/* * Copyright (c) 2022, Liav A. * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #include namespace Kernel { namespace IntelGraphics { #define DDC2_I2C_ADDRESS 0x50 struct PLLSettings { bool is_valid() const { return (n != 0 && m1 != 0 && m2 != 0 && p1 != 0 && p2 != 0); } u64 compute_dot_clock(u64 refclock) const { return (refclock * (5 * m1 + m2) / n) / (p1 * p2); } u64 compute_vco(u64 refclock) const { return refclock * (5 * m1 + m2) / n; } u64 compute_m() const { return 5 * m1 + m2; } u64 compute_p() const { return p1 * p2; } u64 n { 0 }; u64 m1 { 0 }; u64 m2 { 0 }; u64 p1 { 0 }; u64 p2 { 0 }; }; static constexpr PLLMaxSettings G35Limits { { 20'000'000, 400'000'000 }, // values in Hz, dot_clock { 1'400'000'000, 2'800'000'000 }, // values in Hz, VCO { 3, 8 }, // n { 70, 120 }, // m { 10, 20 }, // m1 { 5, 9 }, // m2 { 5, 80 }, // p { 1, 8 }, // p1 { 5, 10 } // p2 }; } static Graphics::Modesetting calculate_modesetting_from_edid(EDID::Parser& edid, size_t index) { auto details = edid.detailed_timing(index).release_value(); Graphics::Modesetting mode; VERIFY(details.pixel_clock_khz()); mode.pixel_clock_in_khz = details.pixel_clock_khz(); size_t horizontal_active = details.horizontal_addressable_pixels(); size_t horizontal_sync_offset = details.horizontal_front_porch_pixels(); mode.horizontal.active = horizontal_active; mode.horizontal.sync_start = horizontal_active + horizontal_sync_offset; mode.horizontal.sync_end = horizontal_active + horizontal_sync_offset + details.horizontal_sync_pulse_width_pixels(); mode.horizontal.total = horizontal_active + details.horizontal_blanking_pixels(); size_t vertical_active = details.vertical_addressable_lines(); size_t vertical_sync_offset = details.vertical_front_porch_lines(); mode.vertical.active = vertical_active; mode.vertical.sync_start = vertical_active + vertical_sync_offset; mode.vertical.sync_end = vertical_active + vertical_sync_offset + details.vertical_sync_pulse_width_lines(); mode.vertical.total = vertical_active + details.vertical_blanking_lines(); return mode; } static bool check_pll_settings(IntelGraphics::PLLSettings const& settings, size_t reference_clock, IntelGraphics::PLLMaxSettings const& limits) { if (settings.n < limits.n.min || settings.n > limits.n.max) { dbgln_if(INTEL_GRAPHICS_DEBUG, "N is invalid {}", settings.n); return false; } if (settings.m1 < limits.m1.min || settings.m1 > limits.m1.max) { dbgln_if(INTEL_GRAPHICS_DEBUG, "m1 is invalid {}", settings.m1); return false; } if (settings.m2 < limits.m2.min || settings.m2 > limits.m2.max) { dbgln_if(INTEL_GRAPHICS_DEBUG, "m2 is invalid {}", settings.m2); return false; } if (settings.p1 < limits.p1.min || settings.p1 > limits.p1.max) { dbgln_if(INTEL_GRAPHICS_DEBUG, "p1 is invalid {}", settings.p1); return false; } if (settings.m1 <= settings.m2) { dbgln_if(INTEL_GRAPHICS_DEBUG, "m2 is invalid {} as it is bigger than m1 {}", settings.m2, settings.m1); return false; } auto m = settings.compute_m(); auto p = settings.compute_p(); if (m < limits.m.min || m > limits.m.max) { dbgln_if(INTEL_GRAPHICS_DEBUG, "m invalid {}", m); return false; } if (p < limits.p.min || p > limits.p.max) { dbgln_if(INTEL_GRAPHICS_DEBUG, "p invalid {}", p); return false; } auto dot = settings.compute_dot_clock(reference_clock); auto vco = settings.compute_vco(reference_clock); if (dot < limits.dot_clock.min || dot > limits.dot_clock.max) { dbgln_if(INTEL_GRAPHICS_DEBUG, "Dot clock invalid {}", dot); return false; } if (vco < limits.vco.min || vco > limits.vco.max) { dbgln_if(INTEL_GRAPHICS_DEBUG, "VCO clock invalid {}", vco); return false; } return true; } static size_t find_absolute_difference(u64 target_frequency, u64 checked_frequency) { if (target_frequency >= checked_frequency) return target_frequency - checked_frequency; return checked_frequency - target_frequency; } Optional IntelNativeDisplayConnector::create_pll_settings(u64 target_frequency, u64 reference_clock, IntelGraphics::PLLMaxSettings const& limits) { IntelGraphics::PLLSettings settings; IntelGraphics::PLLSettings best_settings; // FIXME: Is this correct for all Intel Native graphics cards? settings.p2 = 10; dbgln_if(INTEL_GRAPHICS_DEBUG, "Check PLL settings for ref clock of {} Hz, for target of {} Hz", reference_clock, target_frequency); u64 best_difference = 0xffffffff; for (settings.n = limits.n.min; settings.n <= limits.n.max; ++settings.n) { for (settings.m1 = limits.m1.max; settings.m1 >= limits.m1.min; --settings.m1) { for (settings.m2 = limits.m2.max; settings.m2 >= limits.m2.min; --settings.m2) { for (settings.p1 = limits.p1.max; settings.p1 >= limits.p1.min; --settings.p1) { dbgln_if(INTEL_GRAPHICS_DEBUG, "Check PLL settings for {} {} {} {} {}", settings.n, settings.m1, settings.m2, settings.p1, settings.p2); if (!check_pll_settings(settings, reference_clock, limits)) continue; auto current_dot_clock = settings.compute_dot_clock(reference_clock); if (current_dot_clock == target_frequency) return settings; auto difference = find_absolute_difference(target_frequency, current_dot_clock); if (difference < best_difference && (current_dot_clock > target_frequency)) { best_settings = settings; best_difference = difference; } } } } } if (best_settings.is_valid()) return best_settings; return {}; } ErrorOr> IntelNativeDisplayConnector::try_create(PhysicalAddress framebuffer_address, size_t framebuffer_resource_size, PhysicalAddress registers_region_address, size_t registers_region_length) { auto registers_region = TRY(MM.allocate_kernel_region(PhysicalAddress(registers_region_address), registers_region_length, "Intel Native Graphics Registers"sv, Memory::Region::Access::ReadWrite)); // FIXME: Try to put the address as parameter to this function to allow creating this DisplayConnector for many generations... auto gmbus_connector = TRY(GMBusConnector::create_with_physical_address(registers_region_address.offset(to_underlying(IntelGraphics::RegisterIndex::GMBusClock)))); auto connector = TRY(DeviceManagement::try_create_device(framebuffer_address, framebuffer_resource_size, move(gmbus_connector), move(registers_region))); TRY(connector->initialize_gmbus_settings_and_read_edid()); // Note: This is very important to set the resolution to something safe so we // can create a framebuffer console with valid resolution. { SpinlockLocker control_lock(connector->m_control_lock); TRY(connector->set_safe_mode_setting()); } TRY(connector->create_attached_framebuffer_console()); return connector; } ErrorOr IntelNativeDisplayConnector::initialize_gmbus_settings_and_read_edid() { gmbus_read_edid(); return {}; } ErrorOr IntelNativeDisplayConnector::set_y_offset(size_t) { return Error::from_errno(ENOTIMPL); } ErrorOr IntelNativeDisplayConnector::unblank() { return Error::from_errno(ENOTIMPL); } void IntelNativeDisplayConnector::enable_console() { VERIFY(m_control_lock.is_locked()); VERIFY(m_framebuffer_console); m_framebuffer_console->enable(); } void IntelNativeDisplayConnector::disable_console() { VERIFY(m_control_lock.is_locked()); VERIFY(m_framebuffer_console); m_framebuffer_console->disable(); } ErrorOr IntelNativeDisplayConnector::flush_first_surface() { return Error::from_errno(ENOTSUP); } ErrorOr IntelNativeDisplayConnector::create_attached_framebuffer_console() { m_framebuffer_console = Graphics::ContiguousFramebufferConsole::initialize(m_framebuffer_address.value(), m_current_mode_setting.horizontal_active, m_current_mode_setting.vertical_active, m_current_mode_setting.horizontal_stride); GraphicsManagement::the().set_console(*m_framebuffer_console); return {}; } IntelNativeDisplayConnector::IntelNativeDisplayConnector(PhysicalAddress framebuffer_address, size_t framebuffer_resource_size, NonnullOwnPtr gmbus_connector, NonnullOwnPtr registers_region) : DisplayConnector(framebuffer_address, framebuffer_resource_size, true) , m_registers_region(move(registers_region)) , m_gmbus_connector(move(gmbus_connector)) { } ErrorOr IntelNativeDisplayConnector::set_mode_setting(DisplayConnector::ModeSetting const&) { return Error::from_errno(ENOTIMPL); } ErrorOr IntelNativeDisplayConnector::set_safe_mode_setting() { set_safe_crt_resolution(); return {}; } void IntelNativeDisplayConnector::enable_vga_plane() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); } [[maybe_unused]] static StringView convert_register_index_to_string(IntelGraphics::RegisterIndex index) { switch (index) { case IntelGraphics::RegisterIndex::PipeAConf: return "PipeAConf"sv; case IntelGraphics::RegisterIndex::PipeBConf: return "PipeBConf"sv; case IntelGraphics::RegisterIndex::GMBusData: return "GMBusData"sv; case IntelGraphics::RegisterIndex::GMBusStatus: return "GMBusStatus"sv; case IntelGraphics::RegisterIndex::GMBusCommand: return "GMBusCommand"sv; case IntelGraphics::RegisterIndex::GMBusClock: return "GMBusClock"sv; case IntelGraphics::RegisterIndex::DisplayPlaneAControl: return "DisplayPlaneAControl"sv; case IntelGraphics::RegisterIndex::DisplayPlaneALinearOffset: return "DisplayPlaneALinearOffset"sv; case IntelGraphics::RegisterIndex::DisplayPlaneAStride: return "DisplayPlaneAStride"sv; case IntelGraphics::RegisterIndex::DisplayPlaneASurface: return "DisplayPlaneASurface"sv; case IntelGraphics::RegisterIndex::DPLLDivisorA0: return "DPLLDivisorA0"sv; case IntelGraphics::RegisterIndex::DPLLDivisorA1: return "DPLLDivisorA1"sv; case IntelGraphics::RegisterIndex::DPLLControlA: return "DPLLControlA"sv; case IntelGraphics::RegisterIndex::DPLLControlB: return "DPLLControlB"sv; case IntelGraphics::RegisterIndex::DPLLMultiplierA: return "DPLLMultiplierA"sv; case IntelGraphics::RegisterIndex::HTotalA: return "HTotalA"sv; case IntelGraphics::RegisterIndex::HBlankA: return "HBlankA"sv; case IntelGraphics::RegisterIndex::HSyncA: return "HSyncA"sv; case IntelGraphics::RegisterIndex::VTotalA: return "VTotalA"sv; case IntelGraphics::RegisterIndex::VBlankA: return "VBlankA"sv; case IntelGraphics::RegisterIndex::VSyncA: return "VSyncA"sv; case IntelGraphics::RegisterIndex::PipeASource: return "PipeASource"sv; case IntelGraphics::RegisterIndex::AnalogDisplayPort: return "AnalogDisplayPort"sv; case IntelGraphics::RegisterIndex::VGADisplayPlaneControl: return "VGADisplayPlaneControl"sv; default: VERIFY_NOT_REACHED(); } } void IntelNativeDisplayConnector::write_to_register(IntelGraphics::RegisterIndex index, u32 value) const { VERIFY(m_control_lock.is_locked()); SpinlockLocker lock(m_registers_lock); dbgln_if(INTEL_GRAPHICS_DEBUG, "Intel Graphics Display Connector:: Write to {} value of {:x}", convert_register_index_to_string(index), value); auto* reg = (u32 volatile*)m_registers_region->vaddr().offset(to_underlying(index)).as_ptr(); *reg = value; } u32 IntelNativeDisplayConnector::read_from_register(IntelGraphics::RegisterIndex index) const { VERIFY(m_control_lock.is_locked()); SpinlockLocker lock(m_registers_lock); auto* reg = (u32 volatile*)m_registers_region->vaddr().offset(to_underlying(index)).as_ptr(); u32 value = *reg; dbgln_if(INTEL_GRAPHICS_DEBUG, "Intel Graphics Display Connector: Read from {} value of {:x}", convert_register_index_to_string(index), value); return value; } bool IntelNativeDisplayConnector::pipe_a_enabled() const { VERIFY(m_control_lock.is_locked()); return read_from_register(IntelGraphics::RegisterIndex::PipeAConf) & (1 << 30); } bool IntelNativeDisplayConnector::pipe_b_enabled() const { VERIFY(m_control_lock.is_locked()); return read_from_register(IntelGraphics::RegisterIndex::PipeBConf) & (1 << 30); } void IntelNativeDisplayConnector::gmbus_read_edid() { Array crt_edid_bytes {}; { SpinlockLocker control_lock(m_control_lock); MUST(m_gmbus_connector->write(Graphics::ddc2_i2c_address, 0)); MUST(m_gmbus_connector->read(Graphics::ddc2_i2c_address, crt_edid_bytes.data(), crt_edid_bytes.size())); } set_edid_bytes(crt_edid_bytes); } bool IntelNativeDisplayConnector::is_resolution_valid(size_t, size_t) { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); // FIXME: Check that we are able to modeset to the requested resolution! return true; } void IntelNativeDisplayConnector::disable_output() { VERIFY(m_control_lock.is_locked()); disable_dac_output(); disable_all_planes(); disable_pipe_a(); disable_pipe_b(); disable_dpll(); disable_vga_emulation(); } void IntelNativeDisplayConnector::enable_output(PhysicalAddress fb_address, size_t width) { VERIFY(m_control_lock.is_locked()); VERIFY(!pipe_a_enabled()); enable_pipe_a(); enable_primary_plane(fb_address, width); enable_dac_output(); } static size_t compute_dac_multiplier(size_t pixel_clock_in_khz) { dbgln_if(INTEL_GRAPHICS_DEBUG, "Intel native graphics: Pixel clock is {} KHz", pixel_clock_in_khz); VERIFY(pixel_clock_in_khz >= 25000); if (pixel_clock_in_khz >= 100000) { return 1; } else if (pixel_clock_in_khz >= 50000) { return 2; } else { return 4; } } bool IntelNativeDisplayConnector::set_safe_crt_resolution() { VERIFY(m_control_lock.is_locked()); SpinlockLocker modeset_lock(m_modeset_lock); // Note: Just in case we still allow access to VGA IO ports, disable it now. GraphicsManagement::the().disable_vga_emulation_access_permanently(); // FIXME: Get the requested resolution from the EDID!! auto modesetting = calculate_modesetting_from_edid(m_edid_parser.value(), 0); disable_output(); auto dac_multiplier = compute_dac_multiplier(modesetting.pixel_clock_in_khz); auto pll_settings = create_pll_settings((1000 * modesetting.pixel_clock_in_khz * dac_multiplier), 96'000'000, IntelGraphics::G35Limits); if (!pll_settings.has_value()) VERIFY_NOT_REACHED(); auto settings = pll_settings.value(); dbgln_if(INTEL_GRAPHICS_DEBUG, "PLL settings for {} {} {} {} {}", settings.n, settings.m1, settings.m2, settings.p1, settings.p2); enable_dpll_without_vga(pll_settings.value(), dac_multiplier); set_display_timings(modesetting); enable_output(m_framebuffer_address.value(), modesetting.horizontal.blanking_start()); DisplayConnector::ModeSetting mode_set { .horizontal_stride = modesetting.horizontal.blanking_start() * sizeof(u32), .pixel_clock_in_khz = 0, .horizontal_active = modesetting.horizontal.blanking_start(), .horizontal_front_porch_pixels = 0, .horizontal_sync_time_pixels = 0, .horizontal_blank_pixels = 0, .vertical_active = modesetting.vertical.blanking_start(), .vertical_front_porch_lines = 0, .vertical_sync_time_lines = 0, .vertical_blank_lines = 0, .horizontal_offset = 0, .vertical_offset = 0, }; m_current_mode_setting = mode_set; if (m_framebuffer_console) m_framebuffer_console->set_resolution(m_current_mode_setting.horizontal_active, m_current_mode_setting.vertical_active, m_current_mode_setting.horizontal_stride); return true; } void IntelNativeDisplayConnector::set_display_timings(Graphics::Modesetting const& modesetting) { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); VERIFY(!(read_from_register(IntelGraphics::RegisterIndex::PipeAConf) & (1 << 31))); VERIFY(!(read_from_register(IntelGraphics::RegisterIndex::PipeAConf) & (1 << 30))); dbgln_if(INTEL_GRAPHICS_DEBUG, "htotal - {}, {}", (modesetting.horizontal.active - 1), (modesetting.horizontal.total - 1)); write_to_register(IntelGraphics::RegisterIndex::HTotalA, (modesetting.horizontal.active - 1) | (modesetting.horizontal.total - 1) << 16); dbgln_if(INTEL_GRAPHICS_DEBUG, "hblank - {}, {}", (modesetting.horizontal.blanking_start() - 1), (modesetting.horizontal.blanking_end() - 1)); write_to_register(IntelGraphics::RegisterIndex::HBlankA, (modesetting.horizontal.blanking_start() - 1) | (modesetting.horizontal.blanking_end() - 1) << 16); dbgln_if(INTEL_GRAPHICS_DEBUG, "hsync - {}, {}", (modesetting.horizontal.sync_start - 1), (modesetting.horizontal.sync_end - 1)); write_to_register(IntelGraphics::RegisterIndex::HSyncA, (modesetting.horizontal.sync_start - 1) | (modesetting.horizontal.sync_end - 1) << 16); dbgln_if(INTEL_GRAPHICS_DEBUG, "vtotal - {}, {}", (modesetting.vertical.active - 1), (modesetting.vertical.total - 1)); write_to_register(IntelGraphics::RegisterIndex::VTotalA, (modesetting.vertical.active - 1) | (modesetting.vertical.total - 1) << 16); dbgln_if(INTEL_GRAPHICS_DEBUG, "vblank - {}, {}", (modesetting.vertical.blanking_start() - 1), (modesetting.vertical.blanking_end() - 1)); write_to_register(IntelGraphics::RegisterIndex::VBlankA, (modesetting.vertical.blanking_start() - 1) | (modesetting.vertical.blanking_end() - 1) << 16); dbgln_if(INTEL_GRAPHICS_DEBUG, "vsync - {}, {}", (modesetting.vertical.sync_start - 1), (modesetting.vertical.sync_end - 1)); write_to_register(IntelGraphics::RegisterIndex::VSyncA, (modesetting.vertical.sync_start - 1) | (modesetting.vertical.sync_end - 1) << 16); dbgln_if(INTEL_GRAPHICS_DEBUG, "sourceSize - {}, {}", (modesetting.vertical.active - 1), (modesetting.horizontal.active - 1)); write_to_register(IntelGraphics::RegisterIndex::PipeASource, (modesetting.vertical.active - 1) | (modesetting.horizontal.active - 1) << 16); microseconds_delay(200); } bool IntelNativeDisplayConnector::wait_for_enabled_pipe_a(size_t milliseconds_timeout) const { size_t current_time = 0; while (current_time < milliseconds_timeout) { if (pipe_a_enabled()) return true; microseconds_delay(1000); current_time++; } return false; } bool IntelNativeDisplayConnector::wait_for_disabled_pipe_a(size_t milliseconds_timeout) const { size_t current_time = 0; while (current_time < milliseconds_timeout) { if (!pipe_a_enabled()) return true; microseconds_delay(1000); current_time++; } return false; } bool IntelNativeDisplayConnector::wait_for_disabled_pipe_b(size_t milliseconds_timeout) const { size_t current_time = 0; while (current_time < milliseconds_timeout) { if (!pipe_b_enabled()) return true; microseconds_delay(1000); current_time++; } return false; } void IntelNativeDisplayConnector::disable_dpll() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); write_to_register(IntelGraphics::RegisterIndex::DPLLControlA, 0); write_to_register(IntelGraphics::RegisterIndex::DPLLControlB, 0); } void IntelNativeDisplayConnector::disable_pipe_a() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); write_to_register(IntelGraphics::RegisterIndex::PipeAConf, 0); dbgln_if(INTEL_GRAPHICS_DEBUG, "Disabling Pipe A"); wait_for_disabled_pipe_a(100); dbgln_if(INTEL_GRAPHICS_DEBUG, "Disabling Pipe A - done."); } void IntelNativeDisplayConnector::disable_pipe_b() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); write_to_register(IntelGraphics::RegisterIndex::PipeAConf, 0); dbgln_if(INTEL_GRAPHICS_DEBUG, "Disabling Pipe B"); wait_for_disabled_pipe_b(100); dbgln_if(INTEL_GRAPHICS_DEBUG, "Disabling Pipe B - done."); } void IntelNativeDisplayConnector::enable_pipe_a() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); VERIFY(!(read_from_register(IntelGraphics::RegisterIndex::PipeAConf) & (1 << 31))); VERIFY(!(read_from_register(IntelGraphics::RegisterIndex::PipeAConf) & (1 << 30))); write_to_register(IntelGraphics::RegisterIndex::PipeAConf, (1 << 31) | (1 << 24)); dbgln_if(INTEL_GRAPHICS_DEBUG, "enabling Pipe A"); // FIXME: Seems like my video card is buggy and doesn't set the enabled bit (bit 30)!! wait_for_enabled_pipe_a(100); dbgln_if(INTEL_GRAPHICS_DEBUG, "enabling Pipe A - done."); } void IntelNativeDisplayConnector::enable_primary_plane(PhysicalAddress fb_address, size_t width) { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); VERIFY(((width * 4) % 64 == 0)); write_to_register(IntelGraphics::RegisterIndex::DisplayPlaneAStride, width * 4); write_to_register(IntelGraphics::RegisterIndex::DisplayPlaneALinearOffset, 0); write_to_register(IntelGraphics::RegisterIndex::DisplayPlaneASurface, fb_address.get()); // FIXME: Serenity uses BGR 32 bit pixel format, but maybe we should try to determine it somehow! write_to_register(IntelGraphics::RegisterIndex::DisplayPlaneAControl, (0b0110 << 26) | (1 << 31)); } void IntelNativeDisplayConnector::set_dpll_registers(IntelGraphics::PLLSettings const& settings) { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); write_to_register(IntelGraphics::RegisterIndex::DPLLDivisorA0, (settings.m2 - 2) | ((settings.m1 - 2) << 8) | ((settings.n - 2) << 16)); write_to_register(IntelGraphics::RegisterIndex::DPLLDivisorA1, (settings.m2 - 2) | ((settings.m1 - 2) << 8) | ((settings.n - 2) << 16)); write_to_register(IntelGraphics::RegisterIndex::DPLLControlA, 0); } void IntelNativeDisplayConnector::enable_dpll_without_vga(IntelGraphics::PLLSettings const& settings, size_t dac_multiplier) { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); set_dpll_registers(settings); microseconds_delay(200); write_to_register(IntelGraphics::RegisterIndex::DPLLControlA, (6 << 9) | (settings.p1) << 16 | (1 << 26) | (1 << 28) | (1 << 31)); write_to_register(IntelGraphics::RegisterIndex::DPLLMultiplierA, (dac_multiplier - 1) | ((dac_multiplier - 1) << 8)); // The specification says we should wait (at least) about 150 microseconds // after enabling the DPLL to allow the clock to stabilize microseconds_delay(200); VERIFY(read_from_register(IntelGraphics::RegisterIndex::DPLLControlA) & (1 << 31)); } void IntelNativeDisplayConnector::disable_dac_output() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); write_to_register(IntelGraphics::RegisterIndex::AnalogDisplayPort, 0b11 << 10); } void IntelNativeDisplayConnector::enable_dac_output() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); write_to_register(IntelGraphics::RegisterIndex::AnalogDisplayPort, (1 << 31)); } void IntelNativeDisplayConnector::disable_vga_emulation() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); write_to_register(IntelGraphics::RegisterIndex::VGADisplayPlaneControl, (1 << 31)); read_from_register(IntelGraphics::RegisterIndex::VGADisplayPlaneControl); } void IntelNativeDisplayConnector::disable_all_planes() { VERIFY(m_control_lock.is_locked()); VERIFY(m_modeset_lock.is_locked()); write_to_register(IntelGraphics::RegisterIndex::DisplayPlaneAControl, 0); write_to_register(IntelGraphics::RegisterIndex::DisplayPlaneBControl, 0); } }