ladybird/Kernel/PCI/MMIOAccess.cpp
Andreas Kling 9c856811b2 Kernel: Add Region helpers for accessing underlying physical pages
Since a Region is basically a view into a potentially larger VMObject,
it was always necessary to include the Region starting offset when
accessing its underlying physical pages.

Until now, you had to do that manually, but this patch adds a simple
Region::physical_page() for read-only access and a physical_page_slot()
when you want a mutable reference to the RefPtr<PhysicalPage> itself.

A lot of code is simplified by making use of this.
2020-04-28 17:05:14 +02:00

262 lines
10 KiB
C++

/*
* Copyright (c) 2020, Liav A. <liavalb@hotmail.co.il>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <AK/Optional.h>
#include <AK/StringView.h>
#include <Kernel/PCI/MMIOAccess.h>
#include <Kernel/VM/MemoryManager.h>
namespace Kernel {
namespace PCI {
class MMIOSegment {
public:
MMIOSegment(PhysicalAddress, u8, u8);
u8 get_start_bus();
u8 get_end_bus();
size_t get_size();
PhysicalAddress get_paddr();
private:
PhysicalAddress m_base_addr;
u8 m_start_bus;
u8 m_end_bus;
};
#define PCI_MMIO_CONFIG_SPACE_SIZE 4096
uint32_t MMIOAccess::segment_count() const
{
return m_segments.size();
}
uint8_t MMIOAccess::segment_start_bus(u32 seg) const
{
auto segment = m_segments.get(seg);
ASSERT(segment.has_value());
return segment.value().get_start_bus();
}
uint8_t MMIOAccess::segment_end_bus(u32 seg) const
{
auto segment = m_segments.get(seg);
ASSERT(segment.has_value());
return segment.value().get_end_bus();
}
void MMIOAccess::initialize(PhysicalAddress mcfg)
{
if (!Access::is_initialized())
new MMIOAccess(mcfg);
}
MMIOAccess::MMIOAccess(PhysicalAddress p_mcfg)
: m_mcfg(p_mcfg)
, m_mapped_address(ChangeableAddress(0xFFFF, 0xFF, 0xFF, 0xFF))
{
klog() << "PCI: Using MMIO for PCI configuration space access";
m_mmio_window_region = MM.allocate_kernel_region(PAGE_ROUND_UP(PCI_MMIO_CONFIG_SPACE_SIZE), "PCI MMIO", Region::Access::Read | Region::Access::Write);
auto checkup_region = MM.allocate_kernel_region(p_mcfg.page_base(), (PAGE_SIZE * 2), "PCI MCFG Checkup", Region::Access::Read | Region::Access::Write);
#ifdef PCI_DEBUG
dbg() << "PCI: Checking MCFG Table length to choose the correct mapping size";
#endif
auto* sdt = (ACPI::Structures::SDTHeader*)checkup_region->vaddr().offset(p_mcfg.offset_in_page()).as_ptr();
u32 length = sdt->length;
u8 revision = sdt->revision;
klog() << "PCI: MCFG, length - " << length << ", revision " << revision;
checkup_region->unmap();
auto mcfg_region = MM.allocate_kernel_region(p_mcfg.page_base(), PAGE_ROUND_UP(length) + PAGE_SIZE, "PCI Parsing MCFG", Region::Access::Read | Region::Access::Write);
auto& mcfg = *(ACPI::Structures::MCFG*)mcfg_region->vaddr().offset(p_mcfg.offset_in_page()).as_ptr();
#ifdef PCI_DEBUG
dbg() << "PCI: Checking MCFG @ V " << &mcfg << ", P 0x" << String::format("%x", p_mcfg.get());
#endif
for (u32 index = 0; index < ((mcfg.header.length - sizeof(ACPI::Structures::MCFG)) / sizeof(ACPI::Structures::PCI_MMIO_Descriptor)); index++) {
u8 start_bus = mcfg.descriptors[index].start_pci_bus;
u8 end_bus = mcfg.descriptors[index].end_pci_bus;
u32 lower_addr = mcfg.descriptors[index].base_addr;
m_segments.set(index, { PhysicalAddress(lower_addr), start_bus, end_bus });
klog() << "PCI: New PCI segment @ " << PhysicalAddress(lower_addr) << ", PCI buses (" << start_bus << "-" << end_bus << ")";
}
mcfg_region->unmap();
klog() << "PCI: MMIO segments - " << m_segments.size();
InterruptDisabler disabler;
#ifdef PCI_DEBUG
dbg() << "PCI: mapped address (" << String::format("%w", m_mapped_address.seg()) << ":" << String::format("%b", m_mapped_address.bus()) << ":" << String::format("%b", m_mapped_address.slot()) << "." << String::format("%b", m_mapped_address.function()) << ")";
#endif
map_device(Address(0, 0, 0, 0));
#ifdef PCI_DEBUG
dbg() << "PCI: Default mapped address (" << String::format("%w", m_mapped_address.seg()) << ":" << String::format("%b", m_mapped_address.bus()) << ":" << String::format("%b", m_mapped_address.slot()) << "." << String::format("%b", m_mapped_address.function()) << ")";
#endif
enumerate_hardware([&](const Address& address, ID id) {
m_physical_ids.append({ address, id });
});
}
void MMIOAccess::map_device(Address address)
{
if (m_mapped_address == address)
return;
// FIXME: Map and put some lock!
ASSERT_INTERRUPTS_DISABLED();
auto segment = m_segments.get(address.seg());
ASSERT(segment.has_value());
PhysicalAddress segment_lower_addr = segment.value().get_paddr();
PhysicalAddress device_physical_mmio_space = segment_lower_addr.offset(
PCI_MMIO_CONFIG_SPACE_SIZE * address.function() + (PCI_MMIO_CONFIG_SPACE_SIZE * PCI_MAX_FUNCTIONS_PER_DEVICE) * address.slot() + (PCI_MMIO_CONFIG_SPACE_SIZE * PCI_MAX_FUNCTIONS_PER_DEVICE * PCI_MAX_DEVICES_PER_BUS) * (address.bus() - segment.value().get_start_bus()));
#ifdef PCI_DEBUG
dbg() << "PCI: Mapping device @ pci (" << String::format("%w", address.seg()) << ":" << String::format("%b", address.bus()) << ":" << String::format("%b", address.slot()) << "." << String::format("%b", address.function()) << ")"
<< " V 0x" << String::format("%x", m_mmio_window_region->vaddr().get()) << " P 0x" << String::format("%x", device_physical_mmio_space.get());
#endif
m_mmio_window_region->physical_page_slot(0) = PhysicalPage::create(device_physical_mmio_space, false, false);
m_mmio_window_region->remap();
m_mapped_address = address;
}
u8 MMIOAccess::read8_field(Address address, u32 field)
{
InterruptDisabler disabler;
ASSERT(field <= 0xfff);
#ifdef PCI_DEBUG
dbg() << "PCI: Reading field " << field << ", Address(" << String::format("%w", address.seg()) << ":" << String::format("%b", address.bus()) << ":" << String::format("%b", address.slot()) << "." << String::format("%b", address.function()) << ")";
#endif
map_device(address);
return *((u8*)(m_mmio_window_region->vaddr().get() + (field & 0xfff)));
}
u16 MMIOAccess::read16_field(Address address, u32 field)
{
InterruptDisabler disabler;
ASSERT(field < 0xfff);
#ifdef PCI_DEBUG
dbg() << "PCI: Reading field " << field << ", Address(" << String::format("%w", address.seg()) << ":" << String::format("%b", address.bus()) << ":" << String::format("%b", address.slot()) << "." << String::format("%b", address.function()) << ")";
#endif
map_device(address);
return *((u16*)(m_mmio_window_region->vaddr().get() + (field & 0xfff)));
}
u32 MMIOAccess::read32_field(Address address, u32 field)
{
InterruptDisabler disabler;
ASSERT(field <= 0xffc);
#ifdef PCI_DEBUG
dbg() << "PCI: Reading field " << field << ", Address(" << String::format("%w", address.seg()) << ":" << String::format("%b", address.bus()) << ":" << String::format("%b", address.slot()) << "." << String::format("%b", address.function()) << ")";
#endif
map_device(address);
return *((u32*)(m_mmio_window_region->vaddr().get() + (field & 0xfff)));
}
void MMIOAccess::write8_field(Address address, u32 field, u8 value)
{
InterruptDisabler disabler;
ASSERT(field <= 0xfff);
#ifdef PCI_DEBUG
dbg() << "PCI: Writing to field " << field << ", Address(" << String::format("%w", address.seg()) << ":" << String::format("%b", address.bus()) << ":" << String::format("%b", address.slot()) << "." << String::format("%b", address.function()) << ") value 0x" << String::format("%x", value);
#endif
map_device(address);
*((u8*)(m_mmio_window_region->vaddr().get() + (field & 0xfff))) = value;
}
void MMIOAccess::write16_field(Address address, u32 field, u16 value)
{
InterruptDisabler disabler;
ASSERT(field < 0xfff);
#ifdef PCI_DEBUG
dbg() << "PCI: Writing to field " << field << ", Address(" << String::format("%w", address.seg()) << ":" << String::format("%b", address.bus()) << ":" << String::format("%b", address.slot()) << "." << String::format("%b", address.function()) << ") value 0x" << String::format("%x", value);
#endif
map_device(address);
*((u16*)(m_mmio_window_region->vaddr().get() + (field & 0xfff))) = value;
}
void MMIOAccess::write32_field(Address address, u32 field, u32 value)
{
InterruptDisabler disabler;
ASSERT(field <= 0xffc);
#ifdef PCI_DEBUG
dbg() << "PCI: Writing to field " << field << ", Address(" << String::format("%w", address.seg()) << ":" << String::format("%b", address.bus()) << ":" << String::format("%b", address.slot()) << "." << String::format("%b", address.function()) << ") value 0x" << String::format("%x", value);
#endif
map_device(address);
*((u32*)(m_mmio_window_region->vaddr().get() + (field & 0xfff))) = value;
}
void MMIOAccess::enumerate_hardware(Function<void(Address, ID)> callback)
{
for (u16 seg = 0; seg < m_segments.size(); seg++) {
#ifdef PCI_DEBUG
dbg() << "PCI: Enumerating Memory mapped IO segment " << seg;
#endif
// Single PCI host controller.
if ((read8_field(Address(seg), PCI_HEADER_TYPE) & 0x80) == 0) {
enumerate_bus(-1, 0, callback);
return;
}
// Multiple PCI host controllers.
for (u8 function = 0; function < 8; ++function) {
if (read16_field(Address(seg, 0, 0, function), PCI_VENDOR_ID) == PCI_NONE)
break;
enumerate_bus(-1, function, callback);
}
}
}
MMIOSegment::MMIOSegment(PhysicalAddress segment_base_addr, u8 start_bus, u8 end_bus)
: m_base_addr(segment_base_addr)
, m_start_bus(start_bus)
, m_end_bus(end_bus)
{
}
u8 MMIOSegment::get_start_bus()
{
return m_start_bus;
}
u8 MMIOSegment::get_end_bus()
{
return m_end_bus;
}
size_t MMIOSegment::get_size()
{
return (PCI_MMIO_CONFIG_SPACE_SIZE * PCI_MAX_FUNCTIONS_PER_DEVICE * PCI_MAX_DEVICES_PER_BUS * (get_end_bus() - get_start_bus()));
}
PhysicalAddress MMIOSegment::get_paddr()
{
return m_base_addr;
}
}
}