Luna/kernel/src/arch/x86_64/disk/ATA.cpp

#include "arch/x86_64/disk/ATA.h"
#include "Log.h"
#include "arch/Serial.h"
#include "arch/Timer.h"
#include "arch/x86_64/IO.h"
#include "memory/MemoryManager.h"
#include <luna/Vector.h>

SharedPtr<ATA::Controller> g_controller;

static void irq_handler(Registers* regs, void* ctx)
{
    ((ATA::Channel*)ctx)->irq_handler(regs);
}

static usize copy_ata_string(char* out, u16* in, usize size)
{
    for (usize i = 0; i < size; i += 2)
    {
        u16 val = in[i / 2];
        out[i] = (u8)(val >> 8);
        out[i + 1] = (u8)(val & 0xff);
    }

    out[size + 1] = '\0';

    return size;
}

namespace ATA
{
    Result<void> Controller::scan()
    {
        // FIXME: Propagate errors.
        PCI::scan(
            [](const PCI::Device& device) {
                if (!g_controller)
                {
                    auto controller = adopt_shared_if_nonnull(new (std::nothrow) Controller(device)).release_value();
                    kinfoln("ata: Found ATA controller on PCI bus (%x:%x:%x)", device.address.bus,
                            device.address.function, device.address.slot);

                    if (controller->initialize()) g_controller = controller;
                }
            },
            { .klass = 1, .subclass = 1 });

        if (!g_controller) kwarnln("ata: No ATA controller found.");

        return {};
    }

    bool Controller::initialize()
    {
        if (!m_primary_channel.initialize()) return false;

        return m_secondary_channel.initialize();
    }

    Controller::Controller(const PCI::Device& device)
        : m_device(device), m_primary_channel(this, 0, {}), m_secondary_channel(this, 1, {})
    {
    }

    Channel::Channel(Controller* controller, u8 channel_index, Badge<Controller>)
        : m_controller(controller), m_channel_index(channel_index)
    {
    }

    u8 Channel::read_register(Register reg)
    {
        return IO::inb(m_io_base + (u16)reg);
    }

    u16 Channel::read_data()
    {
        return IO::inw(m_io_base + (u16)Register::Data);
    }

    void Channel::write_data(u16 value)
    {
        IO::outw(m_io_base + (u16)Register::Data, value);
    }

    void Channel::write_register(Register reg, u8 value)
    {
        IO::outb(m_io_base + (u16)reg, value);
    }

    u8 Channel::read_control(ControlRegister reg)
    {
        return IO::inb(m_control_base + (u16)reg);
    }

    void Channel::write_control(ControlRegister reg, u8 value)
    {
        IO::outb(m_control_base + (u16)reg, value);
    }

    u8 Channel::read_bm(BusmasterRegister reg)
    {
        return IO::inb(m_busmaster_base + (u16)reg);
    }

    void Channel::write_bm(BusmasterRegister reg, u8 value)
    {
        IO::outb(m_busmaster_base + (u16)reg, value);
    }

    u32 Channel::read_prdt_address()
    {
        return IO::inl(m_busmaster_base + (u16)BusmasterRegister::PRDTAddress);
    }

    void Channel::write_prdt_address(u32 value)
    {
        IO::outl(m_busmaster_base + (u16)BusmasterRegister::PRDTAddress, value);
    }

    void Channel::delay_400ns()
    {
        // FIXME: We should use kernel_sleep(), but it doesn't support nanosecond granularity.
        for (int i = 0; i < 14; i++) { read_control(ControlRegister::AltStatus); }
    }

    void Channel::select(u8 drive)
    {
        if (drive == m_current_drive) return;

        u8 value = (drive << 4) | 0xa0;
        write_register(Register::DriveSelect, value);

        delay_400ns();

        m_current_drive = drive;
    }

    void Channel::irq_handler(Registers*)
    {
        // FIXME: Read the Busmaster register to make sure the IRQ is for this channel.

        // FIXME: Also read it in case there was a DMA read error.

        if (m_current_drive < 2 && m_drives[m_current_drive]) m_drives[m_current_drive]->irq_handler();

        m_thread->wake_up();
    }

    void Channel::wait_for_irq()
    {
        m_thread = Scheduler::current();

        kernel_wait_for_event();
    }

    bool Channel::wait_for_irq_or_timeout(u64 timeout)
    {
        m_thread = Scheduler::current();

        kernel_sleep(timeout);

        return m_thread->sleep_ticks_left;
    }

    bool Channel::wait_for_reg_set(Register reg, u8 value, u64 timeout)
    {
        u64 begin = Timer::ticks_ms();
        while (true)
        {
            u8 reg_value = read_register(reg);
            if (reg_value & value) return true;
            if ((Timer::ticks_ms() - begin) >= timeout) return false;
            kernel_sleep(1);
        }
    }

    bool Channel::wait_for_reg_clear(Register reg, u8 value, u64 timeout)
    {
        u64 begin = Timer::ticks_ms();
        while (true)
        {
            u8 reg_value = read_register(reg);
            if ((reg_value & value) == 0) return true;
            if ((Timer::ticks_ms() - begin) >= timeout) return false;
            kernel_sleep(1);
        }
    }

    Result<void> Channel::wait_until_ready()
    {
        if (!wait_for_reg_clear(Register::Status, SR_Busy, 1000))
        {
            kwarnln("ata: Drive %d:%d timed out (BSY)", m_channel_index, m_current_drive);
            return err(EIO);
        }

        if (!wait_for_reg_set(Register::Status, SR_DataRequestReady | SR_Error, 1000))
        {
            kwarnln("ata: Drive %d:%d timed out (DRQ)", m_channel_index, m_current_drive);
            return err(EIO);
        }

        u8 status = read_register(Register::Status);
        if (status & SR_Error)
        {
            kwarnln("ata: An error occurred in drive %d:%d while waiting for data to become available", m_channel_index,
                    m_current_drive);
            return err(EIO);
        }

        return {};
    }

    bool Channel::initialize()
    {
        int offset = m_channel_index ? 2 : 0;
        m_is_pci_native_mode = m_controller->device().type.prog_if & (1 << offset);

        u16 control_port_base_address;
        u16 io_base_address;

        if (m_is_pci_native_mode)
        {
            auto io_base = m_controller->device().getBAR(m_channel_index ? 2 : 0);
            if (!io_base.is_iospace())
            {
                kwarnln("ata: Channel %d's IO base BAR is not in IO space", m_channel_index);
                return false;
            }
            io_base_address = io_base.port();

            auto io_control = m_controller->device().getBAR(m_channel_index ? 3 : 1);
            if (!io_control.is_iospace())
            {
                kwarnln("ata: Channel %d's control base BAR is not in IO space", m_channel_index);
                return false;
            }

            control_port_base_address = io_control.port();
        }
        else
        {
            io_base_address = m_channel_index ? 0x170 : 0x1f0;
            control_port_base_address = m_channel_index ? 0x376 : 0x3f6;
        }

        m_io_base = io_base_address;
        m_control_base = control_port_base_address + 2;

        auto io_busmaster = m_controller->device().getBAR(4);
        if (!io_busmaster.is_iospace())
        {
            kwarnln("ata: Channel %d's busmaster base BAR is not in IO space", m_channel_index);
            return false;
        }
        m_busmaster_base = io_busmaster.port() + (u16)(m_channel_index * 8u);

        if (m_is_pci_native_mode) m_interrupt_line = PCI::read8(m_controller->device().address, PCI::InterruptLine);
        else
            m_interrupt_line = m_channel_index ? 15 : 14;

        bool ok = CPU::register_interrupt(m_interrupt_line, ::irq_handler, this);
        if (!ok)
        {
            kerrorln("ata: Failed to register IRQ handler for ATA channel %d (IRQ %d)", m_channel_index,
                     m_interrupt_line);
            return false;
        }

        for (u8 drive = 0; drive < 2; drive++)
        {
            ScopedKMutexLock<100> lock(m_lock);

            select(drive);

            if (read_register(Register::Status) == 0)
            {
                // No drive on this slot.
                continue;
            }

            kinfoln("ata: Channel %d has a drive on slot %d!", m_channel_index, drive);

            auto rc = adopt_shared_if_nonnull(new (std::nothrow) Drive(this, drive, {}));
            if (rc.has_error())
            {
                kinfoln("ata: Failed to create drive object: %s", rc.error_string());
                return false;
            }

            m_drives[drive] = rc.release_value();

            if (!m_drives[drive]->initialize())
            {
                m_drives[drive] = {};
                return false;
            }
        }

        return true;
    }

    Drive::Drive(Channel* channel, u8 drive_index, Badge<Channel>) : m_channel(channel), m_drive_index(drive_index)
    {
    }

    bool Drive::identify_ata()
    {
        m_channel->write_register(Register::Command, m_is_atapi ? CMD_Identify_Packet : CMD_Identify);

        m_channel->delay_400ns();

        if (!m_channel->wait_for_reg_clear(Register::Status, SR_Busy, 1000))
        {
            kwarnln("ata: Drive %d timed out clearing SR_Busy (waited for 1000 ms)", m_drive_index);
            return false;
        }

        if (m_channel->read_register(Register::Status) & SR_Error)
        {
            u8 lbam = m_channel->read_register(Register::LBAMiddle);
            u8 lbah = m_channel->read_register(Register::LBAHigh);

            if ((lbam == 0x14 && lbah == 0xeb) || (lbam == 0x69 && lbah == 0x96))
            {
                if (!m_is_atapi)
                {
                    kinfoln("ata: Drive %d is ATAPI, sending IDENTIFY_PACKET command", m_drive_index);
                    m_is_atapi = true;
                    return identify_ata();
                }
            }

            kwarnln("ata: IDENTIFY command for drive %d returned error", m_drive_index);

            return false;
        }

        if (!m_channel->wait_for_reg_set(Register::Status, SR_DataRequestReady | SR_Error, 1000))
        {
            kwarnln("ata: Drive %d timed out setting SR_DataRequestReady (waited for 1000 ms)", m_drive_index);
            return false;
        }

        u8 status = m_channel->read_register(Register::Status);
        if (status & SR_Error)
        {
            kwarnln("ata: IDENTIFY command for drive %d returned error", m_drive_index);
            return false;
        }

        for (usize i = 0; i < 256; i++)
        {
            u16 data = m_channel->read_data();
            m_identify_words[i] = data;
        }

        return true;
    }

    bool Drive::initialize()
    {
        m_channel->select(m_drive_index);

        m_channel->write_register(Register::SectorCount, 0);
        m_channel->write_register(Register::LBALow, 0);
        m_channel->write_register(Register::LBAMiddle, 0);
        m_channel->write_register(Register::LBAHigh, 0);

        if (!identify_ata()) return false;

        m_serial.set_length(copy_ata_string(m_serial.data(), &m_identify_words[10], SERIAL_LEN));
        m_revision.set_length(copy_ata_string(m_revision.data(), &m_identify_words[23], REVISION_LEN));
        m_model.set_length(copy_ata_string(m_model.data(), &m_identify_words[27], MODEL_LEN));

        m_serial.trim(" ");
        m_revision.trim(" ");
        m_model.trim(" ");

        kinfoln("ata: Drive IDENTIFY returned serial='%s', revision='%s' and model='%s'", m_serial.chars(),
                m_revision.chars(), m_model.chars());

        auto status = m_channel->read_bm(BusmasterRegister::Status);
        if (status & BMS_SimplexOnly)
        {
            kwarnln("ata: Drive %d will not use DMA because of simplex shenanigans", m_drive_index);
            m_uses_dma = false;
        }

        auto frame = MemoryManager::alloc_frame();
        if (frame.has_error() || frame.value() > 0xffffffff)
        {
            kwarnln("ata: Failed to allocate memory below the 32-bit limit for the PRDT");
            return false;
        }
        m_dma_prdt_phys = frame.release_value();
        m_dma_prdt = (prdt_entry*)MMU::translate_physical_address(m_dma_prdt_phys);

        frame = MemoryManager::alloc_frame();
        if (frame.has_error() || frame.value() > 0xffffffff)
        {
            kwarnln("ata: Failed to allocate memory below the 32-bit limit for DMA memory");
            return false;
        }
        m_dma_mem_phys = frame.release_value();
        m_dma_mem = (void*)MMU::translate_physical_address(m_dma_mem_phys);

        if (m_is_atapi)
        {
            atapi_packet packet;
            memset(&packet, 0, sizeof(packet));
            packet.command_bytes[0] = ATAPI_ReadCapacity;

            atapi_read_capacity_reply reply;

            if (send_packet_atapi_pio(&packet, &reply, sizeof(reply)).has_error())
            {
                kwarnln("ata: Failed to send Read Capacity command to ATAPI drive");
                return false;
            }

            // FIXME: This assumes the host machine is little-endian.
            u32 last_lba = __builtin_bswap32(reply.last_lba);
            u32 sector_size = __builtin_bswap32(reply.sector_size);

            kinfoln("ata: ATAPI drive %d capacity information: Last LBA=%u, Sector Size=%u, Total Capacity=%u",
                    m_drive_index, last_lba, sector_size, (last_lba + 1) * sector_size);
        }

        return true;
    }

    Result<void> Drive::send_packet_atapi_pio(const atapi_packet* packet, void* out, u16 response_size)
    {
        u8* ptr = (u8*)out;

        m_channel->select(m_drive_index);

        // We use PIO here.
        m_channel->write_register(Register::Features, 0x00);

        m_channel->write_register(Register::LBAMiddle, (u8)(response_size & 0xff));
        m_channel->write_register(Register::LBAHigh, (u8)(response_size >> 8));

        m_channel->write_register(Register::Command, CMD_Packet);

        m_channel->delay_400ns();

        usize i = 0;

        TRY(m_channel->wait_until_ready());

        for (int j = 0; j < 6; j++) m_channel->write_data(packet->command_words[j]);

        while (i < response_size)
        {
            TRY(m_channel->wait_until_ready());

            usize byte_count =
                m_channel->read_register(Register::LBAHigh) << 8 | m_channel->read_register(Register::LBAMiddle);
            usize word_count = byte_count / 2;

            while (word_count--)
            {
                u16 value = m_channel->read_data();
                ptr[0] = (u8)(value & 0xff);
                ptr[1] = (u8)(value >> 8);
                ptr += 2;
            }

            i += byte_count;
        }

        return {};
    }

    void Drive::irq_handler()
    {
        // Clear the IRQ flag.
        u8 status = m_channel->read_register(Register::Status);

        if (status & SR_Error)
        {
            u8 error = m_channel->read_register(Register::Error);
            (void)error;
        }
    }
}
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`#include "arch/x86_64/disk/ATA.h"`
			`#include "Log.h"`
kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00			`#include "arch/Serial.h"`
			`#include "arch/Timer.h"`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`#include "arch/x86_64/IO.h"`
kernel/ATA: Read the PCI Busmaster registers and start preparing for DMA 2023-05-13 18:56:27 +02:00			`#include "memory/MemoryManager.h"`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`#include <luna/Vector.h>`

			`SharedPtr<ATA::Controller> g_controller;`

kernel/ATA: Handle drive IRQs in compatibility mode 2023-05-13 14:24:45 +02:00			`static void irq_handler(Registers* regs, void* ctx)`
			`{`
			`((ATA::Channel*)ctx)->irq_handler(regs);`
			`}`

kernel/ATA: Read ATA strings properly instead of backwards Now we can see the model string. What does it say... "QEMU DVD-ROM". Let's go! 2023-05-13 16:34:18 +02:00			`static usize copy_ata_string(char* out, u16* in, usize size)`
			`{`
			`for (usize i = 0; i < size; i += 2)`
			`{`
			`u16 val = in[i / 2];`
			`out[i] = (u8)(val >> 8);`
			`out[i + 1] = (u8)(val & 0xff);`
			`}`

			`out[size + 1] = '\0';`

			`return size;`
			`}`

kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`namespace ATA`
			`{`
			`Result<void> Controller::scan()`
			`{`
			`// FIXME: Propagate errors.`
			`PCI::scan(`
			`[](const PCI::Device& device) {`
			`if (!g_controller)`
			`{`
			`auto controller = adopt_shared_if_nonnull(new (std::nothrow) Controller(device)).release_value();`
			`kinfoln("ata: Found ATA controller on PCI bus (%x:%x:%x)", device.address.bus,`
			`device.address.function, device.address.slot);`

			`if (controller->initialize()) g_controller = controller;`
			`}`
			`},`
			`{ .klass = 1, .subclass = 1 });`

kernel: Warn if no ATA controller is found 2023-05-11 19:27:05 +02:00			`if (!g_controller) kwarnln("ata: No ATA controller found.");`

kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`return {};`
			`}`

			`bool Controller::initialize()`
			`{`
			`if (!m_primary_channel.initialize()) return false;`

			`return m_secondary_channel.initialize();`
			`}`

			`Controller::Controller(const PCI::Device& device)`
			`: m_device(device), m_primary_channel(this, 0, {}), m_secondary_channel(this, 1, {})`
			`{`
			`}`

			`Channel::Channel(Controller* controller, u8 channel_index, Badge<Controller>)`
			`: m_controller(controller), m_channel_index(channel_index)`
			`{`
			`}`

kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`u8 Channel::read_register(Register reg)`
			`{`
			`return IO::inb(m_io_base + (u16)reg);`
			`}`

kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00			`u16 Channel::read_data()`
			`{`
			`return IO::inw(m_io_base + (u16)Register::Data);`
			`}`

kernel/ATA: Send a READ CAPACITY packet to an ATA drive on initialization 2023-05-13 22:18:44 +02:00			`void Channel::write_data(u16 value)`
			`{`
			`IO::outw(m_io_base + (u16)Register::Data, value);`
			`}`

kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`void Channel::write_register(Register reg, u8 value)`
			`{`
			`IO::outb(m_io_base + (u16)reg, value);`
			`}`

			`u8 Channel::read_control(ControlRegister reg)`
			`{`
			`return IO::inb(m_control_base + (u16)reg);`
			`}`

			`void Channel::write_control(ControlRegister reg, u8 value)`
			`{`
			`IO::outb(m_control_base + (u16)reg, value);`
			`}`

kernel/ATA: Read the PCI Busmaster registers and start preparing for DMA 2023-05-13 18:56:27 +02:00			`u8 Channel::read_bm(BusmasterRegister reg)`
			`{`
			`return IO::inb(m_busmaster_base + (u16)reg);`
			`}`

			`void Channel::write_bm(BusmasterRegister reg, u8 value)`
			`{`
			`IO::outb(m_busmaster_base + (u16)reg, value);`
			`}`

			`u32 Channel::read_prdt_address()`
			`{`
			`return IO::inl(m_busmaster_base + (u16)BusmasterRegister::PRDTAddress);`
			`}`

			`void Channel::write_prdt_address(u32 value)`
			`{`
			`IO::outl(m_busmaster_base + (u16)BusmasterRegister::PRDTAddress, value);`
			`}`

kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`void Channel::delay_400ns()`
			`{`
kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00			`// FIXME: We should use kernel_sleep(), but it doesn't support nanosecond granularity.`
			`for (int i = 0; i < 14; i++) { read_control(ControlRegister::AltStatus); }`
kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`}`

			`void Channel::select(u8 drive)`
			`{`
			`if (drive == m_current_drive) return;`

			`u8 value = (drive << 4) \| 0xa0;`
			`write_register(Register::DriveSelect, value);`

			`delay_400ns();`

			`m_current_drive = drive;`
			`}`

kernel/ATA: Handle drive IRQs in compatibility mode 2023-05-13 14:24:45 +02:00			`void Channel::irq_handler(Registers*)`
			`{`
			`// FIXME: Read the Busmaster register to make sure the IRQ is for this channel.`

			`// FIXME: Also read it in case there was a DMA read error.`

kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00			`if (m_current_drive < 2 && m_drives[m_current_drive]) m_drives[m_current_drive]->irq_handler();`

kernel/ATA: Handle drive IRQs in compatibility mode 2023-05-13 14:24:45 +02:00			`m_thread->wake_up();`
			`}`

			`void Channel::wait_for_irq()`
			`{`
			`m_thread = Scheduler::current();`

			`kernel_wait_for_event();`
			`}`

kernel/ATA: Read the PCI Busmaster registers and start preparing for DMA 2023-05-13 18:56:27 +02:00			`bool Channel::wait_for_irq_or_timeout(u64 timeout)`
			`{`
			`m_thread = Scheduler::current();`

			`kernel_sleep(timeout);`

kernel/ATA: Send a READ CAPACITY packet to an ATA drive on initialization 2023-05-13 22:18:44 +02:00			`return m_thread->sleep_ticks_left;`
kernel/ATA: Read the PCI Busmaster registers and start preparing for DMA 2023-05-13 18:56:27 +02:00			`}`

kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00			`bool Channel::wait_for_reg_set(Register reg, u8 value, u64 timeout)`
			`{`
			`u64 begin = Timer::ticks_ms();`
			`while (true)`
			`{`
			`u8 reg_value = read_register(reg);`
			`if (reg_value & value) return true;`
			`if ((Timer::ticks_ms() - begin) >= timeout) return false;`
			`kernel_sleep(1);`
			`}`
			`}`

			`bool Channel::wait_for_reg_clear(Register reg, u8 value, u64 timeout)`
			`{`
			`u64 begin = Timer::ticks_ms();`
			`while (true)`
			`{`
			`u8 reg_value = read_register(reg);`
			`if ((reg_value & value) == 0) return true;`
			`if ((Timer::ticks_ms() - begin) >= timeout) return false;`
			`kernel_sleep(1);`
			`}`
			`}`

kernel/ATA: Send a READ CAPACITY packet to an ATA drive on initialization 2023-05-13 22:18:44 +02:00			`Result<void> Channel::wait_until_ready()`
			`{`
			`if (!wait_for_reg_clear(Register::Status, SR_Busy, 1000))`
			`{`
			`kwarnln("ata: Drive %d:%d timed out (BSY)", m_channel_index, m_current_drive);`
			`return err(EIO);`
			`}`

			`if (!wait_for_reg_set(Register::Status, SR_DataRequestReady \| SR_Error, 1000))`
			`{`
			`kwarnln("ata: Drive %d:%d timed out (DRQ)", m_channel_index, m_current_drive);`
			`return err(EIO);`
			`}`

			`u8 status = read_register(Register::Status);`
			`if (status & SR_Error)`
			`{`
			`kwarnln("ata: An error occurred in drive %d:%d while waiting for data to become available", m_channel_index,`
			`m_current_drive);`
			`return err(EIO);`
			`}`

			`return {};`
			`}`

kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`bool Channel::initialize()`
			`{`
			`int offset = m_channel_index ? 2 : 0;`
			`m_is_pci_native_mode = m_controller->device().type.prog_if & (1 << offset);`
kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00
kernel: Handle device BARs properly 2023-05-13 17:54:02 +02:00			`u16 control_port_base_address;`
			`u16 io_base_address;`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00
			`if (m_is_pci_native_mode)`
			`{`
kernel: Handle device BARs properly 2023-05-13 17:54:02 +02:00			`auto io_base = m_controller->device().getBAR(m_channel_index ? 2 : 0);`
			`if (!io_base.is_iospace())`
			`{`
			`kwarnln("ata: Channel %d's IO base BAR is not in IO space", m_channel_index);`
			`return false;`
			`}`
			`io_base_address = io_base.port();`

			`auto io_control = m_controller->device().getBAR(m_channel_index ? 3 : 1);`
			`if (!io_control.is_iospace())`
			`{`
			`kwarnln("ata: Channel %d's control base BAR is not in IO space", m_channel_index);`
			`return false;`
			`}`

			`control_port_base_address = io_control.port();`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`}`
			`else`
			`{`
kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`io_base_address = m_channel_index ? 0x170 : 0x1f0;`
			`control_port_base_address = m_channel_index ? 0x376 : 0x3f6;`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`}`

kernel: Handle device BARs properly 2023-05-13 17:54:02 +02:00			`m_io_base = io_base_address;`
			`m_control_base = control_port_base_address + 2;`
kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00
kernel/ATA: Read the Busmaster base port and verify it 2023-05-13 18:12:34 +02:00			`auto io_busmaster = m_controller->device().getBAR(4);`
			`if (!io_busmaster.is_iospace())`
			`{`
			`kwarnln("ata: Channel %d's busmaster base BAR is not in IO space", m_channel_index);`
			`return false;`
			`}`
			`m_busmaster_base = io_busmaster.port() + (u16)(m_channel_index * 8u);`

kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`if (m_is_pci_native_mode) m_interrupt_line = PCI::read8(m_controller->device().address, PCI::InterruptLine);`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`else`
kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`m_interrupt_line = m_channel_index ? 15 : 14;`

kernel/ATA: Handle drive IRQs in compatibility mode 2023-05-13 14:24:45 +02:00			`bool ok = CPU::register_interrupt(m_interrupt_line, ::irq_handler, this);`
			`if (!ok)`
			`{`
			`kerrorln("ata: Failed to register IRQ handler for ATA channel %d (IRQ %d)", m_channel_index,`
			`m_interrupt_line);`
			`return false;`
			`}`

kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`for (u8 drive = 0; drive < 2; drive++)`
			`{`
			`ScopedKMutexLock<100> lock(m_lock);`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00
kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`select(drive);`

			`if (read_register(Register::Status) == 0)`
			`{`
			`// No drive on this slot.`
			`continue;`
			`}`

			`kinfoln("ata: Channel %d has a drive on slot %d!", m_channel_index, drive);`
kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00
			`auto rc = adopt_shared_if_nonnull(new (std::nothrow) Drive(this, drive, {}));`
			`if (rc.has_error())`
			`{`
			`kinfoln("ata: Failed to create drive object: %s", rc.error_string());`
			`return false;`
			`}`

			`m_drives[drive] = rc.release_value();`

			`if (!m_drives[drive]->initialize())`
			`{`
			`m_drives[drive] = {};`
			`return false;`
			`}`
			`}`

			`return true;`
			`}`

			`Drive::Drive(Channel* channel, u8 drive_index, Badge<Channel>) : m_channel(channel), m_drive_index(drive_index)`
			`{`
			`}`

			`bool Drive::identify_ata()`
			`{`
			`m_channel->write_register(Register::Command, m_is_atapi ? CMD_Identify_Packet : CMD_Identify);`

			`m_channel->delay_400ns();`

			`if (!m_channel->wait_for_reg_clear(Register::Status, SR_Busy, 1000))`
			`{`
			`kwarnln("ata: Drive %d timed out clearing SR_Busy (waited for 1000 ms)", m_drive_index);`
			`return false;`
			`}`

			`if (m_channel->read_register(Register::Status) & SR_Error)`
			`{`
			`u8 lbam = m_channel->read_register(Register::LBAMiddle);`
			`u8 lbah = m_channel->read_register(Register::LBAHigh);`

			`if ((lbam == 0x14 && lbah == 0xeb) \|\| (lbam == 0x69 && lbah == 0x96))`
			`{`
			`if (!m_is_atapi)`
			`{`
			`kinfoln("ata: Drive %d is ATAPI, sending IDENTIFY_PACKET command", m_drive_index);`
			`m_is_atapi = true;`
			`return identify_ata();`
			`}`
			`}`

			`kwarnln("ata: IDENTIFY command for drive %d returned error", m_drive_index);`

			`return false;`
			`}`

			`if (!m_channel->wait_for_reg_set(Register::Status, SR_DataRequestReady \| SR_Error, 1000))`
			`{`
			`kwarnln("ata: Drive %d timed out setting SR_DataRequestReady (waited for 1000 ms)", m_drive_index);`
			`return false;`
			`}`

			`u8 status = m_channel->read_register(Register::Status);`
			`if (status & SR_Error)`
			`{`
			`kwarnln("ata: IDENTIFY command for drive %d returned error", m_drive_index);`
			`return false;`
			`}`

			`for (usize i = 0; i < 256; i++)`
			`{`
			`u16 data = m_channel->read_data();`
			`m_identify_words[i] = data;`
kernel/ATA: Start reading/writing registers and detecting drives 2023-05-13 14:11:09 +02:00			`}`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00
			`return true;`
			`}`
kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00
			`bool Drive::initialize()`
			`{`
			`m_channel->select(m_drive_index);`

			`m_channel->write_register(Register::SectorCount, 0);`
			`m_channel->write_register(Register::LBALow, 0);`
			`m_channel->write_register(Register::LBAMiddle, 0);`
			`m_channel->write_register(Register::LBAHigh, 0);`

			`if (!identify_ata()) return false;`

kernel/ATA: Read ATA strings properly instead of backwards Now we can see the model string. What does it say... "QEMU DVD-ROM". Let's go! 2023-05-13 16:34:18 +02:00			`m_serial.set_length(copy_ata_string(m_serial.data(), &m_identify_words[10], SERIAL_LEN));`
			`m_revision.set_length(copy_ata_string(m_revision.data(), &m_identify_words[23], REVISION_LEN));`
			`m_model.set_length(copy_ata_string(m_model.data(), &m_identify_words[27], MODEL_LEN));`
kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00
			`m_serial.trim(" ");`
			`m_revision.trim(" ");`
			`m_model.trim(" ");`

			`kinfoln("ata: Drive IDENTIFY returned serial='%s', revision='%s' and model='%s'", m_serial.chars(),`
			`m_revision.chars(), m_model.chars());`

kernel/ATA: Read the PCI Busmaster registers and start preparing for DMA 2023-05-13 18:56:27 +02:00			`auto status = m_channel->read_bm(BusmasterRegister::Status);`
			`if (status & BMS_SimplexOnly)`
			`{`
			`kwarnln("ata: Drive %d will not use DMA because of simplex shenanigans", m_drive_index);`
			`m_uses_dma = false;`
			`}`

			`auto frame = MemoryManager::alloc_frame();`
			`if (frame.has_error() \|\| frame.value() > 0xffffffff)`
			`{`
			`kwarnln("ata: Failed to allocate memory below the 32-bit limit for the PRDT");`
			`return false;`
			`}`
			`m_dma_prdt_phys = frame.release_value();`
			`m_dma_prdt = (prdt_entry*)MMU::translate_physical_address(m_dma_prdt_phys);`

			`frame = MemoryManager::alloc_frame();`
			`if (frame.has_error() \|\| frame.value() > 0xffffffff)`
			`{`
			`kwarnln("ata: Failed to allocate memory below the 32-bit limit for DMA memory");`
			`return false;`
			`}`
			`m_dma_mem_phys = frame.release_value();`
			`m_dma_mem = (void*)MMU::translate_physical_address(m_dma_mem_phys);`

kernel/ATA: Send a READ CAPACITY packet to an ATA drive on initialization 2023-05-13 22:18:44 +02:00			`if (m_is_atapi)`
			`{`
			`atapi_packet packet;`
			`memset(&packet, 0, sizeof(packet));`
			`packet.command_bytes[0] = ATAPI_ReadCapacity;`

			`atapi_read_capacity_reply reply;`

			`if (send_packet_atapi_pio(&packet, &reply, sizeof(reply)).has_error())`
			`{`
			`kwarnln("ata: Failed to send Read Capacity command to ATAPI drive");`
			`return false;`
			`}`

			`// FIXME: This assumes the host machine is little-endian.`
			`u32 last_lba = __builtin_bswap32(reply.last_lba);`
			`u32 sector_size = __builtin_bswap32(reply.sector_size);`

			`kinfoln("ata: ATAPI drive %d capacity information: Last LBA=%u, Sector Size=%u, Total Capacity=%u",`
			`m_drive_index, last_lba, sector_size, (last_lba + 1) * sector_size);`
			`}`

kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00			`return true;`
			`}`

kernel/ATA: Send a READ CAPACITY packet to an ATA drive on initialization 2023-05-13 22:18:44 +02:00			`Result<void> Drive::send_packet_atapi_pio(const atapi_packet* packet, void* out, u16 response_size)`
			`{`
			`u8* ptr = (u8*)out;`

			`m_channel->select(m_drive_index);`

			`// We use PIO here.`
			`m_channel->write_register(Register::Features, 0x00);`

			`m_channel->write_register(Register::LBAMiddle, (u8)(response_size & 0xff));`
			`m_channel->write_register(Register::LBAHigh, (u8)(response_size >> 8));`

			`m_channel->write_register(Register::Command, CMD_Packet);`

			`m_channel->delay_400ns();`

			`usize i = 0;`

			`TRY(m_channel->wait_until_ready());`

			`for (int j = 0; j < 6; j++) m_channel->write_data(packet->command_words[j]);`

			`while (i < response_size)`
			`{`
			`TRY(m_channel->wait_until_ready());`

			`usize byte_count =`
			`m_channel->read_register(Register::LBAHigh) << 8 \| m_channel->read_register(Register::LBAMiddle);`
			`usize word_count = byte_count / 2;`

			`while (word_count--)`
			`{`
			`u16 value = m_channel->read_data();`
			`ptr[0] = (u8)(value & 0xff);`
			`ptr[1] = (u8)(value >> 8);`
			`ptr += 2;`
			`}`

			`i += byte_count;`
			`}`

			`return {};`
			`}`

kernel/ATA: Implement enough to send an IDENTIFY command and read the model number :) 2023-05-13 16:13:26 +02:00			`void Drive::irq_handler()`
			`{`
			`// Clear the IRQ flag.`
			`u8 status = m_channel->read_register(Register::Status);`

			`if (status & SR_Error)`
			`{`
			`u8 error = m_channel->read_register(Register::Error);`
			`(void)error;`
			`}`
			`}`
kernel/x86_64: Add basic ATA controller and channel identification 2023-05-10 19:15:47 +02:00			`}`