ladybird/Kernel/VirtIO/VirtIO.cpp
Sahan Fernando cbc845c8a8 Kernel: Reorder VirtIODevice PCI initialization steps
We can't reset the device before we've read the PCI configuration
space, because we read the reset register location from the
configuration space.
2021-05-15 23:29:03 +01:00

377 lines
13 KiB
C++

/*
* Copyright (c) 2021, the SerenityOS developers.
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <Kernel/CommandLine.h>
#include <Kernel/PCI/IDs.h>
#include <Kernel/VirtIO/VirtIO.h>
#include <Kernel/VirtIO/VirtIOConsole.h>
#include <Kernel/VirtIO/VirtIORNG.h>
namespace Kernel {
void VirtIO::detect()
{
if (kernel_command_line().disable_virtio())
return;
PCI::enumerate([&](const PCI::Address& address, PCI::ID id) {
if (address.is_null() || id.is_null())
return;
if (id.vendor_id != (u16)PCIVendorID::VirtIO)
return;
switch (id.device_id) {
case (u16)PCIDeviceID::VirtIOConsole: {
[[maybe_unused]] auto& unused = adopt_ref(*new VirtIOConsole(address)).leak_ref();
break;
}
case (u16)PCIDeviceID::VirtIOEntropy: {
[[maybe_unused]] auto& unused = adopt_ref(*new VirtIORNG(address)).leak_ref();
break;
}
default:
dbgln_if(VIRTIO_DEBUG, "VirtIO: Unknown VirtIO device with ID: {}", id.device_id);
break;
}
});
}
VirtIODevice::VirtIODevice(PCI::Address address, String class_name)
: PCI::Device(address, PCI::get_interrupt_line(address))
, m_class_name(move(class_name))
, m_io_base(IOAddress(PCI::get_BAR0(pci_address()) & ~1))
{
dbgln("{}: Found @ {}", m_class_name, pci_address());
enable_bus_mastering(pci_address());
PCI::enable_interrupt_line(pci_address());
enable_irq();
auto capabilities = PCI::get_physical_id(address).capabilities();
for (auto& capability : capabilities) {
if (capability.id() == PCI_CAPABILITY_VENDOR_SPECIFIC) {
// We have a virtio_pci_cap
auto cfg = make<Configuration>();
auto raw_config_type = capability.read8(0x3);
if (raw_config_type < static_cast<u8>(ConfigurationType::Common) || raw_config_type > static_cast<u8>(ConfigurationType::PCI)) {
dbgln("{}: Unknown capability configuration type: {}", m_class_name, raw_config_type);
return;
}
cfg->cfg_type = static_cast<ConfigurationType>(raw_config_type);
auto cap_length = capability.read8(0x2);
if (cap_length < 0x10) {
dbgln("{}: Unexpected capability size: {}", m_class_name, cap_length);
break;
}
cfg->bar = capability.read8(0x4);
if (cfg->bar > 0x5) {
dbgln("{}: Unexpected capability bar value: {}", m_class_name, cfg->bar);
break;
}
cfg->offset = capability.read32(0x8);
cfg->length = capability.read32(0xc);
dbgln_if(VIRTIO_DEBUG, "{}: Found configuration {}, bar: {}, offset: {}, length: {}", m_class_name, (u32)cfg->cfg_type, cfg->bar, cfg->offset, cfg->length);
if (cfg->cfg_type == ConfigurationType::Common)
m_use_mmio = true;
else if (cfg->cfg_type == ConfigurationType::Notify)
m_notify_multiplier = capability.read32(0x10);
m_configs.append(move(cfg));
}
}
if (m_use_mmio) {
m_common_cfg = get_config(ConfigurationType::Common, 0);
m_notify_cfg = get_config(ConfigurationType::Notify, 0);
m_isr_cfg = get_config(ConfigurationType::ISR, 0);
}
reset_device();
set_status_bit(DEVICE_STATUS_ACKNOWLEDGE);
set_status_bit(DEVICE_STATUS_DRIVER);
}
VirtIODevice::~VirtIODevice()
{
}
auto VirtIODevice::mapping_for_bar(u8 bar) -> MappedMMIO&
{
VERIFY(m_use_mmio);
auto& mapping = m_mmio[bar];
if (!mapping.base) {
mapping.size = PCI::get_BAR_space_size(pci_address(), bar);
mapping.base = MM.allocate_kernel_region(PhysicalAddress(page_base_of(PCI::get_BAR(pci_address(), bar))), page_round_up(mapping.size), "VirtIO MMIO", Region::Access::Read | Region::Access::Write, Region::Cacheable::No);
if (!mapping.base)
dbgln("{}: Failed to map bar {}", m_class_name, bar);
}
return mapping;
}
void VirtIODevice::notify_queue(u16 queue_index)
{
dbgln_if(VIRTIO_DEBUG, "{}: notifying about queue change at idx: {}", m_class_name, queue_index);
if (!m_notify_cfg)
out<u16>(REG_QUEUE_NOTIFY, queue_index);
else
config_write16(*m_notify_cfg, get_queue(queue_index).notify_offset() * m_notify_multiplier, queue_index);
}
u8 VirtIODevice::config_read8(const Configuration& config, u32 offset)
{
return mapping_for_bar(config.bar).read<u8>(config.offset + offset);
}
u16 VirtIODevice::config_read16(const Configuration& config, u32 offset)
{
return mapping_for_bar(config.bar).read<u16>(config.offset + offset);
}
u32 VirtIODevice::config_read32(const Configuration& config, u32 offset)
{
return mapping_for_bar(config.bar).read<u32>(config.offset + offset);
}
void VirtIODevice::config_write8(const Configuration& config, u32 offset, u8 value)
{
mapping_for_bar(config.bar).write(config.offset + offset, value);
}
void VirtIODevice::config_write16(const Configuration& config, u32 offset, u16 value)
{
mapping_for_bar(config.bar).write(config.offset + offset, value);
}
void VirtIODevice::config_write32(const Configuration& config, u32 offset, u32 value)
{
mapping_for_bar(config.bar).write(config.offset + offset, value);
}
void VirtIODevice::config_write64(const Configuration& config, u32 offset, u64 value)
{
mapping_for_bar(config.bar).write(config.offset + offset, value);
}
u8 VirtIODevice::read_status_bits()
{
if (!m_common_cfg)
return in<u8>(REG_DEVICE_STATUS);
return config_read8(*m_common_cfg, COMMON_CFG_DEVICE_STATUS);
}
void VirtIODevice::mask_status_bits(u8 status_mask)
{
m_status &= status_mask;
if (!m_common_cfg)
out<u8>(REG_DEVICE_STATUS, m_status);
else
config_write8(*m_common_cfg, COMMON_CFG_DEVICE_STATUS, m_status);
}
void VirtIODevice::set_status_bit(u8 status_bit)
{
m_status |= status_bit;
if (!m_common_cfg)
out<u8>(REG_DEVICE_STATUS, m_status);
else
config_write8(*m_common_cfg, COMMON_CFG_DEVICE_STATUS, m_status);
}
u64 VirtIODevice::get_device_features()
{
if (!m_common_cfg)
return in<u32>(REG_DEVICE_FEATURES);
config_write32(*m_common_cfg, COMMON_CFG_DEVICE_FEATURE_SELECT, 0);
auto lower_bits = config_read32(*m_common_cfg, COMMON_CFG_DEVICE_FEATURE);
config_write32(*m_common_cfg, COMMON_CFG_DEVICE_FEATURE_SELECT, 1);
u64 upper_bits = (u64)config_read32(*m_common_cfg, COMMON_CFG_DEVICE_FEATURE) << 32;
return upper_bits | lower_bits;
}
bool VirtIODevice::accept_device_features(u64 device_features, u64 accepted_features)
{
VERIFY(!m_did_accept_features);
m_did_accept_features = true;
if (is_feature_set(device_features, VIRTIO_F_VERSION_1)) {
accepted_features |= VIRTIO_F_VERSION_1; // let the device know were not a legacy driver
}
if (is_feature_set(device_features, VIRTIO_F_RING_PACKED)) {
dbgln_if(VIRTIO_DEBUG, "{}: packed queues not yet supported", m_class_name);
accepted_features &= ~(VIRTIO_F_RING_PACKED);
}
// TODO: implement indirect descriptors to allow queue_size buffers instead of buffers totalling (PAGE_SIZE * queue_size) bytes
if (is_feature_set(device_features, VIRTIO_F_INDIRECT_DESC)) {
// accepted_features |= VIRTIO_F_INDIRECT_DESC;
}
if (is_feature_set(device_features, VIRTIO_F_IN_ORDER)) {
accepted_features |= VIRTIO_F_IN_ORDER;
}
dbgln_if(VIRTIO_DEBUG, "{}: Device features: {}", m_class_name, device_features);
dbgln_if(VIRTIO_DEBUG, "{}: Accepted features: {}", m_class_name, accepted_features);
if (!m_common_cfg) {
out<u32>(REG_GUEST_FEATURES, accepted_features);
} else {
config_write32(*m_common_cfg, COMMON_CFG_DRIVER_FEATURE_SELECT, 0);
config_write32(*m_common_cfg, COMMON_CFG_DRIVER_FEATURE, accepted_features);
config_write32(*m_common_cfg, COMMON_CFG_DRIVER_FEATURE_SELECT, 1);
config_write32(*m_common_cfg, COMMON_CFG_DRIVER_FEATURE, accepted_features >> 32);
}
set_status_bit(DEVICE_STATUS_FEATURES_OK);
m_status = read_status_bits();
if (!(m_status & DEVICE_STATUS_FEATURES_OK)) {
set_status_bit(DEVICE_STATUS_FAILED);
dbgln("{}: Features not accepted by host!", m_class_name);
return false;
}
m_accepted_features = accepted_features;
dbgln_if(VIRTIO_DEBUG, "{}: Features accepted by host", m_class_name);
return true;
}
void VirtIODevice::reset_device()
{
dbgln_if(VIRTIO_DEBUG, "{}: Reset device", m_class_name);
if (!m_common_cfg) {
mask_status_bits(0);
while (read_status_bits() != 0) {
// TODO: delay a bit?
}
return;
}
config_write8(*m_common_cfg, COMMON_CFG_DEVICE_STATUS, 0);
while (config_read8(*m_common_cfg, COMMON_CFG_DEVICE_STATUS) != 0) {
// TODO: delay a bit?
}
}
bool VirtIODevice::setup_queue(u16 queue_index)
{
if (!m_common_cfg)
return false;
config_write16(*m_common_cfg, COMMON_CFG_QUEUE_SELECT, queue_index);
u16 queue_size = config_read16(*m_common_cfg, COMMON_CFG_QUEUE_SIZE);
if (queue_size == 0) {
dbgln_if(VIRTIO_DEBUG, "{}: Queue[{}] is unavailable!", m_class_name, queue_index);
return true;
}
u16 queue_notify_offset = config_read16(*m_common_cfg, COMMON_CFG_QUEUE_NOTIFY_OFF);
auto queue = make<VirtIOQueue>(queue_size, queue_notify_offset);
if (queue->is_null())
return false;
config_write64(*m_common_cfg, COMMON_CFG_QUEUE_DESC, queue->descriptor_area().get());
config_write64(*m_common_cfg, COMMON_CFG_QUEUE_DRIVER, queue->driver_area().get());
config_write64(*m_common_cfg, COMMON_CFG_QUEUE_DEVICE, queue->device_area().get());
dbgln_if(VIRTIO_DEBUG, "{}: Queue[{}] configured with size: {}", m_class_name, queue_index, queue_size);
m_queues.append(move(queue));
return true;
}
bool VirtIODevice::activate_queue(u16 queue_index)
{
if (!m_common_cfg)
return false;
config_write16(*m_common_cfg, COMMON_CFG_QUEUE_SELECT, queue_index);
config_write16(*m_common_cfg, COMMON_CFG_QUEUE_ENABLE, true);
dbgln_if(VIRTIO_DEBUG, "{}: Queue[{}] activated", m_class_name, queue_index);
return true;
}
bool VirtIODevice::setup_queues(u16 requested_queue_count)
{
VERIFY(!m_did_setup_queues);
m_did_setup_queues = true;
if (m_common_cfg) {
auto maximum_queue_count = config_read16(*m_common_cfg, COMMON_CFG_NUM_QUEUES);
if (requested_queue_count == 0) {
m_queue_count = maximum_queue_count;
} else if (requested_queue_count > maximum_queue_count) {
dbgln("{}: {} queues requested but only {} available!", m_class_name, m_queue_count, maximum_queue_count);
return false;
} else {
m_queue_count = requested_queue_count;
}
} else {
m_queue_count = requested_queue_count;
dbgln("{}: device's available queue count could not be determined!", m_class_name);
}
dbgln_if(VIRTIO_DEBUG, "{}: Setting up {} queues", m_class_name, m_queue_count);
for (u16 i = 0; i < m_queue_count; i++) {
if (!setup_queue(i))
return false;
}
for (u16 i = 0; i < m_queue_count; i++) { // Queues can only be activated *after* all others queues were also configured
if (!activate_queue(i))
return false;
}
return true;
}
void VirtIODevice::finish_init()
{
VERIFY(m_did_accept_features); // ensure features were negotiated
VERIFY(m_did_setup_queues); // ensure queues were set-up
VERIFY(!(m_status & DEVICE_STATUS_DRIVER_OK)); // ensure we didn't already finish the initialization
set_status_bit(DEVICE_STATUS_DRIVER_OK);
dbgln_if(VIRTIO_DEBUG, "{}: Finished initialization", m_class_name);
}
u8 VirtIODevice::isr_status()
{
if (!m_isr_cfg)
return in<u8>(REG_ISR_STATUS);
return config_read8(*m_isr_cfg, 0);
}
void VirtIODevice::handle_irq(const RegisterState&)
{
u8 isr_type = isr_status();
if (isr_type & DEVICE_CONFIG_INTERRUPT) {
dbgln_if(VIRTIO_DEBUG, "{}: VirtIO Device config interrupt!", m_class_name);
if (!handle_device_config_change()) {
set_status_bit(DEVICE_STATUS_FAILED);
dbgln("{}: Failed to handle device config change!", m_class_name);
}
}
if (isr_type & QUEUE_INTERRUPT) {
dbgln_if(VIRTIO_DEBUG, "{}: VirtIO Queue interrupt!", m_class_name);
for (size_t i = 0; i < m_queues.size(); i++) {
if (get_queue(i).new_data_available())
return handle_queue_update(i);
}
dbgln_if(VIRTIO_DEBUG, "{}: Got queue interrupt but all queues are up to date!", m_class_name);
}
if (isr_type & ~(QUEUE_INTERRUPT | DEVICE_CONFIG_INTERRUPT))
dbgln("{}: Handling interrupt with unknown type: {}", m_class_name, isr_type);
}
void VirtIODevice::supply_chain_and_notify(u16 queue_index, VirtIOQueueChain& chain)
{
auto& queue = get_queue(queue_index);
VERIFY(&chain.queue() == &queue);
VERIFY(queue.lock().is_locked());
chain.submit_to_queue();
if (queue.should_notify())
notify_queue(queue_index);
}
}