rev0.rank0_ch1, ram_rev1.rank0_ch1, die_channels);
switch ((ram_density.rank0_ch0 & 0x3C) >> 2)
{
case 2:
strcat(txt_buf, " x 512MB");
break;
case 3:
strcat(txt_buf, " x 768MB");
break;
case 4:
strcat(txt_buf, " x 1GB");
break;
default:
s_printf(txt_buf + strlen(txt_buf), " x Unk (%d)", (ram_density.rank0_ch0 & 0x3C) >> 2);
break;
}
s_printf(txt_buf + strlen(txt_buf), " #FF8000 |# %d", die_channels);
switch ((ram_density.rank0_ch1 & 0x3C) >> 2)
{
case 2:
strcat(txt_buf, " x 512MB");
break;
case 3:
strcat(txt_buf, " x 768MB");
break;
case 4:
strcat(txt_buf, " x 1GB");
break;
default:
s_printf(txt_buf + strlen(txt_buf), " x Unk (%d)", (ram_density.rank0_ch1 & 0x3C) >> 2);
break;
}
strcat(txt_buf, "\n\n");
// Display info.
u8 display_rev = (nyx_str->info.disp_id >> 8) & 0xFF;
u32 display_id = ((nyx_str->info.disp_id >> 8) & 0xFF00) | (nyx_str->info.disp_id & 0xFF);
strcat(txt_buf, "#00DDFF Display Panel:#\n#FF8000 Model:# ");
switch (display_id)
{
case PANEL_JDI_LAM062M109A:
strcat(txt_buf, "JDI LAM062M109A");
break;
case PANEL_JDI_LPM062M326A:
strcat(txt_buf, "JDI LPM062M326A");
break;
case PANEL_INL_P062CCA_AZ1:
strcat(txt_buf, "InnoLux P062CCA");
switch (display_rev)
{
case 0x93:
strcat(txt_buf, "-AZ1");
break;
case 0x95:
strcat(txt_buf, "-AZ2");
break;
case 0x96:
strcat(txt_buf, "-AZ3");
break;
default:
strcat(txt_buf, " #FFDD00 Contact me!#");
break;
}
break;
case PANEL_AUO_A062TAN01:
strcat(txt_buf, "AUO A062");
switch (display_rev)
{
case 0x94:
strcat(txt_buf, "TAN01");
break;
case 0x95:
strcat(txt_buf, "TAN02");
break;
default:
strcat(txt_buf, " #FFDD00 Contact me!#");
break;
}
break;
case PANEL_INL_2J055IA_27A:
strcat(txt_buf, "InnoLux 2J055IA-27A");
break;
case PANEL_AUO_A055TAN01:
strcat(txt_buf, "AUO A055TAN01");
break;
default:
switch (display_id & 0xFF)
{
case PANEL_JDI_XXX062M:
strcat(txt_buf, "JDI ");
break;
case (PANEL_INL_P062CCA_AZ1 & 0xFF):
strcat(txt_buf, "InnoLux ");
break;
case (PANEL_AUO_A062TAN01 & 0xFF):
strcat(txt_buf, "AUO ");
break;
}
strcat(txt_buf, "Unknown #FFDD00 Contact me!#");
break;
}
s_printf(txt_buf + strlen(txt_buf), "\n#FF8000 ID:# [%02X] %02X [%02X]",
nyx_str->info.disp_id & 0xFF, (nyx_str->info.disp_id >> 8) & 0xFF, (nyx_str->info.disp_id >> 16) & 0xFF);
touch_fw_info_t touch_fw;
touch_panel_info_t *touch_panel;
bool panel_ic_paired = false;
if (!touch_get_fw_info(&touch_fw))
{
strcat(txt_buf, "\n\n#00DDFF Touch Panel:#\n#FF8000 Model:# ");
touch_panel = touch_get_panel_vendor();
if (touch_panel)
strcat(txt_buf, touch_panel->vendor);
else
strcat(txt_buf, "Unknown #FFDD00 Contact me!#");
s_printf(txt_buf + strlen(txt_buf), "\n#FF8000 ID:# %08X (", touch_fw.fw_id);
switch (touch_fw.fw_id)
{
case 0x00100100:
strcat(txt_buf, "4CD 1601");
if (touch_panel)
panel_ic_paired = touch_panel->idx == -1;
break;
case 0x00120100:
case 0x32000001:
strcat(txt_buf, "4CD 1801");
if (touch_panel)
panel_ic_paired = touch_panel->idx == 0;
break;
case 0x001A0300:
case 0x32000102:
strcat(txt_buf, "4CD 2602");
if (touch_panel)
panel_ic_paired = touch_panel->idx == 1;
break;
case 0x00290100:
case 0x32000302:
strcat(txt_buf, "4CD 3801");
if (touch_panel)
panel_ic_paired = touch_panel->idx == 2;
break;
case 0x31051820:
case 0x32000402:
strcat(txt_buf, "4CD XXXX");
if (touch_panel)
panel_ic_paired = touch_panel->idx == 3;
break;
case 0x32000501:
case 0x33000502:
strcat(txt_buf, "4CD UNKN");
if (touch_panel)
panel_ic_paired = touch_panel->idx == 4;
break;
default:
strcat(txt_buf, "#FF8000 Unknown#");
break;
}
s_printf(txt_buf + strlen(txt_buf), " - %s)\n#FF8000 FTB ver:# %04X\n#FF8000 FW rev:# %04X",
panel_ic_paired ? "Paired" : "#FFDD00 Error#", touch_fw.ftb_ver, touch_fw.fw_rev);
}
// Check if patched unit.
if (!fuse_check_patched_rcm())
strcat(txt_buf, "\n\n#96FF00 This unit is exploitable#\n#96FF00 to the RCM bug!#");
else
strcat(txt_buf, "\n\n#FF8000 This unit is patched#\n#FF8000 to the RCM bug!#");
lv_label_set_text(lb_desc2, txt_buf);
free(txt_buf);
lv_obj_set_width(lb_desc2, lv_obj_get_width(desc2));
lv_obj_align(desc2, val, LV_ALIGN_OUT_RIGHT_MID, LV_DPI / 2, 0);
if (!btn)
_create_mbox_cal0(NULL);
return LV_RES_OK;
}
void sept_run_cal0(void *param)
{
_create_window_fuses_info_status(NULL);
}
static char *ipatches_txt;
static void _ipatch_process(u32 offset, u32 value)
{
s_printf(ipatches_txt + strlen(ipatches_txt), "%6X %4X ", BOOTROM_BASE + offset, value);
u8 lo = value & 0xFF;
switch (value >> 8)
{
case 0x20:
s_printf(ipatches_txt + strlen(ipatches_txt), "MOVS R0, ##0x%02X", lo);
break;
case 0xDF:
s_printf(ipatches_txt + strlen(ipatches_txt), "SVC ##0x%02X", lo);
break;
}
strcat(ipatches_txt, "\n");
}
static lv_res_t _create_window_bootrom_info_status(lv_obj_t *btn)
{
lv_obj_t *win = nyx_create_standard_window(SYMBOL_CHIP" Bootrom Info");
lv_win_add_btn(win, NULL, SYMBOL_DOWNLOAD" Dump Bootrom", _bootrom_dump_window_action);
lv_obj_t *desc = lv_cont_create(win, NULL);
lv_obj_set_size(desc, LV_HOR_RES / 2 / 3 * 2, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_desc = lv_label_create(desc, NULL);
lv_label_set_long_mode(lb_desc, LV_LABEL_LONG_BREAK);
lv_label_set_recolor(lb_desc, true);
lv_label_set_style(lb_desc, &monospace_text);
char *txt_buf = (char *)malloc(0x1000);
ipatches_txt = txt_buf;
s_printf(txt_buf, "#00DDFF Ipatches:#\n#FF8000 Address "SYMBOL_DOT" Val "SYMBOL_DOT" Instruction#\n");
u32 res = fuse_read_ipatch(_ipatch_process);
if (res != 0)
s_printf(txt_buf + strlen(txt_buf), "#FFDD00 Failed to read ipatches. Error: %d#", res);
lv_label_set_text(lb_desc, txt_buf);
free(txt_buf);
lv_obj_set_width(lb_desc, lv_obj_get_width(desc));
return LV_RES_OK;
}
static lv_res_t _create_window_tsec_keys_status(lv_obj_t *btn)
{
u32 retries = 0;
tsec_ctxt_t tsec_ctxt;
lv_obj_t *win = nyx_create_standard_window(SYMBOL_CHIP" TSEC Keys");
//Disable buttons.
nyx_window_toggle_buttons(win, true);
lv_obj_t *desc = lv_cont_create(win, NULL);
lv_obj_set_size(desc, LV_HOR_RES / 2 / 2, LV_VER_RES - (LV_DPI * 11 / 6));
//lv_obj_align(desc, win, LV_ALIGN_ou_TOP_LEFT, 0, 40);
lv_obj_t * lb_desc = lv_label_create(desc, NULL);
lv_label_set_long_mode(lb_desc, LV_LABEL_LONG_BREAK);
lv_label_set_recolor(lb_desc, true);
lv_label_set_style(lb_desc, &monospace_text);
char *txt_buf = (char *)malloc(0x1000);
char *txt_buf2 = (char *)malloc(0x1000);
txt_buf[0] = 0;
// Read package1.
static const u32 BOOTLOADER_SIZE = 0x40000;
static const u32 BOOTLOADER_MAIN_OFFSET = 0x100000;
static const u32 BOOTLOADER_BACKUP_OFFSET = 0x140000;
u8 *pkg1 = (u8 *)malloc(0x40000);
u32 bootloader_offset = BOOTLOADER_MAIN_OFFSET;
try_load:
sdmmc_storage_init_mmc(&emmc_storage, &emmc_sdmmc, SDMMC_BUS_WIDTH_8, SDHCI_TIMING_MMC_HS400);
sdmmc_storage_set_mmc_partition(&emmc_storage, EMMC_BOOT0);
sdmmc_storage_read(&emmc_storage, bootloader_offset / NX_EMMC_BLOCKSIZE, BOOTLOADER_SIZE / NX_EMMC_BLOCKSIZE, pkg1);
sdmmc_storage_end(&emmc_storage);
char *build_date = malloc(32);
const pkg1_id_t *pkg1_id = pkg1_identify(pkg1, build_date);
s_printf(txt_buf + strlen(txt_buf), "#00DDFF Found pkg1 ('%s')#\n", build_date);
free(build_date);
if (!pkg1_id)
{
strcat(txt_buf, "#FFDD00 Unknown pkg1 version for reading#\n#FFDD00 TSEC firmware!#\n");
// Try backup bootloader.
if (bootloader_offset != BOOTLOADER_BACKUP_OFFSET)
{
strcat(txt_buf, "Trying backup bootloader...\n");
bootloader_offset = BOOTLOADER_BACKUP_OFFSET;
goto try_load;
}
lv_label_set_text(lb_desc, txt_buf);
lv_obj_set_width(lb_desc, lv_obj_get_width(desc));
goto out;
}
lv_label_set_text(lb_desc, txt_buf);
lv_obj_set_width(lb_desc, lv_obj_get_width(desc));
lv_obj_t *val = lv_cont_create(win, NULL);
lv_obj_set_size(val, LV_HOR_RES / 11 * 3, LV_VER_RES - (LV_DPI * 11 / 6));
lv_obj_t * lb_val = lv_label_create(val, lb_desc);
lv_label_set_style(lb_val, &monospace_text);
lv_label_set_text(lb_val, "Please wait...");
lv_obj_set_width(lb_val, lv_obj_get_width(val));
lv_obj_align(val, desc, LV_ALIGN_OUT_RIGHT_MID, 0, 0);
manual_system_maintenance(true);
tsec_ctxt.fw = (u8 *)pkg1 + pkg1_id->tsec_off;
tsec_ctxt.pkg1 = pkg1;
tsec_ctxt.pkg11_off = pkg1_id->pkg11_off;
tsec_ctxt.secmon_base = pkg1_id->secmon_base;
if (pkg1_id->kb <= KB_FIRMWARE_VERSION_600)
tsec_ctxt.size = 0xF00;
else if (pkg1_id->kb == KB_FIRMWARE_VERSION_620)
tsec_ctxt.size = 0x2900;
else if (pkg1_id->kb == KB_FIRMWARE_VERSION_700)
{
tsec_ctxt.size = 0x3000;
// Exit after TSEC key generation.
*((vu16 *)((u32)tsec_ctxt.fw + 0x2DB5)) = 0x02F8;
}
else
tsec_ctxt.size = 0x3300;
if (pkg1_id->kb == KB_FIRMWARE_VERSION_620)
{
u8 *tsec_paged = (u8 *)page_alloc(3);
memcpy(tsec_paged, (void *)tsec_ctxt.fw, tsec_ctxt.size);
tsec_ctxt.fw = tsec_paged;
}
int res = 0;
while (tsec_query((u8 *)tsec_keys, pkg1_id->kb, &tsec_ctxt) < 0)
{
memset(tsec_keys, 0x00, 0x20);
retries++;
if (retries > 3)
{
res = -1;
break;
}
}
strcat(txt_buf, "#C7EA46 TSEC Key:#\n");
if (res >= 0)
{
s_printf(txt_buf2, "\n%08X%08X%08X%08X\n",
byte_swap_32(tsec_keys[0]), byte_swap_32(tsec_keys[1]), byte_swap_32(tsec_keys[2]), byte_swap_32(tsec_keys[3]));
if (pkg1_id->kb == KB_FIRMWARE_VERSION_620)
{
strcat(txt_buf, "#C7EA46 TSEC root:#\n");
s_printf(txt_buf2 + strlen(txt_buf2), "%08X%08X%08X%08X\n",
byte_swap_32(tsec_keys[4]), byte_swap_32(tsec_keys[5]), byte_swap_32(tsec_keys[6]), byte_swap_32(tsec_keys[7]));
}
lv_win_add_btn(win, NULL, SYMBOL_DOWNLOAD" Dump Keys", _tsec_keys_dump_window_action);
}
else
{
s_printf(txt_buf2, "Error: %x", res);
}
lv_label_set_text(lb_desc, txt_buf);
lv_label_set_text(lb_val, txt_buf2);
out:
free(pkg1);
free(txt_buf);
free(txt_buf2);
nyx_window_toggle_buttons(win, false);
return LV_RES_OK;
}
static lv_res_t _create_mbox_benchmark(bool sd_bench)
{
sdmmc_t emmc_sdmmc;
sdmmc_storage_t emmc_storage;
sdmmc_storage_t *storage;
lv_obj_t *dark_bg = lv_obj_create(lv_scr_act(), NULL);
lv_obj_set_style(dark_bg, &mbox_darken);
lv_obj_set_size(dark_bg, LV_HOR_RES, LV_VER_RES);
static const char * mbox_btn_map[] = { "\211", "\222OK", "\211", "" };
lv_obj_t * mbox = lv_mbox_create(dark_bg, NULL);
lv_mbox_set_recolor_text(mbox, true);
lv_obj_set_width(mbox, LV_HOR_RES / 7 * 5);
char *txt_buf = (char *)malloc(0x1000);
s_printf(txt_buf, "#FF8000 %s Benchmark#\n[3 x %s raw reads] Abort: VOL- & VOL+\n",
sd_bench ? "SD Card" : "eMMC", sd_bench ? "2GB" : "8GB");
lv_mbox_set_text(mbox, txt_buf);
lv_obj_t * bar = lv_bar_create(mbox, NULL);
lv_obj_set_size(bar, LV_DPI * 2, LV_DPI / 5);
lv_bar_set_range(bar, 0, 100);
lv_bar_set_value(bar, 0);
lv_obj_align(mbox, NULL, LV_ALIGN_CENTER, 0, 0);
lv_obj_set_top(mbox, true);
manual_system_maintenance(true);
int res = 0;
if (sd_bench)
{
storage = &sd_storage;
res = !sd_mount();
}
else
{
storage = &emmc_storage;
res = !sdmmc_storage_init_mmc(&emmc_storage, &emmc_sdmmc, SDMMC_BUS_WIDTH_8, SDHCI_TIMING_MMC_HS400);
if (!res)
sdmmc_storage_set_mmc_partition(&emmc_storage, EMMC_GPP);
}
if (res)
lv_mbox_set_text(mbox, "#FFDD00 Failed to init Storage!#");
else
{
u32 iters = 3;
u32 sector_num = 0x8000;
u32 data_scts = sd_bench ? 0x400000 : 0x1000000; // SD 2GB or eMMC 8GB.
u32 offset_chunk_start = ALIGN_DOWN(storage->sec_cnt / 3, sector_num);
if (storage->sec_cnt < 0xC00000)
iters -= 2; // 4GB card.
for (u32 iter_curr = 0; iter_curr < iters; iter_curr++)
{
u32 pct = 0;
u32 prevPct = 200;
u32 lba_curr = 0;
u32 sector = offset_chunk_start * iter_curr;
u32 data_remaining = data_scts;
u32 timer = get_tmr_ms();
strcat(txt_buf, "\n");
lv_mbox_set_text(mbox, txt_buf);
while (data_remaining)
{
// Read 16MB chunks.
sdmmc_storage_read(storage, sector + lba_curr, sector_num, (u8 *)MIXD_BUF_ALIGNED);
manual_system_maintenance(false);
data_remaining -= sector_num;
lba_curr += sector_num;
pct = (lba_curr * 100) / data_scts;
if (pct != prevPct)
{
lv_bar_set_value(bar, pct);
manual_system_maintenance(true);
prevPct = pct;
if (btn_read_vol() == (BTN_VOL_UP | BTN_VOL_DOWN))
break;
}
}
timer = get_tmr_ms() - timer;
timer -= sd_bench ? 175 : 185; // Compensate 175ms/185ms for maintenance/drawing/calc ops.
lv_bar_set_value(bar, 100);
u32 rate_1k = (sd_bench ? (2048 * 1000 * 1000) : (u64)((u64)8192 * 1000 * 1000)) / timer;
s_printf(txt_buf + strlen(txt_buf),
"#C7EA46 %d#: Offset: #C7EA46 %08X#, Time: #C7EA46 %d.%02ds#, Rate: #C7EA46 %d.%02d MB/s#",
iter_curr, sector, timer / 1000, (timer % 1000) / 10, rate_1k / 1000, (rate_1k % 1000) / 10);
lv_mbox_set_text(mbox, txt_buf);
lv_obj_align(mbox, NULL, LV_ALIGN_CENTER, 0, 0);
manual_system_maintenance(true);
}
lv_obj_del(bar);
if (sd_bench)
sd_unmount();
else
sdmmc_storage_end(&emmc_storage);
}
lv_mbox_add_btns(mbox, mbox_btn_map, mbox_action); // Important. After set_text.
return LV_RES_OK;
}
static lv_res_t _create_mbox_emmc_bench(lv_obj_t * btn)
{
_create_mbox_benchmark(false);
return LV_RES_OK;
}
static lv_res_t _create_mbox_sd_bench(lv_obj_t * btn)
{
_create_mbox_benchmark(true);
return LV_RES_OK;
}
static lv_res_t _create_window_emmc_info_status(lv_obj_t *btn)
{
lv_obj_t *win = nyx_create_standard_window(SYMBOL_CHIP" Internal eMMC Info");
lv_win_add_btn(win, NULL, SYMBOL_CHIP" Benchmark", _create_mbox_emmc_bench);
lv_obj_t *desc = lv_cont_create(win, NULL);
lv_obj_set_size(desc, LV_HOR_RES / 2 / 6 * 2, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_desc = lv_label_create(desc, NULL);
lv_label_set_long_mode(lb_desc, LV_LABEL_LONG_BREAK);
lv_label_set_recolor(lb_desc, true);
sdmmc_storage_t storage;
sdmmc_t sdmmc;
char *txt_buf = (char *)malloc(0x4000);
txt_buf[0] = '\n';
txt_buf[1] = 0;
if (!sdmmc_storage_init_mmc(&storage, &sdmmc, SDMMC_BUS_WIDTH_8, SDHCI_TIMING_MMC_HS400))
{
lv_label_set_text(lb_desc, "#FFDD00 Failed to init eMMC!#");
lv_obj_set_width(lb_desc, lv_obj_get_width(desc));
}
else
{
u32 speed = 0;
char *rsvd_blocks;
char life_a_txt[8];
char life_b_txt[8];
u32 life_a = storage.ext_csd.dev_life_est_a;
u32 life_b = storage.ext_csd.dev_life_est_b;
u16 card_type = storage.ext_csd.card_type;
char card_type_support[96];
card_type_support[0] = 0;
// Identify manufacturer. Only official eMMCs.
switch (storage.cid.manfid)
{
case 0x11:
strcat(txt_buf, "Toshiba ");
break;
case 0x15:
strcat(txt_buf, "Samsung ");
break;
case 0x90:
strcat(txt_buf, "SK Hynix ");
break;
}
s_printf(txt_buf + strlen(txt_buf), "(%02X)\n%X\n%02X\n%c%c%c%c%c%c\n%X\n%04X\n%02d/%04d\n\n",
storage.cid.manfid, storage.cid.card_bga, storage.cid.oemid,
storage.cid.prod_name[0], storage.cid.prod_name[1], storage.cid.prod_name[2],
storage.cid.prod_name[3], storage.cid.prod_name[4], storage.cid.prod_name[5],
storage.cid.prv, storage.cid.serial, storage.cid.month, storage.cid.year);
if (card_type & EXT_CSD_CARD_TYPE_HS_26)
{
strcat(card_type_support, "HS26");
speed = (26 << 16) | 26;
}
if (card_type & EXT_CSD_CARD_TYPE_HS_52)
{
strcat(card_type_support, ", HS52");
speed = (52 << 16) | 52;
}
if (card_type & EXT_CSD_CARD_TYPE_DDR_1_8V)
{
strcat(card_type_support, ", DDR52 1.8V");
speed = (52 << 16) | 104;
}
if (card_type & EXT_CSD_CARD_TYPE_HS200_1_8V)
{
strcat(card_type_support, ", HS200 1.8V");
speed = (200 << 16) | 200;
}
if (card_type & EXT_CSD_CARD_TYPE_HS400_1_8V)
{
strcat(card_type_support, ", HS400 1.8V");
speed = (200 << 16) | 400;
}
strcpy(life_a_txt, "-");
strcpy(life_b_txt, "-");
// Normalize cells life.
if (life_a)
{
life_a--;
life_a = (10 - life_a) * 10;
s_printf(life_a_txt, "%d%%", life_a);
}
if (life_b) // Toshiba is 0 (undefined).
{
life_b--;
life_b = (10 - life_b) * 10;
s_printf(life_b_txt, "%d%%", life_b);
}
switch (storage.ext_csd.pre_eol_info)
{
case 1:
rsvd_blocks = "Normal (< 80%)";
break;
case 2:
rsvd_blocks = "Warning (> 80%)";
break;
case 3:
rsvd_blocks = "Urgent (> 90%)";
break;
default:
rsvd_blocks = "#FF8000 Unknown#";
break;
}
s_printf(txt_buf + strlen(txt_buf),
"#00DDFF V1.%d (rev 1.%d)#\n%02X\n%d MB/s (%d MHz)\n%d MB/s\n%s\nA: %s, B: %s\n%s",
storage.ext_csd.ext_struct, storage.ext_csd.rev,
storage.csd.cmdclass, speed & 0xFFFF, (speed >> 16) & 0xFFFF,
storage.csd.busspeed, card_type_support, life_a_txt, life_b_txt, rsvd_blocks);
lv_label_set_static_text(lb_desc,
"#00DDFF CID:#\n"
"Vendor ID:\n"
"Card/BGA:\n"
"OEM ID:\n"
"Model:\n"
"Prd Rev:\n"
"S/N:\n"
"Month/Year:\n\n"
"#00DDFF Ext CSD#\n"
"Cmd Classes:\n"
"Max Rate:\n"
"Current Rate:\n"
"Type Support:\n\n"
"Estimated Life:\n"
"Reserved Used:"
);
lv_obj_set_width(lb_desc, lv_obj_get_width(desc));
lv_obj_t *val = lv_cont_create(win, NULL);
lv_obj_set_size(val, LV_HOR_RES / 11 * 3, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_val = lv_label_create(val, lb_desc);
lv_label_set_text(lb_val, txt_buf);
lv_obj_set_width(lb_val, lv_obj_get_width(val));
lv_obj_align(val, desc, LV_ALIGN_OUT_RIGHT_MID, 0, 0);
lv_obj_t *desc2 = lv_cont_create(win, NULL);
lv_obj_set_size(desc2, LV_HOR_RES / 2 / 4 * 4, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_desc2 = lv_label_create(desc2, lb_desc);
lv_label_set_style(lb_desc2, &monospace_text);
u32 boot_size = storage.ext_csd.boot_mult << 17;
u32 rpmb_size = storage.ext_csd.rpmb_mult << 17;
s_printf(txt_buf, "#00DDFF eMMC Physical Partitions:#\n");
s_printf(txt_buf + strlen(txt_buf), "1: #96FF00 BOOT0# Size: %5d KiB (Sect: 0x%08X)\n", boot_size / 1024, boot_size / 512);
s_printf(txt_buf + strlen(txt_buf), "2: #96FF00 BOOT1# Size: %5d KiB (Sect: 0x%08X)\n", boot_size / 1024, boot_size / 512);
s_printf(txt_buf + strlen(txt_buf), "3: #96FF00 RPMB# Size: %5d KiB (Sect: 0x%08X)\n", rpmb_size / 1024, rpmb_size / 512);
s_printf(txt_buf + strlen(txt_buf), "0: #96FF00 GPP# Size: %5d MiB (Sect: 0x%08X)\n\n", storage.sec_cnt >> SECTORS_TO_MIB_COEFF, storage.sec_cnt);
s_printf(txt_buf + strlen(txt_buf), "#00DDFF GPP (eMMC USER) Partition Table:#\n");
sdmmc_storage_set_mmc_partition(&storage, EMMC_GPP);
LIST_INIT(gpt);
nx_emmc_gpt_parse(&gpt, &storage);
u32 idx = 0;
LIST_FOREACH_ENTRY(emmc_part_t, part, &gpt, link)
{
if (idx > 10)
{
strcat(txt_buf, "#FFDD00 Table truncated!#");
break;
}
if (part->index < 2)
{
s_printf(txt_buf + strlen(txt_buf), "%02d: #96FF00 %s# ", part->index, part->name);
s_printf(txt_buf + strlen(txt_buf), " Size: %d MiB (Sect: 0x%X), Start: %06X\n",
(part->lba_end - part->lba_start + 1) >> SECTORS_TO_MIB_COEFF,
part->lba_end - part->lba_start + 1, part->lba_start);
}
else
{
s_printf(txt_buf + strlen(txt_buf), "%02d: #96FF00 %s#\n Size: %7d MiB (Sect: 0x%07X), Start: %07X\n",
part->index, part->name, (part->lba_end - part->lba_start + 1) >> SECTORS_TO_MIB_COEFF,
part->lba_end - part->lba_start + 1, part->lba_start);
}
idx++;
}
nx_emmc_gpt_free(&gpt);
lv_label_set_text(lb_desc2, txt_buf);
lv_obj_set_width(lb_desc2, lv_obj_get_width(desc2));
lv_obj_align(desc2, val, LV_ALIGN_OUT_RIGHT_MID, LV_DPI / 6, 0);
}
sdmmc_storage_end(&storage);
free(txt_buf);
return LV_RES_OK;
}
static lv_res_t _create_window_sdcard_info_status(lv_obj_t *btn)
{
lv_obj_t *win = nyx_create_standard_window(SYMBOL_SD" microSD Card Info");
lv_win_add_btn(win, NULL, SYMBOL_SD" Benchmark", _create_mbox_sd_bench);
lv_obj_t *desc = lv_cont_create(win, NULL);
lv_obj_set_size(desc, LV_HOR_RES / 2 / 5 * 2, LV_VER_RES - (LV_DPI * 11 / 8) * 5 / 2);
lv_obj_t * lb_desc = lv_label_create(desc, NULL);
lv_label_set_long_mode(lb_desc, LV_LABEL_LONG_BREAK);
lv_label_set_recolor(lb_desc, true);
lv_label_set_text(lb_desc, "#D4FF00 Please wait...#");
lv_obj_set_width(lb_desc, lv_obj_get_width(desc));
// Disable buttons.
nyx_window_toggle_buttons(win, true);
manual_system_maintenance(true);
if (!sd_mount())
lv_label_set_text(lb_desc, "#FFDD00 Failed to init SD!#");
else
{
lv_label_set_text(lb_desc,
"#00DDFF Card IDentification:#\n"
"Vendor ID:\n"
"OEM ID:\n"
"Model:\n"
"HW rev:\n"
"FW rev:\n"
"S/N:\n"
"Month/Year:\n\n"
"Bootloader bus:"
);
lv_obj_t *val = lv_cont_create(win, NULL);
lv_obj_set_size(val, LV_HOR_RES / 9 * 2, LV_VER_RES - (LV_DPI * 11 / 8) * 5 / 2);
lv_obj_t * lb_val = lv_label_create(val, lb_desc);
char *txt_buf = (char *)malloc(0x4000);
txt_buf[0] = '\n';
txt_buf[1] = 0;
// Identify manufacturer.
switch (sd_storage.cid.manfid)
{
case 1:
strcat(txt_buf, "Panasonic ");
break;
case 2:
strcat(txt_buf, "Toshiba ");
break;
case 3:
strcat(txt_buf, "SanDisk ");
break;
case 0x1B:
strcat(txt_buf, "Samsung ");
break;
case 0x1D:
strcat(txt_buf, "AData ");
break;
case 0x27:
strcat(txt_buf, "Phison ");
break;
case 0x28:
strcat(txt_buf, "Lexar ");
break;
case 0x31:
strcat(txt_buf, "Silicon Power ");
break;
case 0x41:
strcat(txt_buf, "Kingston ");
break;
case 0x74:
strcat(txt_buf, "Transcend ");
break;
case 0x76:
strcat(txt_buf, "Patriot ");
break;
case 0x82:
strcat(txt_buf, "Sony ");
break;
}
s_printf(txt_buf + strlen(txt_buf), "(%02X)\n%c%c\n%c%c%c%c%c\n%X\n%X\n%08x\n%02d/%04d\n\n",
sd_storage.cid.manfid, (sd_storage.cid.oemid >> 8) & 0xFF, sd_storage.cid.oemid & 0xFF,
sd_storage.cid.prod_name[0], sd_storage.cid.prod_name[1], sd_storage.cid.prod_name[2],
sd_storage.cid.prod_name[3], sd_storage.cid.prod_name[4],
sd_storage.cid.hwrev, sd_storage.cid.fwrev, sd_storage.cid.serial,
sd_storage.cid.month, sd_storage.cid.year);
switch (nyx_str->info.sd_init)
{
case SD_1BIT_HS25:
strcat(txt_buf, "HS25 1bit");
break;
case SD_4BIT_HS25:
strcat(txt_buf, "HS25");
break;
case SD_UHS_SDR82: // Report as SDR104.
case SD_UHS_SDR104:
strcat(txt_buf, "SDR104");
break;
case 0:
default:
strcat(txt_buf, "Undefined");
break;
}
lv_label_set_text(lb_val, txt_buf);
lv_obj_set_width(lb_val, lv_obj_get_width(val));
lv_obj_align(val, desc, LV_ALIGN_OUT_RIGHT_MID, 0, 0);
lv_obj_t *desc2 = lv_cont_create(win, NULL);
lv_obj_set_size(desc2, LV_HOR_RES / 2 / 4 * 2, LV_VER_RES - (LV_DPI * 11 / 8) * 5 / 2);
lv_obj_t * lb_desc2 = lv_label_create(desc2, lb_desc);
lv_label_set_static_text(lb_desc2,
"#00DDFF Card-Specific Data#\n"
"Cmd Classes:\n"
"Capacity:\n"
"Capacity (LBA):\n"
"Bus Width:\n"
"Current Rate:\n"
"Speed Class:\n"
"UHS Grade:\n"
"Video Class:\n"
"App perf class:\n"
"Write Protect:"
);
lv_obj_set_width(lb_desc2, lv_obj_get_width(desc2));
lv_obj_align(desc2, val, LV_ALIGN_OUT_RIGHT_MID, LV_DPI / 2, 0);
lv_obj_t *val2 = lv_cont_create(win, NULL);
lv_obj_set_size(val2, LV_HOR_RES / 13 * 3, LV_VER_RES - (LV_DPI * 11 / 8) * 5 / 2);
lv_obj_t * lb_val2 = lv_label_create(val2, lb_desc);
char *wp_info;
switch (sd_storage.csd.write_protect)
{
case 1:
wp_info = "Temporary";
break;
case 2:
case 3:
wp_info = "Permanent";
break;
default:
wp_info = "None";
break;
}
bool uhs_au_mb = false;
u32 uhs_au_size = sd_storage_ssr_get_au(&sd_storage);
if (uhs_au_size >= 1024)
{
uhs_au_mb = true;
uhs_au_size /= 1024;
}
s_printf(txt_buf,
"#00DDFF v%d.0#\n%02X\n%d MiB\n%X (CP %X)\n%d\n%d MB/s (%d MHz)\n%d (AU: %d %s\nU%d\nV%d\nA%d\n%s",
sd_storage.csd.structure + 1, sd_storage.csd.cmdclass,
sd_storage.sec_cnt >> 11, sd_storage.sec_cnt, sd_storage.ssr.protected_size >> 9,
sd_storage.ssr.bus_width, sd_storage.csd.busspeed,
(sd_storage.csd.busspeed > 10) ? (sd_storage.csd.busspeed * 2) : 50,
sd_storage.ssr.speed_class, uhs_au_size, uhs_au_mb ? "MiB)" : "KiB)", sd_storage.ssr.uhs_grade,
sd_storage.ssr.video_class, sd_storage.ssr.app_class, wp_info);
lv_label_set_text(lb_val2, txt_buf);
lv_obj_set_width(lb_val2, lv_obj_get_width(val2));
lv_obj_align(val2, desc2, LV_ALIGN_OUT_RIGHT_MID, 0, 0);
lv_obj_t *line_sep = lv_line_create(win, NULL);
static const lv_point_t line_pp[] = { {0, 0}, { LV_HOR_RES - (LV_DPI - (LV_DPI / 4)) * 12, 0} };
lv_line_set_points(line_sep, line_pp, 2);
lv_line_set_style(line_sep, lv_theme_get_current()->line.decor);
lv_obj_align(line_sep, desc, LV_ALIGN_OUT_BOTTOM_LEFT, LV_DPI * 410 / 100, LV_DPI / 7);
lv_obj_t *desc3 = lv_cont_create(win, NULL);
lv_obj_set_size(desc3, LV_HOR_RES / 2 / 2 * 2, LV_VER_RES - (LV_DPI * 11 / 8) * 4);
lv_obj_t * lb_desc3 = lv_label_create(desc3, lb_desc);
lv_label_set_text(lb_desc3, "#D4FF00 Acquiring FAT volume info...#");
lv_obj_set_width(lb_desc3, lv_obj_get_width(desc3));
lv_obj_align(desc3, desc, LV_ALIGN_OUT_BOTTOM_LEFT, 0, LV_DPI / 2);
manual_system_maintenance(true);
f_getfree("", &sd_fs.free_clst, NULL);
lv_label_set_text(lb_desc3,
"#00DDFF Found FAT volume:#\n"
"Filesystem:\n"
"Cluster:\n"
"Free:"
);
lv_obj_set_size(desc3, LV_HOR_RES / 2 / 5 * 2, LV_VER_RES - (LV_DPI * 11 / 8) * 4);
lv_obj_set_width(lb_desc3, lv_obj_get_width(desc3));
lv_obj_align(desc3, desc, LV_ALIGN_OUT_BOTTOM_LEFT, 0, LV_DPI / 2);
lv_obj_t *val3 = lv_cont_create(win, NULL);
lv_obj_set_size(val3, LV_HOR_RES / 13 * 3, LV_VER_RES - (LV_DPI * 11 / 8) * 4);
lv_obj_t * lb_val3 = lv_label_create(val3, lb_desc);
s_printf(txt_buf, "\n%s\n%d %s\n%d MiB",
sd_fs.fs_type == FS_EXFAT ? ("exFAT "SYMBOL_SHRK) : ("FAT32"),
(sd_fs.csize > 1) ? (sd_fs.csize >> 1) : 512,
(sd_fs.csize > 1) ? "KiB" : "B",
sd_fs.free_clst * sd_fs.csize >> SECTORS_TO_MIB_COEFF);
lv_label_set_text(lb_val3, txt_buf);
lv_obj_set_width(lb_val3, lv_obj_get_width(val3));
lv_obj_align(val3, desc3, LV_ALIGN_OUT_RIGHT_MID, 0, 0);
lv_obj_t *desc4 = lv_cont_create(win, NULL);
lv_obj_set_size(desc4, LV_HOR_RES / 2 / 2 * 2, LV_VER_RES - (LV_DPI * 11 / 8) * 4);
lv_obj_t * lb_desc4 = lv_label_create(desc4, lb_desc);
lv_label_set_text(lb_desc4, "#D4FF00 Acquiring FAT volume info...#");
lv_obj_set_width(lb_desc4, lv_obj_get_width(desc4));
lv_label_set_text(lb_desc4,
"#00DDFF SDMMC1 Errors:#\n"
"Init fails:\n"
"Read/Write fails:\n"
"Read/Write errors:"
);
lv_obj_set_size(desc4, LV_HOR_RES / 2 / 5 * 2, LV_VER_RES - (LV_DPI * 11 / 8) * 4);
lv_obj_set_width(lb_desc4, lv_obj_get_width(desc4));
lv_obj_align(desc4, val3, LV_ALIGN_OUT_RIGHT_MID, LV_DPI / 2, 0);
lv_obj_t *val4 = lv_cont_create(win, NULL);
lv_obj_set_size(val4, LV_HOR_RES / 13 * 3, LV_VER_RES - (LV_DPI * 11 / 8) * 4);
lv_obj_t * lb_val4 = lv_label_create(val4, lb_desc);
u16 *sd_errors = sd_get_error_count();
s_printf(txt_buf, "\n%d (%d)\n%d (%d)\n%d (%d)",
sd_errors[0], nyx_str->info.sd_errors[0], sd_errors[1], nyx_str->info.sd_errors[1], sd_errors[2], nyx_str->info.sd_errors[2]);
lv_label_set_text(lb_val4, txt_buf);
lv_obj_set_width(lb_val4, lv_obj_get_width(val4));
lv_obj_align(val4, desc4, LV_ALIGN_OUT_RIGHT_MID, LV_DPI / 2, 0);
free(txt_buf);
sd_unmount();
}
nyx_window_toggle_buttons(win, false);
return LV_RES_OK;
}
static lv_res_t _create_window_battery_status(lv_obj_t *btn)
{
lv_obj_t *win = nyx_create_standard_window(SYMBOL_BATTERY_FULL" Battery Info");
lv_win_add_btn(win, NULL, SYMBOL_DOWNLOAD" Dump Fuel Regs", _battery_dump_window_action);
lv_obj_t *desc = lv_cont_create(win, NULL);
lv_obj_set_size(desc, LV_HOR_RES / 2 / 4 * 2, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_desc = lv_label_create(desc, NULL);
lv_label_set_long_mode(lb_desc, LV_LABEL_LONG_BREAK);
lv_label_set_recolor(lb_desc, true);
lv_label_set_static_text(lb_desc,
"#00DDFF Fuel Gauge IC Info:#\n"
"Capacity now:\n"
"Capacity full:\n"
"Capacity (design):\n"
"Current now:\n"
"Current average:\n"
"Voltage now:\n"
"Voltage open-circuit:\n"
"Min voltage reached:\n"
"Max voltage reached:\n"
"Empty voltage:\n"
"Battery temp:\n\n"
"#00DDFF PMIC IC Info:#\n"
"Main PMIC:\n\n"
"CPU/GPU PMIC:\n"
);
lv_obj_set_width(lb_desc, lv_obj_get_width(desc));
lv_obj_t *val = lv_cont_create(win, NULL);
lv_obj_set_size(val, LV_HOR_RES / 5, LV_VER_RES - (LV_DPI * 11 / 7));
lv_obj_t * lb_val = lv_label_create(val, lb_desc);
char *txt_buf = (char *)malloc(0x4000);
int value = 0;
int cap_pct = 0;
max17050_get_property(MAX17050_RepSOC, &cap_pct);
max17050_get_property(MAX17050_RepCap, &value);
s_printf(txt_buf, "\n%d mAh [%d %]\n", value, cap_pct >> 8);
max17050_get_property(MAX17050_FullCAP, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mAh\n", value);
max17050_get_property(MAX17050_DesignCap, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mAh\n", value);
max17050_get_property(MAX17050_Current, &value);
if (value >= 0)
s_printf(txt_buf + strlen(txt_buf), "%d mA\n", value / 1000);
else
s_printf(txt_buf + strlen(txt_buf), "-%d mA\n", (~value + 1) / 1000);
max17050_get_property(MAX17050_AvgCurrent, &value);
if (value >= 0)
s_printf(txt_buf + strlen(txt_buf), "%d mA\n", value / 1000);
else
s_printf(txt_buf + strlen(txt_buf), "-%d mA\n", (~value + 1) / 1000);
max17050_get_property(MAX17050_VCELL, &value);
bool voltage_empty = value < 3200;
s_printf(txt_buf + strlen(txt_buf), "%s%d mV%s\n",
voltage_empty ? "#FF8000 " : "", value, voltage_empty ? " "SYMBOL_WARNING"#" : "");
max17050_get_property(MAX17050_OCVInternal, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mV\n", value);
max17050_get_property(MAX17050_MinVolt, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mV\n", value);
max17050_get_property(MAX17050_MaxVolt, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mV\n", value);
max17050_get_property(MAX17050_V_empty, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mV\n", value);
max17050_get_property(MAX17050_TEMP, &value);
if (value >= 0)
s_printf(txt_buf + strlen(txt_buf), "%d.%d oC\n\n\n", value / 10, value % 10);
else
s_printf(txt_buf + strlen(txt_buf), "-%d.%d oC\n\n\n", (~value + 1) / 10, (~value + 1) % 10);
value = i2c_recv_byte(I2C_5, MAX77620_I2C_ADDR, MAX77620_REG_CID4);
u32 main_pmic_version = i2c_recv_byte(I2C_5, MAX77620_I2C_ADDR, MAX77620_REG_CID3) & 0xF;
if (value == 0x35)
s_printf(txt_buf + strlen(txt_buf), "max77620 v%d\nErista OTP\n", main_pmic_version);
else if (value == 0x53)
s_printf(txt_buf + strlen(txt_buf), "max77620 v%d\nMariko OTP\n", main_pmic_version);
else
s_printf(txt_buf + strlen(txt_buf), "max77620 v%d\n#FF8000 Unknown OTP# (%02X)\n", main_pmic_version, value);
u32 cpu_gpu_pmic_type = h_cfg.t210b01 ? (FUSE(FUSE_RESERVED_ODM28_T210B01) & 1) + 1 : 0;
switch (cpu_gpu_pmic_type)
{
case 0:
s_printf(txt_buf + strlen(txt_buf), "max77621 v%d",
i2c_recv_byte(I2C_5, MAX77621_CPU_I2C_ADDR, MAX77621_CHIPID1_REG));
break;
case 1:
s_printf(txt_buf + strlen(txt_buf), "max77812-2 v%d",
i2c_recv_byte(I2C_5, MAX77812_PHASE31_CPU_I2C_ADDR, MAX77812_REG_VERSION) & 7);
break;
case 2:
s_printf(txt_buf + strlen(txt_buf), "max77812-3 v%d.0",
i2c_recv_byte(I2C_5, MAX77812_PHASE211_CPU_I2C_ADDR, MAX77812_REG_VERSION) & 7);
break;
}
lv_label_set_text(lb_val, txt_buf);
lv_obj_set_width(lb_val, lv_obj_get_width(val));
lv_obj_align(val, desc, LV_ALIGN_OUT_RIGHT_MID, 0, 0);
lv_obj_t *desc2 = lv_cont_create(win, NULL);
lv_obj_set_size(desc2, LV_HOR_RES / 2 / 7 * 4, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_desc2 = lv_label_create(desc2, lb_desc);
lv_label_set_static_text(lb_desc2,
"#00DDFF Battery Charger IC Info:#\n"
"Input voltage limit:\n"
"Input current limit:\n"
"Min voltage limit:\n"
"Fast charge current limit:\n"
"Charge voltage limit:\n"
"Charge status:\n"
"Temperature status:\n\n"
"#00DDFF USB-PD IC Info:#\n"
"Connection status:\n"
"Input Wattage Limit:\n"
"USB-PD Profiles:"
);
lv_obj_set_width(lb_desc2, lv_obj_get_width(desc2));
lv_obj_align(desc2, val, LV_ALIGN_OUT_RIGHT_MID, LV_DPI / 2, 0);
lv_obj_t *val2 = lv_cont_create(win, NULL);
lv_obj_set_size(val2, LV_HOR_RES / 2 / 3, LV_VER_RES - (LV_DPI * 11 / 7) - 5);
lv_obj_t * lb_val2 = lv_label_create(val2, lb_desc);
bq24193_get_property(BQ24193_InputVoltageLimit, &value);
s_printf(txt_buf, "\n%d mV\n", value);
int iinlim = 0;
bq24193_get_property(BQ24193_InputCurrentLimit, &iinlim);
s_printf(txt_buf + strlen(txt_buf), "%d mA\n", iinlim);
bq24193_get_property(BQ24193_SystemMinimumVoltage, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mV\n", value);
bq24193_get_property(BQ24193_FastChargeCurrentLimit, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mA\n", value);
bq24193_get_property(BQ24193_ChargeVoltageLimit, &value);
s_printf(txt_buf + strlen(txt_buf), "%d mV\n", value);
bq24193_get_property(BQ24193_ChargeStatus, &value);
switch (value)
{
case 0:
strcat(txt_buf, "Not charging\n");
break;
case 1:
strcat(txt_buf, "Pre-charging\n");
break;
case 2:
strcat(txt_buf, "Fast charging\n");
break;
case 3:
strcat(txt_buf, "Charge terminated\n");
break;
default:
s_printf(txt_buf + strlen(txt_buf), "Unknown (%d)\n", value);
break;
}
bq24193_get_property(BQ24193_TempStatus, &value);
switch (value)
{
case 0:
strcat(txt_buf, "Normal");
break;
case 2:
strcat(txt_buf, "Warm");
break;
case 3:
strcat(txt_buf, "Cool");
break;
case 5:
strcat(txt_buf, "Cold");
break;
case 6:
strcat(txt_buf, "Hot");
break;
default:
s_printf(txt_buf + strlen(txt_buf), "Unknown (%d)", value);
break;
}
bool inserted;
u32 wattage = 0;
usb_pd_objects_t usb_pd;
bm92t36_get_sink_info(&inserted, &usb_pd);
strcat(txt_buf, "\n\n\n");
strcat(txt_buf, inserted ? "Connected" : "Disconnected");
// Select 5V is no PD contract.
wattage = iinlim * (usb_pd.pdo_no ? usb_pd.selected_pdo.voltage : 5);
s_printf(txt_buf + strlen(txt_buf), "\n%d.%d W", wattage / 1000, (wattage % 1000) / 100);
if (!usb_pd.pdo_no)
strcat(txt_buf, "\nNon PD");
// Limit to 5 profiles so it can fit.
usb_pd.pdo_no = MIN(usb_pd.pdo_no, 5);
for (u32 i = 0; i < usb_pd.pdo_no; i++)
{
bool selected =
usb_pd.pdos[i].amperage == usb_pd.selected_pdo.amperage &&
usb_pd.pdos[i].voltage == usb_pd.selected_pdo.voltage;
s_printf(txt_buf + strlen(txt_buf), "\n%s%d mA, %2d V%s",
selected ? "#D4FF00 " : "",
usb_pd.pdos[i].amperage, usb_pd.pdos[i].voltage,
selected ? "#" : "");
}
lv_label_set_text(lb_val2, txt_buf);
lv_obj_set_width(lb_val2, lv_obj_get_width(val2));
lv_obj_align(val2, desc2, LV_ALIGN_OUT_RIGHT_MID, 0, 0);
free(txt_buf);
return LV_RES_OK;
}
void create_tab_info(lv_theme_t *th, lv_obj_t *parent)
{
lv_page_set_scrl_layout(parent, LV_LAYOUT_PRETTY);
static lv_style_t h_style;
lv_style_copy(&h_style, &lv_style_transp);
h_style.body.padding.inner = 0;
h_style.body.padding.hor = LV_DPI - (LV_DPI / 4);
h_style.body.padding.ver = LV_DPI / 6;
// Create SoC Info container.
lv_obj_t *h1 = lv_cont_create(parent, NULL);
lv_cont_set_style(h1, &h_style);
lv_cont_set_fit(h1, false, true);
lv_obj_set_width(h1, (LV_HOR_RES / 9) * 4);
lv_obj_set_click(h1, false);
lv_cont_set_layout(h1, LV_LAYOUT_OFF);
lv_obj_t *label_sep = lv_label_create(h1, NULL);
lv_label_set_static_text(label_sep, "");
lv_obj_t *label_txt = lv_label_create(h1, NULL);
lv_label_set_static_text(label_txt, "SoC & HW Info");
lv_obj_set_style(label_txt, th->label.prim);
lv_obj_align(label_txt, label_sep, LV_ALIGN_OUT_BOTTOM_LEFT, LV_DPI / 4, 0);
lv_obj_t *line_sep = lv_line_create(h1, NULL);
static const lv_point_t line_pp[] = { {0, 0}, { LV_HOR_RES - (LV_DPI - (LV_DPI / 4)) * 2, 0} };
lv_line_set_points(line_sep, line_pp, 2);
lv_line_set_style(line_sep, th->line.decor);
lv_obj_align(line_sep, label_txt, LV_ALIGN_OUT_BOTTOM_LEFT, -(LV_DPI / 4), LV_DPI / 8);
// Create Bootrom button.
lv_obj_t *btn = lv_btn_create(h1, NULL);
if (hekate_bg)
{
lv_btn_set_style(btn, LV_BTN_STYLE_REL, &btn_transp_rel);
lv_btn_set_style(btn, LV_BTN_STYLE_PR, &btn_transp_pr);
}
lv_obj_t *label_btn = lv_label_create(btn, NULL);
lv_btn_set_fit(btn, true, true);
lv_label_set_static_text(label_btn, SYMBOL_CHIP" Bootrom");
lv_obj_align(btn, line_sep, LV_ALIGN_OUT_BOTTOM_LEFT, LV_DPI / 4, LV_DPI / 4);
lv_btn_set_action(btn, LV_BTN_ACTION_CLICK, _create_window_bootrom_info_status);
// Create TSEC Keys button.
lv_obj_t *btn2 = lv_btn_create(h1, btn);
label_btn = lv_label_create(btn2, NULL);
lv_label_set_static_text(label_btn, SYMBOL_KEY" TSEC Keys");
lv_obj_align(btn2, btn, LV_ALIGN_OUT_RIGHT_TOP, LV_DPI * 4 / 9, 0);
lv_btn_set_action(btn2, LV_BTN_ACTION_CLICK, _create_window_tsec_keys_status);
if (h_cfg.t210b01)
lv_btn_set_state(btn2, LV_BTN_STATE_INA);
lv_obj_t *label_txt2 = lv_label_create(h1, NULL);
lv_label_set_recolor(label_txt2, true);
lv_label_set_static_text(label_txt2,
"View Ipatches and dump the unpatched and patched versions\nof BootROM.\n"
"Or view and dump the device's TSEC Keys.\n");
lv_obj_set_style(label_txt2, &hint_small_style);
lv_obj_align(label_txt2, btn, LV_ALIGN_OUT_BOTTOM_LEFT, 0, LV_DPI / 3);
static lv_style_t line_style;
lv_style_copy(&line_style, th->line.decor);
line_style.line.color = LV_COLOR_HEX(0x444444);
line_sep = lv_line_create(h1, line_sep);
lv_obj_align(line_sep, label_txt2, LV_ALIGN_OUT_BOTTOM_LEFT, -(LV_DPI / 4), LV_DPI / 16);
lv_line_set_style(line_sep, &line_style);
// Create Fuses button.
lv_obj_t *btn3 = lv_btn_create(h1, btn);
label_btn = lv_label_create(btn3, NULL);
lv_btn_set_fit(btn3, true, true);
lv_label_set_static_text(label_btn, SYMBOL_CIRCUIT" HW & Fuses");
lv_obj_align(btn3, line_sep, LV_ALIGN_OUT_BOTTOM_LEFT, LV_DPI / 4, LV_DPI / 2);
lv_btn_set_action(btn3, LV_BTN_ACTION_CLICK, _create_window_fuses_info_status);
// Create KFuses button.
lv_obj_t *btn4 = lv_btn_create(h1, btn);
label_btn = lv_label_create(btn4, NULL);
lv_label_set_static_text(label_btn, SYMBOL_SHUFFLE" KFuses");
lv_obj_align(btn4, btn3, LV_ALIGN_OUT_RIGHT_TOP, LV_DPI * 46 / 100, 0);
lv_btn_set_action(btn4, LV_BTN_ACTION_CLICK, _kfuse_dump_window_action);
lv_obj_t *label_txt4 = lv_label_create(h1, NULL);
lv_label_set_recolor(label_txt4, true);
lv_label_set_static_text(label_txt4,
"View and dump the cached #C7EA46 Fuses# and #C7EA46 KFuses#.\n"
"Fuses contain info about the SoC/SKU and KFuses HDCP keys.\n"
"You can also see info about #C7EA46 DRAM#, #C7EA46 Screen# and #C7EA46 Touch panel#.");
lv_obj_set_style(label_txt4, &hint_small_style);
lv_obj_align(label_txt4, btn3, LV_ALIGN_OUT_BOTTOM_LEFT, 0, LV_DPI / 3);
// Create Storage & Battery Info container.
lv_obj_t *h2 = lv_cont_create(parent, NULL);
lv_cont_set_style(h2, &h_style);
lv_cont_set_fit(h2, false, true);
lv_obj_set_width(h2, (LV_HOR_RES / 9) * 4);
lv_obj_set_click(h2, false);
lv_cont_set_layout(h2, LV_LAYOUT_OFF);
lv_obj_align(h2, h1, LV_ALIGN_OUT_RIGHT_TOP, 0, 0);
label_sep = lv_label_create(h2, NULL);
lv_label_set_static_text(label_sep, "");
lv_obj_t *label_txt3 = lv_label_create(h2, NULL);
lv_label_set_static_text(label_txt3, "Storage & Battery Info");
lv_obj_set_style(label_txt3, th->label.prim);
lv_obj_align(label_txt3, label_sep, LV_ALIGN_OUT_BOTTOM_LEFT, LV_DPI / 4, 0);
line_sep = lv_line_create(h2, line_sep);
lv_obj_align(line_sep, label_txt3, LV_ALIGN_OUT_BOTTOM_LEFT, -(LV_DPI / 2), LV_DPI / 8);
lv_line_set_style(line_sep, th->line.decor);
// Create eMMC button.
lv_obj_t *btn5 = lv_btn_create(h2, NULL);
if (hekate_bg)
{
lv_btn_set_style(btn5, LV_BTN_STYLE_REL, &btn_transp_rel);
lv_btn_set_style(btn5, LV_BTN_STYLE_PR, &btn_transp_pr);
}
label_btn = lv_label_create(btn5, NULL);
lv_btn_set_fit(btn5, true, true);
lv_label_set_static_text(label_btn, SYMBOL_CHIP" eMMC ");
lv_obj_align(btn5, line_sep, LV_ALIGN_OUT_BOTTOM_LEFT, LV_DPI / 2, LV_DPI / 4);
lv_btn_set_action(btn5, LV_BTN_ACTION_CLICK, _create_window_emmc_info_status);
// Create microSD button.
lv_obj_t *btn6 = lv_btn_create(h2, btn);
label_btn = lv_label_create(btn6, NULL);
lv_label_set_static_text(label_btn, SYMBOL_SD" microSD ");
lv_obj_align(btn6, btn5, LV_ALIGN_OUT_RIGHT_TOP, LV_DPI * 3 / 4, 0);
lv_btn_set_action(btn6, LV_BTN_ACTION_CLICK, _create_window_sdcard_info_status);
lv_obj_t *label_txt5 = lv_label_create(h2, NULL);
lv_label_set_recolor(label_txt5, true);
lv_label_set_static_text(label_txt5,
"View info about the eMMC or microSD and their partition list.\n"
"Additionally you can benchmark read speeds.");
lv_obj_set_style(label_txt5, &hint_small_style);
lv_obj_align(label_txt5, btn5, LV_ALIGN_OUT_BOTTOM_LEFT, 0, LV_DPI / 3);
line_sep = lv_line_create(h2, line_sep);
lv_obj_align(line_sep, label_txt5, LV_ALIGN_OUT_BOTTOM_LEFT, -(LV_DPI / 4), LV_DPI / 2);
lv_line_set_style(line_sep, &line_style);
// Create Battery button.
lv_obj_t *btn7 = lv_btn_create(h2, NULL);
if (hekate_bg)
{
lv_btn_set_style(btn7, LV_BTN_STYLE_REL, &btn_transp_rel);
lv_btn_set_style(btn7, LV_BTN_STYLE_PR, &btn_transp_pr);
}
label_btn = lv_label_create(btn7, NULL);
lv_btn_set_fit(btn7, true, true);
lv_label_set_static_text(label_btn, SYMBOL_BATTERY_FULL" Battery");
lv_obj_align(btn7, line_sep, LV_ALIGN_OUT_BOTTOM_LEFT, LV_DPI / 4, LV_DPI / 2);
lv_btn_set_action(btn7, LV_BTN_ACTION_CLICK, _create_window_battery_status);
lv_obj_t *label_txt6 = lv_label_create(h2, NULL);
lv_label_set_recolor(label_txt6, true);
lv_label_set_static_text(label_txt6,
"View battery and battery charger related info.\n"
"Additionally you can dump battery charger's registers.\n");
lv_obj_set_style(label_txt6, &hint_small_style);
lv_obj_align(label_txt6, btn7, LV_ALIGN_OUT_BOTTOM_LEFT, 0, LV_DPI / 3);
}