Atmosphere/exosphere/mariko_fatal/source/fatal_display.cpp

/*
 * Copyright (c) 2018-2020 Atmosphère-NX
 *
 * This program is free software; you can redistribute it and/or modify it
 * under the terms and conditions of the GNU General Public License,
 * version 2, as published by the Free Software Foundation.
 *
 * This program is distributed in the hope it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
 * more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
#include <exosphere.hpp>
#include "fatal_device_page_table.hpp"
#include "fatal_registers_di.hpp"

namespace ams::secmon::fatal {

    namespace {

        #include "fatal_display_config.inc"

    }

    namespace {

        /* Helpful defines. */
        constexpr size_t FrameBufferHeight = 768;
        constexpr size_t FrameBufferWidth  = 1280;
        constexpr size_t FrameBufferSize   = FrameBufferHeight * FrameBufferWidth * sizeof(u32);

        constexpr int DsiWaitForCommandMilliSecondsMax        = 250;
        constexpr int DsiWaitForCommandCompletionMilliSeconds = 5;
        constexpr int DsiWaitForHostControlMilliSecondsMax    = 150;

        constexpr inline int I2cAddressMax77620Pmic     = 0x3C;

        constexpr size_t GPIO_PORT3_CNF_0 = 0x200;
        constexpr size_t GPIO_PORT3_OE_0  = 0x210;
        constexpr size_t GPIO_PORT3_OUT_0 = 0x220;

        constexpr size_t GPIO_PORT6_CNF_1 = 0x504;
        constexpr size_t GPIO_PORT6_OE_1  = 0x514;
        constexpr size_t GPIO_PORT6_OUT_1 = 0x524;

        /* Globals. */
        constexpr inline const uintptr_t PMC             = secmon::MemoryRegionVirtualDevicePmc    .GetAddress();
        constexpr inline const uintptr_t g_disp1_regs    = secmon::MemoryRegionVirtualDeviceDisp1  .GetAddress();
        constexpr inline const uintptr_t g_dsi_regs      = secmon::MemoryRegionVirtualDeviceDsi    .GetAddress();
        constexpr inline const uintptr_t g_clk_rst_regs  = secmon::MemoryRegionVirtualDeviceClkRst .GetAddress();
        constexpr inline const uintptr_t g_gpio_regs     = secmon::MemoryRegionVirtualDeviceGpio   .GetAddress();
        constexpr inline const uintptr_t g_apb_misc_regs = secmon::MemoryRegionVirtualDeviceApbMisc.GetAddress();
        constexpr inline const uintptr_t g_mipi_cal_regs = secmon::MemoryRegionVirtualDeviceMipiCal.GetAddress();

        constinit u32 *g_frame_buffer = nullptr;

        inline void DoRegisterWrites(uintptr_t base_address, const RegisterWrite *reg_writes, size_t num_writes) {
            for (size_t i = 0; i < num_writes; i++) {
                reg::Write(base_address + reg_writes[i].offset, reg_writes[i].value);
            }
        }

        inline void DoSocDependentRegisterWrites(uintptr_t base_address, const RegisterWrite *reg_writes_erista, size_t num_writes_erista, const RegisterWrite *reg_writes_mariko, size_t num_writes_mariko) {
            switch (GetSocType()) {
                case fuse::SocType_Erista: DoRegisterWrites(base_address, reg_writes_erista, num_writes_erista); break;
                case fuse::SocType_Mariko: DoRegisterWrites(base_address, reg_writes_mariko, num_writes_mariko); break;
                AMS_UNREACHABLE_DEFAULT_CASE();
            }
        }

        inline void DoSleepOrRegisterWrites(uintptr_t base_address, const SleepOrRegisterWrite *reg_writes, size_t num_writes) {
            for (size_t i = 0; i < num_writes; i++) {
                switch (reg_writes[i].kind) {
                    case SleepOrRegisterWriteKind_Write:
                        reg::Write(base_address + sizeof(u32) * reg_writes[i].offset, reg_writes[i].value);
                        break;
                    case SleepOrRegisterWriteKind_Sleep:
                        util::WaitMicroSeconds(reg_writes[i].offset * UINT64_C(1000));
                        break;
                    AMS_UNREACHABLE_DEFAULT_CASE();
                }
            }
        }

        void WaitDsiTrigger() {
            const u32 timeout = util::GetMicroSeconds() + (DsiWaitForCommandMilliSecondsMax * 1000u);

            while (true) {
                if (util::GetMicroSeconds() >= timeout) {
                    break;
                }
                if (reg::Read(g_dsi_regs + sizeof(u32) * DSI_TRIGGER) == 0) {
                    break;
                }
            }

            util::WaitMicroSeconds(DsiWaitForCommandCompletionMilliSeconds * 1000u);
        }

        void WaitDsiHostControl() {
            const u32 timeout = util::GetMicroSeconds() + (DsiWaitForHostControlMilliSecondsMax * 1000u);

            while (true) {
                if (util::GetMicroSeconds() >= timeout) {
                    break;
                }
                if ((reg::Read(g_dsi_regs + sizeof(u32) * DSI_HOST_CONTROL) & DSI_HOST_CONTROL_IMM_BTA) == 0) {
                    break;
                }
            }
        }

        void EnableBacklightForVendor2050ForHardwareTypeFive(int brightness) {
            /* Enable FRAME_END_INT */
            reg::Write(g_disp1_regs + sizeof(u32) * DC_CMD_INT_ENABLE, 2);

            /* Configure DSI_LINE_TYPE as FOUR */
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_VIDEO_MODE_CONTROL, 1);
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_VIDEO_MODE_CONTROL, 9);

            /* Set and wait for FRAME_END_INT */
            reg::Write(g_disp1_regs + sizeof(u32) * DC_CMD_INT_STATUS, 2);
            while ((reg::Read(g_disp1_regs + sizeof(u32) * DC_CMD_INT_STATUS) & 2) != 0) { /* ... */ }

            /* Configure display brightness. */
            const u32 brightness_val = ((0x7FF * brightness) / 100);
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x339);
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, (brightness_val & 0x700) | ((brightness_val & 0xFF) << 16) | 0x51);

            /* Set and wait for FRAME_END_INT */
            reg::Write(g_disp1_regs + sizeof(u32) * DC_CMD_INT_STATUS, 2);
            while ((reg::Read(g_disp1_regs + sizeof(u32) * DC_CMD_INT_STATUS) & 2) != 0) { /* ... */ }

            /* Set client sync point block reset. */
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_INCR_SYNCPT_CNTRL, 1);
            util::WaitMicroSeconds(300'000ul);

            /* Clear client sync point block resest. */
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_INCR_SYNCPT_CNTRL, 0);
            util::WaitMicroSeconds(300'000ul);

            /* Clear DSI_LINE_TYPE config. */
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_VIDEO_MODE_CONTROL, 0);

            /* Disable FRAME_END_INT */
            reg::Write(g_disp1_regs + sizeof(u32) * DC_CMD_INT_ENABLE, 0);
            reg::Write(g_disp1_regs + sizeof(u32) * DC_CMD_INT_STATUS, 2);
        }

        void EnableBacklightForGeneric(int brightness) {
            AMS_UNUSED(brightness);

            reg::SetBits(g_gpio_regs + GPIO_PORT6_OUT_1, 0x1);
        }

        #define DO_REGISTER_WRITES(base_address, writes) DoRegisterWrites(base_address, writes, util::size(writes))
        #define DO_SOC_DEPENDENT_REGISTER_WRITES(base_address, writes) DoSocDependentRegisterWrites(base_address, writes##Erista, util::size(writes##Erista), writes##Mariko, util::size(writes##Mariko))
        #define DO_SLEEP_OR_REGISTER_WRITES(base_address, writes) DoSleepOrRegisterWrites(base_address, writes, util::size(writes))

        void InitializeFrameBuffer() {
            if (g_frame_buffer != nullptr) {
                std::memset(g_frame_buffer, 0, FrameBufferSize);
                hw::FlushDataCache(g_frame_buffer, FrameBufferSize);
            } else {
                /* Clear the frame buffer. */
                g_frame_buffer = secmon::MemoryRegionDramDcFramebuffer.GetPointer<u32>();
                std::memset(g_frame_buffer, 0, FrameBufferSize);
                hw::FlushDataCache(g_frame_buffer, FrameBufferSize);

                /* Attach the frame buffer to DC. */
                InitializeDevicePageTableForDc();
            }
        }

        void FinalizeFrameBuffer() {
            /* We don't actually support finalizing the framebuffer, so do nothing here. */
        }

    }

    void FinalizeDisplay() {
        FinalizeFrameBuffer();
        /* TODO */
        AMS_SECMON_LOG("FinalizeDisplay not yet implemented\n");
    }

    void InitializeDisplay() {
        /* Ensure that the display is finalized. */
        /* TODO */

        /* Setup the framebuffer. */
        InitializeFrameBuffer();

        /* Get the hardware type. */
        const auto hw_type = fuse::GetHardwareType();

        /* Turn on DSI/voltage rail. */
        {
            if (GetSocType() == fuse::SocType_Mariko) {
                i2c::SendByte(i2c::Port_5, I2cAddressMax77620Pmic, 0x18, 0x3A);
                i2c::SendByte(i2c::Port_5, I2cAddressMax77620Pmic, 0x18, 0x3A);
            }
            i2c::SendByte(i2c::Port_5, I2cAddressMax77620Pmic, 0x23, 0xD0);
        }

        /* Enable MIPI CAL, DSI, DISP1, HOST1X, UART_FST_MIPI_CAL, DSIA LP clocks. */
        reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_RST_DEV_H_CLR, CLK_RST_REG_BITS_ENUM(RST_DEV_H_CLR_CLR_MIPI_CAL_RST, ENABLE),
                                                                      CLK_RST_REG_BITS_ENUM(RST_DEV_H_CLR_CLR_DSI_RST,      ENABLE));

        reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_CLK_ENB_H_SET, CLK_RST_REG_BITS_ENUM(CLK_ENB_H_SET_SET_CLK_ENB_MIPI_CAL, ENABLE),
                                                                      CLK_RST_REG_BITS_ENUM(CLK_ENB_H_SET_SET_CLK_ENB_DSI,      ENABLE));

        reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_RST_DEV_L_CLR, CLK_RST_REG_BITS_ENUM(RST_DEV_L_CLR_CLR_HOST1X_RST, ENABLE),
                                                                      CLK_RST_REG_BITS_ENUM(RST_DEV_L_CLR_CLR_DISP1_RST,  ENABLE));

        reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_CLK_ENB_L_SET, CLK_RST_REG_BITS_ENUM(CLK_ENB_L_SET_SET_CLK_ENB_HOST1X, ENABLE),
                                                                      CLK_RST_REG_BITS_ENUM(CLK_ENB_L_SET_SET_CLK_ENB_DISP1,  ENABLE));


        reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_CLK_ENB_X_SET, CLK_RST_REG_BITS_ENUM(CLK_ENB_X_SET_SET_CLK_ENB_UART_FST_MIPI_CAL, ENABLE));

        reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_CLK_SOURCE_UART_FST_MIPI_CAL, CLK_RST_REG_BITS_VALUE(CLK_SOURCE_UART_FST_MIPI_CAL_UART_FST_MIPI_CAL_CLK_DIVISOR,        10),
                                                                                     CLK_RST_REG_BITS_ENUM (CLK_SOURCE_UART_FST_MIPI_CAL_UART_FST_MIPI_CAL_CLK_SRC,     PLLP_OUT3));

        reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_CLK_ENB_W_SET, CLK_RST_REG_BITS_ENUM(CLK_ENB_W_SET_SET_CLK_ENB_DSIA_LP, ENABLE));

        reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_CLK_SOURCE_DSIA_LP, CLK_RST_REG_BITS_VALUE(CLK_SOURCE_DSIA_LP_DSIA_LP_CLK_DIVISOR,        10),
                                                                           CLK_RST_REG_BITS_ENUM (CLK_SOURCE_DSIA_LP_DSIA_LP_CLK_SRC,     PLLP_OUT0));

        /* Set IO_DPD_REQ to DPD_OFF. */
        reg::ReadWrite(PMC + APBDEV_PMC_IO_DPD_REQ,  PMC_REG_BITS_ENUM(IO_DPD_REQ_CODE,  DPD_OFF));
        reg::ReadWrite(PMC + APBDEV_PMC_IO_DPD2_REQ, PMC_REG_BITS_ENUM(IO_DPD2_REQ_CODE, DPD_OFF));

        /* Configure LCD pinmux tristate + passthrough. */
        reg::ClearBits(g_apb_misc_regs + PINMUX_AUX_NFC_EN,     reg::EncodeMask(PINMUX_REG_BITS_MASK(AUX_TRISTATE)));
        reg::ClearBits(g_apb_misc_regs + PINMUX_AUX_NFC_INT,    reg::EncodeMask(PINMUX_REG_BITS_MASK(AUX_TRISTATE)));
        reg::ClearBits(g_apb_misc_regs + PINMUX_AUX_LCD_BL_PWM, reg::EncodeMask(PINMUX_REG_BITS_MASK(AUX_TRISTATE)));
        reg::ClearBits(g_apb_misc_regs + PINMUX_AUX_LCD_BL_EN,  reg::EncodeMask(PINMUX_REG_BITS_MASK(AUX_TRISTATE)));
        reg::ClearBits(g_apb_misc_regs + PINMUX_AUX_LCD_RST,    reg::EncodeMask(PINMUX_REG_BITS_MASK(AUX_TRISTATE)));

        if (hw_type == fuse::HardwareType_Five) {
            /* Configure LCD backlight. */
            reg::SetBits(g_gpio_regs + GPIO_PORT6_CNF_1, 0x4);
            reg::SetBits(g_gpio_regs + GPIO_PORT6_OE_1,  0x4);
        } else {
            /* Configure LCD power, VDD. */
            reg::SetBits(g_gpio_regs + GPIO_PORT3_CNF_0, 0x3);
            reg::SetBits(g_gpio_regs + GPIO_PORT3_OE_0,  0x3);
            reg::SetBits(g_gpio_regs + GPIO_PORT3_OUT_0, 0x1);
            util::WaitMicroSeconds(10'000ul);

            reg::SetBits(g_gpio_regs + GPIO_PORT3_OUT_0, 0x2);
            util::WaitMicroSeconds(10'000ul);

            /* Configure LCD backlight. */
            reg::SetBits(g_gpio_regs + GPIO_PORT6_CNF_1, 0x7);
            reg::SetBits(g_gpio_regs + GPIO_PORT6_OE_1,  0x7);
            reg::SetBits(g_gpio_regs + GPIO_PORT6_OUT_1, 0x2);
        }

        /* Configure display interface and display. */
        reg::Write(g_mipi_cal_regs + MIPI_CAL_MIPI_BIAS_PAD_CFG2, 0);
        if (GetSocType() == fuse::SocType_Mariko) {
            reg::Write(g_mipi_cal_regs + MIPI_CAL_MIPI_BIAS_PAD_CFG0, 0);
            reg::Write(g_apb_misc_regs + APB_MISC_GP_DSI_PAD_CONTROL, 0);
        }

        /* Execute configs. */
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_clk_rst_regs, DisplayConfigPlld01);
        DO_SLEEP_OR_REGISTER_WRITES(g_disp1_regs, DisplayConfigDc01);
        DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init01);
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init02);
        DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init03);
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init04);
        DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init05);
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsiPhyTiming);
        DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init06);
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsiPhyTiming);
        DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init07);
        util::WaitMicroSeconds(10'000ul);

        /* Enable backlight reset. */
        reg::SetBits(g_gpio_regs + GPIO_PORT6_OUT_1, 0x4);
        util::WaitMicroSeconds(60'000ul);

        if (hw_type == fuse::HardwareType_Five) {
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_BTA_TIMING, 0x40103);
        } else {
            reg::Write(g_dsi_regs + sizeof(u32) * DSI_BTA_TIMING, 0x50204);
        }

        reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x337);
        reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
        WaitDsiTrigger();

        reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x406);
        reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
        WaitDsiTrigger();

        reg::Write(g_dsi_regs + sizeof(u32) * DSI_HOST_CONTROL, DSI_HOST_CONTROL_TX_TRIG_HOST | DSI_HOST_CONTROL_IMM_BTA | DSI_HOST_CONTROL_CS | DSI_HOST_CONTROL_ECC);
        WaitDsiHostControl();
        util::WaitMicroSeconds(5'000ul);

        /* Parse LCD vendor. */
        {
            u32 host_response[3];
            for (size_t i = 0; i < util::size(host_response); i++) {
                host_response[i] = reg::Read(g_dsi_regs + sizeof(u32) * DSI_RD_DATA);
            }

            /* The last word from host response is:
                Bits 0-7: FAB
                Bits 8-15: REV
                Bits 16-23: Minor REV
            */
            u32 lcd_vendor;
            if ((host_response[2] & 0xFF) == 0x10) {
                lcd_vendor = 0;
            } else {
                lcd_vendor = (host_response[2] >> 8) & 0xFF00;
            }
            lcd_vendor = (lcd_vendor & 0xFFFFFF00) | (host_response[2] & 0xFF);

            AMS_ASSERT(lcd_vendor == GetLcdVendor());
        }

        /* LCD vendor specific configuration. */
        switch (GetLcdVendor()) {
            case 0x10: /* Japan Display Inc screens. */
                DO_SLEEP_OR_REGISTER_WRITES(g_dsi_regs, DisplayConfigJdiSpecificInit01);
                break;
            case 0xF20: /* Innolux first revision screens. */
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x1105);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(180'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x439);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x9483FFB9);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(5'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x739);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x751548B1);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x143209);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(5'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x2905);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                break;
            case 0xF30: /* AUO first revision screens. */
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x1105);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(180'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x439);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x9483FFB9);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(5'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x739);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x711148B1);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x143209);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(5'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x2905);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                break;
            case 0x2050: /* Unknown (hardware type 5) screen. */
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x1105);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(180'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0xA015);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x205315);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x339);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x51);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(5'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x2905);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                break;
            case 0x1020: /* Innolux second revision screen. */
            case 0x1030: /* AUO second revision screen. */
            case 0x1040: /* Unknown second revision screen. */
            default:
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x1105);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                util::WaitMicroSeconds(120'000ul);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x2905);
                reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST);
                break;
        }
        util::WaitMicroSeconds(20'000ul);

        DO_SOC_DEPENDENT_REGISTER_WRITES(g_clk_rst_regs, DisplayConfigPlld02);
        DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init08);
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsiPhyTiming);
        DO_SLEEP_OR_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init09);

        reg::Write(g_disp1_regs + sizeof(u32) * DC_DISP_DISP_CLOCK_CONTROL, SHIFT_CLK_DIVIDER(4));
        DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init10);
        util::WaitMicroSeconds(10'000ul);

        /* Configure MIPI CAL. */
        DO_REGISTER_WRITES(g_mipi_cal_regs, DisplayConfigMipiCal01);
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_mipi_cal_regs, DisplayConfigMipiCal02);
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init11);
        DO_SOC_DEPENDENT_REGISTER_WRITES(g_mipi_cal_regs, DisplayConfigMipiCal03);
        DO_REGISTER_WRITES(g_mipi_cal_regs, DisplayConfigMipiCal04);
        if (GetSocType() == fuse::SocType_Mariko) {
            /* On Mariko the above configurations are executed twice, for some reason. */
            DO_SOC_DEPENDENT_REGISTER_WRITES(g_mipi_cal_regs, DisplayConfigMipiCal02);
            DO_SOC_DEPENDENT_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Init11);
            DO_SOC_DEPENDENT_REGISTER_WRITES(g_mipi_cal_regs, DisplayConfigMipiCal03);
            DO_REGISTER_WRITES(g_mipi_cal_regs, DisplayConfigMipiCal04);
        }
        util::WaitMicroSeconds(10'000ul);

        /* Write DISP1, FrameBuffer config. */
        DO_SLEEP_OR_REGISTER_WRITES(g_disp1_regs, DisplayConfigDc02);
        DO_SLEEP_OR_REGISTER_WRITES(g_disp1_regs, DisplayConfigFrameBuffer);
        if (GetLcdVendor() != 0x2050) {
            util::WaitMicroSeconds(35'000ul);
        }
    }

    void ShowDisplay(const ams::impl::FatalErrorContext *f_ctx, const Result save_result) {
        /* Draw the image to the screen. */
        std::memset(g_frame_buffer, 0, FrameBufferSize);
        {
            /* TODO: Actually print the contents of the report. */
            AMS_UNUSED(f_ctx, save_result);
            for (size_t n = 0; n < 8; n++) {
                const size_t x = n * (FrameBufferWidth / 8);
                for (size_t cur_y = 0; cur_y < FrameBufferHeight; cur_y++) {
                    for (size_t cur_x = 0; cur_x < (FrameBufferWidth / 8); cur_x++) {
                        g_frame_buffer[(FrameBufferWidth - (x + cur_x)) * FrameBufferHeight + 0 + cur_y] = ((0x20 * n) | 0x1F);
                    }
                }
            }
        }
        hw::FlushDataCache(g_frame_buffer, FrameBufferSize);

        /* Enable backlight. */
        constexpr auto DisplayBrightness = 100;
        if (GetLcdVendor() == 0x2050) {
            EnableBacklightForVendor2050ForHardwareTypeFive(DisplayBrightness);
        } else {
            EnableBacklightForGeneric(DisplayBrightness);
        }
    }

}