/* * 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 . */ #include #include "boot_display.hpp" #include "boot_i2c_utils.hpp" #include "boot_registers_di.hpp" namespace ams::boot { /* Display configuration included into anonymous namespace. */ namespace { #include "boot_display_config.inc" } namespace { /* Helpful defines. */ constexpr size_t DeviceAddressSpaceAlignSize = 4_MB; constexpr dd::DeviceVirtualAddress FrameBufferDeviceAddress = DisplayConfigFrameBufferAddress; constexpr size_t FrameBufferWidth = 768; constexpr size_t FrameBufferHeight = 1280; constexpr size_t FrameBufferSize = FrameBufferHeight * FrameBufferWidth * sizeof(u32); constexpr dd::PhysicalAddress PmcBase = 0x7000E400ul; constexpr dd::PhysicalAddress Disp1Base = 0x54200000ul; constexpr dd::PhysicalAddress DsiBase = 0x54300000ul; constexpr dd::PhysicalAddress ClkRstBase = 0x60006000ul; constexpr dd::PhysicalAddress GpioBase = 0x6000D000ul; constexpr dd::PhysicalAddress ApbMiscBase = 0x70000000ul; constexpr dd::PhysicalAddress MipiCalBase = 0x700E3000ul; constexpr size_t Disp1Size = 3 * os::MemoryPageSize; constexpr size_t DsiSize = os::MemoryPageSize; constexpr size_t ClkRstSize = os::MemoryPageSize; constexpr size_t GpioSize = os::MemoryPageSize; constexpr size_t ApbMiscSize = os::MemoryPageSize; constexpr size_t MipiCalSize = os::MemoryPageSize; constexpr int DsiWaitForCommandMilliSecondsMax = 250; constexpr int DsiWaitForCommandCompletionMilliSeconds = 5; constexpr int DsiWaitForHostControlMilliSecondsMax = 150; 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. */ constinit bool g_is_display_intialized = false; constinit spl::SocType g_soc_type = spl::SocType_Erista; constinit u32 g_lcd_vendor = 0; constinit int g_display_brightness = 100; constinit dd::DeviceAddressSpaceType g_device_address_space; constinit pwm::driver::ChannelSession g_lcd_backlight_session; constinit u32 *g_frame_buffer = nullptr; constinit u8 g_frame_buffer_storage[DeviceAddressSpaceAlignSize + FrameBufferSize]; constinit uintptr_t g_disp1_regs = 0; constinit uintptr_t g_dsi_regs = 0; constinit uintptr_t g_clk_rst_regs = 0; constinit uintptr_t g_gpio_regs = 0; constinit uintptr_t g_apb_misc_regs = 0; constinit uintptr_t g_mipi_cal_regs = 0; /* Helper functions. */ void InitializeRegisterVirtualAddresses() { g_disp1_regs = dd::QueryIoMapping(Disp1Base, Disp1Size); g_dsi_regs = dd::QueryIoMapping(DsiBase, DsiSize); g_clk_rst_regs = dd::QueryIoMapping(ClkRstBase, ClkRstSize); g_gpio_regs = dd::QueryIoMapping(GpioBase, GpioSize); g_apb_misc_regs = dd::QueryIoMapping(ApbMiscBase, ApbMiscSize); g_mipi_cal_regs = dd::QueryIoMapping(MipiCalBase, MipiCalSize); AMS_ABORT_UNLESS(g_disp1_regs != 0); AMS_ABORT_UNLESS(g_dsi_regs != 0); AMS_ABORT_UNLESS(g_clk_rst_regs != 0); AMS_ABORT_UNLESS(g_gpio_regs != 0); AMS_ABORT_UNLESS(g_apb_misc_regs != 0); AMS_ABORT_UNLESS(g_mipi_cal_regs != 0); } 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 (g_soc_type) { case spl::SocType_Erista: DoRegisterWrites(base_address, reg_writes_erista, num_writes_erista); break; case spl::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: os::SleepThread(TimeSpan::FromMilliSeconds(reg_writes[i].offset)); break; AMS_UNREACHABLE_DEFAULT_CASE(); } } } #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, 0x00, FrameBufferSize); dd::FlushDataCache(g_frame_buffer, FrameBufferSize); } else { const uintptr_t frame_buffer_aligned = util::AlignUp(reinterpret_cast(g_frame_buffer_storage), DeviceAddressSpaceAlignSize); g_frame_buffer = reinterpret_cast(frame_buffer_aligned); std::memset(g_frame_buffer, 0x00, FrameBufferSize); dd::FlushDataCache(g_frame_buffer, FrameBufferSize); /* Create Address Space. */ R_ABORT_UNLESS(dd::CreateDeviceAddressSpace(std::addressof(g_device_address_space), 0, (UINT64_C(1) << 32))); /* Attach it to the DC. */ R_ABORT_UNLESS(dd::AttachDeviceAddressSpace(std::addressof(g_device_address_space), svc::DeviceName_Dc)); /* Map the framebuffer for the DC as read-only. */ R_ABORT_UNLESS(dd::MapDeviceAddressSpaceAligned(std::addressof(g_device_address_space), dd::GetCurrentProcessHandle(), frame_buffer_aligned, FrameBufferSize, FrameBufferDeviceAddress, dd::MemoryPermission_ReadOnly)); } } void FinalizeFrameBuffer() { if (g_frame_buffer != nullptr) { const uintptr_t frame_buffer_aligned = util::AlignUp(reinterpret_cast(g_frame_buffer_storage), DeviceAddressSpaceAlignSize); /* Unmap the framebuffer from the DC. */ dd::UnmapDeviceAddressSpace(std::addressof(g_device_address_space), dd::GetCurrentProcessHandle(), frame_buffer_aligned, FrameBufferSize, FrameBufferDeviceAddress); /* Detach address space from the DC. */ dd::DetachDeviceAddressSpace(std::addressof(g_device_address_space), svc::DeviceName_Dc); /* Destroy the address space. */ dd::DestroyDeviceAddressSpace(std::addressof(g_device_address_space)); g_frame_buffer = nullptr; } } void WaitDsiTrigger() { os::Tick timeout = os::GetSystemTick() + os::ConvertToTick(TimeSpan::FromMilliSeconds(DsiWaitForCommandMilliSecondsMax)); while (true) { if (os::GetSystemTick() >= timeout) { break; } if (reg::Read(g_dsi_regs + sizeof(u32) * DSI_TRIGGER) == 0) { break; } } os::SleepThread(TimeSpan::FromMilliSeconds(DsiWaitForCommandCompletionMilliSeconds)); } void WaitDsiHostControl() { os::Tick timeout = os::GetSystemTick() + os::ConvertToTick(TimeSpan::FromMilliSeconds(DsiWaitForHostControlMilliSecondsMax)); while (true) { if (os::GetSystemTick() >= 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); os::SleepThread(TimeSpan::FromMilliSeconds(300)); /* Clear client sync point block resest. */ reg::Write(g_dsi_regs + sizeof(u32) * DSI_INCR_SYNCPT_CNTRL, 0); os::SleepThread(TimeSpan::FromMilliSeconds(300)); /* 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) { pwm::driver::SetScale(g_lcd_backlight_session, static_cast(brightness)); pwm::driver::SetEnabled(g_lcd_backlight_session, true); } } void InitializeDisplay() { /* Setup globals. */ InitializeRegisterVirtualAddresses(); g_soc_type = spl::GetSocType(); InitializeFrameBuffer(); /* Get the hardware type. */ const auto hw_type = spl::GetHardwareType(); /* Turn on DSI/voltage rail. */ { i2c::driver::I2cSession i2c_session; R_ABORT_UNLESS(i2c::driver::OpenSession(std::addressof(i2c_session), i2c::DeviceCode_Max77620Pmic)); if (g_soc_type == spl::SocType_Mariko) { WriteI2cRegister(i2c_session, 0x18, 0x3A); WriteI2cRegister(i2c_session, 0x1F, 0x71); } WriteI2cRegister(i2c_session, 0x23, 0xD0); i2c::driver::CloseSession(i2c_session); } /* 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. */ dd::WriteIoRegister(PmcBase + APBDEV_PMC_IO_DPD_REQ, reg::Encode(PMC_REG_BITS_ENUM(IO_DPD_REQ_CODE, DPD_OFF))); dd::WriteIoRegister(PmcBase + APBDEV_PMC_IO_DPD2_REQ, reg::Encode(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 == spl::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); os::SleepThread(TimeSpan::FromMilliSeconds(10)); reg::SetBits(g_gpio_regs + GPIO_PORT3_OUT_0, 0x2); os::SleepThread(TimeSpan::FromMilliSeconds(10)); /* Configure LCD backlight. */ R_ABORT_UNLESS(pwm::driver::OpenSession(std::addressof(g_lcd_backlight_session), pwm::DeviceCode_LcdBacklight)); pwm::driver::SetPeriod(g_lcd_backlight_session, TimeSpan::FromNanoSeconds(33898)); reg::SetBits(g_gpio_regs + GPIO_PORT6_CNF_1, 0x6); reg::SetBits(g_gpio_regs + GPIO_PORT6_OE_1, 0x6); 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 (g_soc_type == spl::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); /* NOTE: Nintendo bug here. */ /* As of 8.0.0, Nintendo writes this list to CAR instead of DSI */ /* This results in them zeroing CLK_SOURCE_UARTA... */ 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); os::SleepThread(TimeSpan::FromMilliSeconds(10)); /* Enable backlight reset. */ reg::SetBits(g_gpio_regs + GPIO_PORT6_OUT_1, 0x4); os::SleepThread(TimeSpan::FromMilliSeconds(60)); if (hw_type == spl::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(); os::SleepThread(TimeSpan::FromMilliSeconds(5)); /* 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 */ if ((host_response[2] & 0xFF) == 0x10) { g_lcd_vendor = 0; } else { g_lcd_vendor = (host_response[2] >> 8) & 0xFF00; } g_lcd_vendor = (g_lcd_vendor & 0xFFFFFF00) | (host_response[2] & 0xFF); } /* LCD vendor specific configuration. */ switch (g_lcd_vendor) { 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); os::SleepThread(TimeSpan::FromMilliSeconds(180)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(5)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(5)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(180)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(5)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(5)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(180)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(5)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(120)); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x2905); reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST); break; } os::SleepThread(TimeSpan::FromMilliSeconds(20)); 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); os::SleepThread(TimeSpan::FromMilliSeconds(10)); /* 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 (g_soc_type == spl::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); } os::SleepThread(TimeSpan::FromMilliSeconds(10)); /* Write DISP1, FrameBuffer config. */ DO_SLEEP_OR_REGISTER_WRITES(g_disp1_regs, DisplayConfigDc02); DO_SLEEP_OR_REGISTER_WRITES(g_disp1_regs, DisplayConfigFrameBuffer); if (g_lcd_vendor != 0x2050) { os::SleepThread(TimeSpan::FromMilliSeconds(35)); } g_is_display_intialized = true; } void ShowDisplay(size_t x, size_t y, size_t width, size_t height, const u32 *img) { if (!g_is_display_intialized) { return; } /* Draw the image to the screen. */ std::memset(g_frame_buffer, 0, FrameBufferSize); { for (size_t cur_y = 0; cur_y < height; cur_y++) { for (size_t cur_x = 0; cur_x < width; cur_x++) { g_frame_buffer[(FrameBufferHeight - (x + cur_x)) * FrameBufferWidth + y + cur_y] = img[cur_y * width + cur_x]; } } } dd::FlushDataCache(g_frame_buffer, FrameBufferSize); /* Enable backlight. */ if (g_lcd_vendor == 0x2050) { EnableBacklightForVendor2050ForHardwareTypeFive(g_display_brightness); } else { EnableBacklightForGeneric(g_display_brightness); } } void FinalizeDisplay() { if (!g_is_display_intialized) { return; } /* Disable backlight. */ if (g_lcd_vendor == 0x2050) { EnableBacklightForVendor2050ForHardwareTypeFive(0); } else { pwm::driver::SetEnabled(g_lcd_backlight_session, true); pwm::driver::CloseSession(g_lcd_backlight_session); } reg::Write(g_disp1_regs + sizeof(u32) * DSI_VIDEO_MODE_CONTROL, 1); reg::Write(g_disp1_regs + sizeof(u32) * DSI_WR_DATA, 0x2805); /* Nintendo waits 5 frames before continuing. */ { const uintptr_t host1x_vaddr = dd::GetIoMapping(0x500030A4, 4); const u32 start_val = reg::Read(host1x_vaddr); while (reg::Read(host1x_vaddr) < start_val + 5) { /* spinlock here. */ } } reg::Write(g_disp1_regs + sizeof(u32) * DC_CMD_STATE_ACCESS, (READ_MUX | WRITE_MUX)); reg::Write(g_disp1_regs + sizeof(u32) * DSI_VIDEO_MODE_CONTROL, 0); DO_REGISTER_WRITES(g_disp1_regs, DisplayConfigDc01Fini01); os::SleepThread(TimeSpan::FromMilliSeconds(40)); DO_SOC_DEPENDENT_REGISTER_WRITES(g_clk_rst_regs, DisplayConfigPlld01); DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Fini01); DO_SOC_DEPENDENT_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsiPhyTiming); DO_REGISTER_WRITES(g_dsi_regs, DisplayConfigDsi01Fini02); if (g_lcd_vendor != 0x2050) { os::SleepThread(TimeSpan::FromMilliSeconds(10)); } /* Vendor specific shutdown. */ switch (g_lcd_vendor) { case 0x10: /* Japan Display Inc screens. */ DO_SLEEP_OR_REGISTER_WRITES(g_dsi_regs, DisplayConfigJdiSpecificFini01); break; case 0xF30: /* AUO first revision screens. */ DO_SLEEP_OR_REGISTER_WRITES(g_dsi_regs, DisplayConfigAuoRev1SpecificFini01); break; case 0x1020: /* Innolux second revision screens. */ 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); os::SleepThread(TimeSpan::FromMilliSeconds(5)); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0xB39); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x751548B1); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x71143209); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x115631); reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST); os::SleepThread(TimeSpan::FromMilliSeconds(5)); break; case 0x1030: /* AUO second revision screens. */ 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); os::SleepThread(TimeSpan::FromMilliSeconds(5)); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0xB39); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x711148B1); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x71143209); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x114D31); reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST); os::SleepThread(TimeSpan::FromMilliSeconds(5)); break; case 0x1040: /* Unknown second revision screens. */ 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); os::SleepThread(TimeSpan::FromMilliSeconds(5)); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0xB39); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x731348B1); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x71243209); reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x4C31); reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST); os::SleepThread(TimeSpan::FromMilliSeconds(5)); break; default: break; } reg::Write(g_dsi_regs + sizeof(u32) * DSI_WR_DATA, 0x1005); reg::Write(g_dsi_regs + sizeof(u32) * DSI_TRIGGER, DSI_TRIGGER_HOST); os::SleepThread(g_lcd_vendor == 0x2050 ? TimeSpan::FromMilliSeconds(120) : TimeSpan::FromMilliSeconds(50)); /* Disable backlight RST/Voltage. */ reg::ClearBits(g_gpio_regs + GPIO_PORT6_OUT_1, 0x4); if (g_lcd_vendor == 0x2050) { os::SleepThread(TimeSpan::FromMilliSeconds(30)); } else { os::SleepThread(TimeSpan::FromMilliSeconds(10)); reg::ClearBits(g_gpio_regs + GPIO_PORT3_OUT_0, 0x2); os::SleepThread(TimeSpan::FromMilliSeconds(10)); reg::ClearBits(g_gpio_regs + GPIO_PORT3_OUT_0, 0x1); os::SleepThread(TimeSpan::FromMilliSeconds(10)); } /* Cut clock to DSI. */ reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_RST_DEV_H_SET, CLK_RST_REG_BITS_ENUM(RST_DEV_H_SET_SET_MIPI_CAL_RST, ENABLE), CLK_RST_REG_BITS_ENUM(RST_DEV_H_SET_SET_DSI_RST, ENABLE)); reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_CLK_ENB_H_CLR, CLK_RST_REG_BITS_ENUM(CLK_ENB_H_CLR_CLR_CLK_ENB_MIPI_CAL, ENABLE), CLK_RST_REG_BITS_ENUM(CLK_ENB_H_CLR_CLR_CLK_ENB_DSI, ENABLE)); reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_RST_DEV_L_SET, CLK_RST_REG_BITS_ENUM(RST_DEV_L_SET_SET_HOST1X_RST, ENABLE), CLK_RST_REG_BITS_ENUM(RST_DEV_L_SET_SET_DISP1_RST, ENABLE)); reg::Write(g_clk_rst_regs + CLK_RST_CONTROLLER_CLK_ENB_L_CLR, CLK_RST_REG_BITS_ENUM(CLK_ENB_L_CLR_CLR_CLK_ENB_HOST1X, ENABLE), CLK_RST_REG_BITS_ENUM(CLK_ENB_L_CLR_CLR_CLK_ENB_DISP1, ENABLE)); reg::Write(g_dsi_regs + sizeof(u32) * DSI_PAD_CONTROL_0, (DSI_PAD_CONTROL_VS1_PULLDN_CLK | DSI_PAD_CONTROL_VS1_PULLDN(0xF) | DSI_PAD_CONTROL_VS1_PDIO_CLK | DSI_PAD_CONTROL_VS1_PDIO(0xF))); reg::Write(g_dsi_regs + sizeof(u32) * DSI_POWER_CONTROL, 0); /* Unmap framebuffer from DC virtual address space. */ FinalizeFrameBuffer(); g_is_display_intialized = false; } void SetDisplayBrightness(int percentage) { g_display_brightness = percentage; } }