Kernel: AML tries to initialize processors when entering ACPI mode

I had forgotten that Processors used to be a different definition
in AML.

I also implemented reads/writes for FieldElement/IndexFieldElement
that fit in 64 bits. Reads and writes to buffer are still a TODO.
This commit is contained in:
Bananymous 2024-04-10 21:11:47 +03:00
parent 3f2e110eab
commit 0184e5beb5
6 changed files with 451 additions and 296 deletions

View File

@ -12,6 +12,7 @@ set(KERNEL_SOURCES
font/prefs.psf.o
kernel/ACPI/ACPI.cpp
kernel/ACPI/AML.cpp
kernel/ACPI/AML/Device.cpp
kernel/ACPI/AML/Field.cpp
kernel/ACPI/AML/NamedObject.cpp
kernel/ACPI/AML/Namespace.cpp

View File

@ -36,71 +36,6 @@ namespace Kernel::ACPI::AML
return device->enter_context_and_parse_term_list(context, name_string.value(), device_pkg.value());
}
void initialize()
{
bool run_ini = true;
bool init_children = true;
auto _sta = Namespace::root_namespace()->find_object(scope, NameString("_STA"sv));
if (_sta && _sta->type == Node::Type::Method)
{
auto* method = static_cast<Method*>(_sta.ptr());
if (method->arg_count != 0)
{
AML_ERROR("Method {}._STA has {} arguments, expected 0", scope, method->arg_count);
return;
}
auto result = method->evaluate({});
if (!result.has_value())
{
AML_ERROR("Failed to evaluate {}._STA", scope);
return;
}
if (!result.value())
{
AML_ERROR("Failed to evaluate {}._STA, return value is null", scope);
return;
}
auto result_val = result.value()->as_integer();
if (!result_val.has_value())
{
AML_ERROR("Failed to evaluate {}._STA, return value could not be resolved to integer", scope);
AML_ERROR(" Return value: ");
result.value()->debug_print(0);
return;
}
run_ini = (result_val.value() & 0x01);
init_children = run_ini || (result_val.value() & 0x02);
}
if (run_ini)
{
auto _ini = Namespace::root_namespace()->find_object(scope, NameString("_INI"sv));
if (_ini && _ini->type == Node::Type::Method)
{
auto* method = static_cast<Method*>(_ini.ptr());
if (method->arg_count != 0)
{
AML_ERROR("Method {}._INI has {} arguments, expected 0", scope, method->arg_count);
return;
}
method->evaluate({});
}
}
if (init_children)
{
for (auto& [_, child] : objects)
{
if (child->type == Node::Type::Device)
{
auto* device = static_cast<Device*>(child.ptr());
device->initialize();
}
}
}
}
virtual void debug_print(int indent) const override
{
AML_DEBUG_PRINT_INDENT(indent);
@ -117,4 +52,6 @@ namespace Kernel::ACPI::AML
}
};
bool initialize_device(BAN::RefPtr<NamedObject> device);
}

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@ -40,13 +40,13 @@ namespace Kernel::ACPI::AML
struct FieldElement : public NamedObject
{
uint64_t bit_offset;
uint32_t bit_count;
uint64_t bit_count;
FieldRules access_rules;
BAN::RefPtr<OpRegion> op_region = nullptr;
BAN::RefPtr<OpRegion> op_region;
FieldElement(NameSeg name, uint64_t bit_offset, uint32_t bit_count, FieldRules access_rules)
FieldElement(NameSeg name, uint64_t bit_offset, uint64_t bit_count, FieldRules access_rules)
: NamedObject(Node::Type::FieldElement, name)
, bit_offset(bit_offset)
, bit_count(bit_count)
@ -59,16 +59,10 @@ namespace Kernel::ACPI::AML
void debug_print(int indent) const override;
private:
struct AccessType
{
uint64_t offset;
uint64_t mask;
uint32_t access_size;
uint32_t shift;
};
BAN::Optional<AccessType> determine_access_type() const;
BAN::Optional<uint64_t> read_field(uint64_t offset, uint32_t access_size) const;
bool write_field(uint64_t offset, uint32_t access_size, uint64_t value) const;
BAN::Optional<uint64_t> evaluate_internal();
bool store_internal(uint64_t value);
friend struct IndexFieldElement;
};
struct Field
@ -79,20 +73,23 @@ namespace Kernel::ACPI::AML
struct IndexFieldElement : public NamedObject
{
uint64_t bit_offset;
uint32_t bit_count;
uint64_t bit_count;
FieldRules access_rules;
BAN::RefPtr<FieldElement> index_element = nullptr;
BAN::RefPtr<FieldElement> data_element = nullptr;
BAN::RefPtr<FieldElement> index_element;
BAN::RefPtr<FieldElement> data_element;
IndexFieldElement(NameSeg name, uint64_t bit_offset, uint32_t bit_count, FieldRules access_rules)
IndexFieldElement(NameSeg name, uint64_t bit_offset, uint64_t bit_count, FieldRules access_rules)
: NamedObject(Node::Type::IndexFieldElement, name)
, bit_offset(bit_offset)
, bit_count(bit_count)
, access_rules(access_rules)
{}
BAN::RefPtr<Node> evaluate() override;
bool store(BAN::RefPtr<Node> source) override;
void debug_print(int indent) const override;
};

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@ -406,13 +406,8 @@ namespace Kernel::ACPI
{
auto* scope = static_cast<AML::Scope*>(_sb.ptr());
for (auto& [name, object] : scope->objects)
{
if (object->type == AML::Node::Type::Device)
{
auto* device = static_cast<AML::Device*>(object.ptr());
device->initialize();
}
}
if (object->type == AML::Node::Type::Device || object->type == AML::Node::Type::Processor)
AML::initialize_device(object);
}
// Evaluate \\_PIC (mode)

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@ -0,0 +1,71 @@
#include <kernel/ACPI/AML/Device.h>
namespace Kernel::ACPI
{
bool AML::initialize_device(BAN::RefPtr<AML::NamedObject> device)
{
bool run_ini = true;
bool init_children = true;
ASSERT(device->type == Node::Type::Device || device->type == Node::Type::Processor);
ASSERT(device->is_scope());
auto* scope = static_cast<Scope*>(device.ptr());
auto it = scope->objects.find(NameSeg("_STA"sv));
if (it != scope->objects.end() && it->value->type == Node::Type::Method)
{
auto* method = static_cast<Method*>(it->value.ptr());
if (method->arg_count != 0)
{
AML_ERROR("Method {}._STA has {} arguments, expected 0", scope, method->arg_count);
return false;
}
auto result = method->evaluate({});
if (!result.has_value())
{
AML_ERROR("Failed to evaluate {}._STA", scope);
return false;
}
if (!result.value())
{
AML_ERROR("Failed to evaluate {}._STA, return value is null", scope);
return false;
}
auto result_val = result.value()->as_integer();
if (!result_val.has_value())
{
AML_ERROR("Failed to evaluate {}._STA, return value could not be resolved to integer", scope);
AML_ERROR(" Return value: ");
result.value()->debug_print(0);
return false;
}
run_ini = (result_val.value() & 0x01);
init_children = run_ini || (result_val.value() & 0x02);
}
if (run_ini)
{
auto it = scope->objects.find(NameSeg("_STA"sv));
if (it != scope->objects.end() && it->value->type == Node::Type::Method)
{
auto* method = static_cast<Method*>(it->value.ptr());
if (method->arg_count != 0)
{
AML_ERROR("Method {}._INI has {} arguments, expected 0", scope, method->arg_count);
return false;
}
method->evaluate({});
}
}
bool success = true;
if (init_children)
for (auto& [_, child] : scope->objects)
if (child->type == Node::Type::Device || child->type == Node::Type::Processor)
if (!initialize_device(child))
success = false;
return success;
}
}

View File

@ -7,6 +7,18 @@
namespace Kernel::ACPI
{
template<typename Func>
concept ReadFunc = requires(Func func, uint64_t offset)
{
requires BAN::is_same_v<decltype(func(offset)), BAN::Optional<uint64_t>>;
};
template<typename Func>
concept WriteFunc = requires(Func func, uint64_t offset, uint64_t value)
{
requires BAN::is_same_v<decltype(func(offset, value)), bool>;
};
template<typename Element>
struct ParseFieldElementContext
{
@ -19,6 +31,8 @@ namespace Kernel::ACPI
template<typename Element>
static bool parse_field_element(ParseFieldElementContext<Element>& context)
{
// FIXME: Validate elements
ASSERT(context.field_pkg.size() >= 1);
switch (context.field_pkg[0])
{
@ -81,6 +95,248 @@ namespace Kernel::ACPI
}
}
static BAN::Optional<uint32_t> determine_access_size(const AML::FieldRules::AccessType& access_type)
{
switch (access_type)
{
case AML::FieldRules::AccessType::Any:
case AML::FieldRules::AccessType::Byte:
return 1;
case AML::FieldRules::AccessType::Word:
return 2;
case AML::FieldRules::AccessType::DWord:
return 4;
case AML::FieldRules::AccessType::QWord:
return 8;
case AML::FieldRules::AccessType::Buffer:
AML_TODO("FieldElement with access type Buffer");
return {};
}
return {};
}
static BAN::Optional<uint64_t> perform_read(AML::OpRegion::RegionSpace region_space, uint64_t access_offset, uint32_t access_size)
{
switch (region_space)
{
case AML::OpRegion::RegionSpace::SystemMemory:
{
uint64_t result = 0;
size_t index_in_page = (access_offset % PAGE_SIZE) / access_size;
PageTable::with_fast_page(access_offset & PAGE_ADDR_MASK, [&] {
switch (access_size)
{
case 1: result = PageTable::fast_page_as_sized<uint8_t> (index_in_page); break;
case 2: result = PageTable::fast_page_as_sized<uint16_t>(index_in_page); break;
case 4: result = PageTable::fast_page_as_sized<uint32_t>(index_in_page); break;
case 8: result = PageTable::fast_page_as_sized<uint64_t>(index_in_page); break;
}
});
return result;
}
case AML::OpRegion::RegionSpace::SystemIO:
{
uint64_t result = 0;
switch (access_size)
{
case 1: result = IO::inb(access_offset); break;
case 2: result = IO::inw(access_offset); break;
case 4: result = IO::inl(access_offset); break;
default:
AML_ERROR("FieldElement read_field (SystemIO) with access size {}", access_size);
return {};
}
return result;
}
case AML::OpRegion::RegionSpace::PCIConfig:
{
// https://uefi.org/htmlspecs/ACPI_Spec_6_4_html/05_ACPI_Software_Programming_Model/ACPI_Software_Programming_Model.html#address-space-format
// PCI configuration space is confined to segment 0, bus 0
uint16_t device = (access_offset >> 32) & 0xFFFF;
uint16_t function = (access_offset >> 16) & 0xFFFF;
uint16_t offset = access_offset & 0xFFFF;
uint64_t result = 0;
switch (access_size)
{
case 1: result = PCI::PCIManager::read_config_byte(0, device, function, offset); break;
case 2: result = PCI::PCIManager::read_config_word(0, device, function, offset); break;
case 4: result = PCI::PCIManager::read_config_dword(0, device, function, offset); break;
default:
AML_ERROR("FieldElement read_field (PCIConfig) with access size {}", access_size);
return {};
}
return result;
}
default:
AML_TODO("FieldElement read_field with region space {}", static_cast<uint8_t>(region_space));
return {};
}
}
static bool perform_write(AML::OpRegion::RegionSpace region_space, uint64_t access_offset, uint32_t access_size, uint64_t value)
{
switch (region_space)
{
case AML::OpRegion::RegionSpace::SystemMemory:
{
size_t index_in_page = (access_offset % PAGE_SIZE) / access_size;
PageTable::with_fast_page(access_offset & PAGE_ADDR_MASK, [&] {
switch (access_size)
{
case 1: PageTable::fast_page_as_sized<uint8_t> (index_in_page) = value; break;
case 2: PageTable::fast_page_as_sized<uint16_t>(index_in_page) = value; break;
case 4: PageTable::fast_page_as_sized<uint32_t>(index_in_page) = value; break;
case 8: PageTable::fast_page_as_sized<uint64_t>(index_in_page) = value; break;
}
});
return true;
}
case AML::OpRegion::RegionSpace::SystemIO:
{
switch (access_size)
{
case 1: IO::outb(access_offset, value); break;
case 2: IO::outw(access_offset, value); break;
case 4: IO::outl(access_offset, value); break;
default:
AML_ERROR("FieldElement write_field (SystemIO) with access size {}", access_size);
return false;
}
return true;
}
case AML::OpRegion::RegionSpace::PCIConfig:
{
// https://uefi.org/htmlspecs/ACPI_Spec_6_4_html/05_ACPI_Software_Programming_Model/ACPI_Software_Programming_Model.html#address-space-format
// PCI configuration space is confined to segment 0, bus 0
uint16_t device = (access_offset >> 32) & 0xFFFF;
uint16_t function = (access_offset >> 16) & 0xFFFF;
uint16_t offset = access_offset & 0xFFFF;
switch (access_size)
{
case 1: PCI::PCIManager::write_config_byte(0, device, function, offset, value); break;
case 2: PCI::PCIManager::write_config_word(0, device, function, offset, value); break;
case 4: PCI::PCIManager::write_config_dword(0, device, function, offset, value); break;
default:
AML_ERROR("FieldElement write_field (PCIConfig) with access size {}", access_size);
return false;
}
return true;
}
default:
AML_TODO("FieldElement write_field with region space {}", static_cast<uint8_t>(region_space));
return false;
}
}
template<ReadFunc ReadFunc>
static BAN::Optional<uint64_t> perform_read_general(
uint64_t base_byte_offset,
uint64_t bit_count,
uint64_t bit_offset,
uint32_t access_size,
ReadFunc& read_func
)
{
if (bit_count > 64)
{
AML_TODO("Field read with bit_count > 64");
return {};
}
uint32_t access_bytes = access_size;
uint32_t access_bits = access_bytes * 8;
uint64_t result = 0;
uint32_t bits_read = 0;
while (bits_read < bit_count)
{
uint64_t byte_offset = base_byte_offset + ((bit_offset + bits_read) / 8);
if (auto rem = byte_offset % access_bytes)
byte_offset -= rem;
auto partial = read_func(byte_offset);
if (!partial.has_value())
return {};
uint32_t shift = (bit_offset + bits_read) % access_bits;
uint32_t valid_bits = BAN::Math::min<uint32_t>(access_bits - shift, bit_count - bits_read);
uint64_t mask = ((uint64_t)1 << valid_bits) - 1;
result |= ((partial.value() >> shift) & mask) << bits_read;
bits_read += valid_bits;
}
return result;
}
template<ReadFunc ReadFunc, WriteFunc WriteFunc>
static bool perform_write_general(
uint64_t base_byte_offset,
uint64_t bit_count,
uint64_t bit_offset,
uint32_t access_size,
uint64_t value,
AML::FieldRules::UpdateRule update_rule,
ReadFunc& read_func,
WriteFunc& write_func
)
{
if (bit_count > 64)
{
AML_TODO("Field write with bit_count > 64");
return false;
}
uint32_t access_bytes = access_size;
uint32_t access_bits = access_bytes * 8;
uint32_t bits_written = 0;
while (bits_written < bit_count)
{
uint64_t byte_offset = base_byte_offset + ((bit_offset + bits_written) / 8);
if (auto rem = byte_offset % access_bytes)
byte_offset -= rem;
uint32_t shift = (bit_offset + bits_written) % access_bits;
uint32_t valid_bits = BAN::Math::min<uint32_t>(access_bits - shift, bit_count - bits_written);
uint64_t mask = ((uint64_t)1 << valid_bits) - 1;
uint64_t to_write = 0;
if (valid_bits != access_bits)
{
switch (update_rule)
{
case AML::FieldRules::UpdateRule::Preserve:
{
auto read_result = read_func(byte_offset);
if (!read_result.has_value())
return false;
to_write = read_result.value() & ~(mask << shift);
break;
}
case AML::FieldRules::UpdateRule::WriteAsOnes:
to_write = ~(mask << shift);
break;
case AML::FieldRules::UpdateRule::WriteAsZeros:
to_write = 0;
break;
}
}
to_write |= ((value >> bits_written) & mask) << shift;
if (!write_func(byte_offset, to_write))
return false;
bits_written += valid_bits;
}
return true;
}
AML::ParseResult AML::Field::parse(ParseContext& context)
{
ASSERT(context.aml_data.size() >= 2);
@ -137,185 +393,37 @@ namespace Kernel::ACPI
return ParseResult::Success;
}
BAN::Optional<AML::FieldElement::AccessType> AML::FieldElement::determine_access_type() const
BAN::Optional<uint64_t> AML::FieldElement::evaluate_internal()
{
uint32_t access_size = 0;
switch (access_rules.access_type)
{
case FieldRules::AccessType::Any:
case FieldRules::AccessType::Byte:
access_size = 1;
break;
case FieldRules::AccessType::Word:
access_size = 2;
break;
case FieldRules::AccessType::DWord:
access_size = 4;
break;
case FieldRules::AccessType::QWord:
access_size = 8;
break;
case FieldRules::AccessType::Buffer:
AML_TODO("FieldElement with access type Buffer");
return {};
}
uint64_t byte_offset = op_region->region_offset + (bit_offset / 8);
if (auto rem = byte_offset % access_size)
byte_offset -= rem;
if ((bit_offset % access_size) + bit_count > access_size * 8)
{
AML_ERROR("FieldElement over multiple access sizes");
auto access_size = determine_access_size(access_rules.access_type);
if (!access_size.has_value())
return {};
}
if (byte_offset + access_size > op_region->region_offset + op_region->region_length)
{
AML_ERROR("FieldElement out of bounds");
return {};
}
uint32_t shift = bit_offset % access_size;
uint64_t mask = ((uint64_t)1 << bit_count) - 1;
return AccessType {
.offset = byte_offset,
.mask = mask,
.access_size = access_size,
.shift = shift
auto read_func = [&](uint64_t byte_offset) -> BAN::Optional<uint64_t> {
return perform_read(op_region->region_space, byte_offset, access_size.value());
};
return perform_read_general(op_region->region_offset, bit_count, bit_offset, access_size.value(), read_func);
}
BAN::Optional<uint64_t> AML::FieldElement::read_field(uint64_t access_offset, uint32_t access_size) const
bool AML::FieldElement::store_internal(uint64_t value)
{
switch (op_region->region_space)
{
case OpRegion::RegionSpace::SystemMemory:
{
uint64_t result = 0;
PageTable::with_fast_page(access_offset & PAGE_ADDR_MASK, [&] {
switch (access_size)
{
case 1: result = PageTable::fast_page_as_sized<uint8_t> ((access_offset % PAGE_SIZE) / access_size); break;
case 2: result = PageTable::fast_page_as_sized<uint16_t>((access_offset % PAGE_SIZE) / access_size); break;
case 4: result = PageTable::fast_page_as_sized<uint32_t>((access_offset % PAGE_SIZE) / access_size); break;
case 8: result = PageTable::fast_page_as_sized<uint64_t>((access_offset % PAGE_SIZE) / access_size); break;
}
});
return result;
}
case OpRegion::RegionSpace::SystemIO:
{
uint64_t result = 0;
switch (access_size)
{
case 1: result = IO::inb(access_offset); break;
case 2: result = IO::inw(access_offset); break;
case 4: result = IO::inl(access_offset); break;
default:
AML_ERROR("FieldElement read_field (SystemIO) with access size {}", access_size);
return {};
}
return result;
}
case OpRegion::RegionSpace::PCIConfig:
{
// https://uefi.org/htmlspecs/ACPI_Spec_6_4_html/05_ACPI_Software_Programming_Model/ACPI_Software_Programming_Model.html#address-space-format
// PCI configuration space is confined to segment 0, bus 0
uint16_t device = (access_offset >> 32) & 0xFFFF;
uint16_t function = (access_offset >> 16) & 0xFFFF;
uint16_t offset = access_offset & 0xFFFF;
uint64_t result = 0;
switch (access_size)
{
case 1: result = PCI::PCIManager::read_config_byte(0, device, function, offset); break;
case 2: result = PCI::PCIManager::read_config_word(0, device, function, offset); break;
case 4: result = PCI::PCIManager::read_config_dword(0, device, function, offset); break;
default:
AML_ERROR("FieldElement read_field (PCIConfig) with access size {}", access_size);
return {};
}
return result;
}
default:
AML_TODO("FieldElement read_field with region space {}", static_cast<uint8_t>(op_region->region_space));
return {};
}
}
bool AML::FieldElement::write_field(uint64_t access_offset, uint32_t access_size, uint64_t value) const
{
switch (op_region->region_space)
{
case OpRegion::RegionSpace::SystemMemory:
{
PageTable::with_fast_page(access_offset & PAGE_ADDR_MASK, [&] {
switch (access_size)
{
case 1: PageTable::fast_page_as_sized<uint8_t> ((access_offset % PAGE_SIZE) / access_size) = value; break;
case 2: PageTable::fast_page_as_sized<uint16_t>((access_offset % PAGE_SIZE) / access_size) = value; break;
case 4: PageTable::fast_page_as_sized<uint32_t>((access_offset % PAGE_SIZE) / access_size) = value; break;
case 8: PageTable::fast_page_as_sized<uint64_t>((access_offset % PAGE_SIZE) / access_size) = value; break;
}
});
return true;
}
case OpRegion::RegionSpace::SystemIO:
{
switch (access_size)
{
case 1: IO::outb(access_offset, value); break;
case 2: IO::outw(access_offset, value); break;
case 4: IO::outl(access_offset, value); break;
default:
AML_ERROR("FieldElement write_field (SystemIO) with access size {}", access_size);
return false;
}
return true;
}
case OpRegion::RegionSpace::PCIConfig:
{
// https://uefi.org/htmlspecs/ACPI_Spec_6_4_html/05_ACPI_Software_Programming_Model/ACPI_Software_Programming_Model.html#address-space-format
// PCI configuration space is confined to segment 0, bus 0
uint16_t device = (access_offset >> 32) & 0xFFFF;
uint16_t function = (access_offset >> 16) & 0xFFFF;
uint16_t offset = access_offset & 0xFFFF;
switch (access_size)
{
case 1: PCI::PCIManager::write_config_byte(0, device, function, offset, value); break;
case 2: PCI::PCIManager::write_config_word(0, device, function, offset, value); break;
case 4: PCI::PCIManager::write_config_dword(0, device, function, offset, value); break;
default:
AML_ERROR("FieldElement write_field (PCIConfig) with access size {}", access_size);
return false;
}
return true;
}
default:
AML_TODO("FieldElement write_field with region space {}", static_cast<uint8_t>(op_region->region_space));
return false;
}
auto access_size = determine_access_size(access_rules.access_type);
if (!access_size.has_value())
return false;
auto read_func = [&](uint64_t byte_offset) -> BAN::Optional<uint64_t> {
return perform_read(op_region->region_space, byte_offset, access_size.value());
};
auto write_func = [&](uint64_t byte_offset, uint64_t value) -> bool {
return perform_write(op_region->region_space, byte_offset, access_size.value(), value);
};
return perform_write_general(op_region->region_offset, bit_count, bit_offset, access_size.value(), value, access_rules.update_rule, read_func, write_func);
}
BAN::RefPtr<AML::Node> AML::FieldElement::evaluate()
{
// Field LockRule only applies to modifying the field, not reading it
auto access_type = determine_access_type();
if (!access_type.has_value())
return {};
auto result = read_field(access_type->offset, access_type->access_size);
auto result = evaluate_internal();
if (!result.has_value())
return {};
return MUST(BAN::RefPtr<Integer>::create((result.value() >> access_type->shift) & access_type->mask));
return MUST(BAN::RefPtr<Integer>::create(result.value()));
}
bool AML::FieldElement::store(BAN::RefPtr<AML::Node> source)
@ -327,10 +435,6 @@ namespace Kernel::ACPI
return false;
}
auto access_type = determine_access_type();
if (!access_type.has_value())
return false;
if (access_rules.lock_rule == FieldRules::LockRule::Lock)
Namespace::root_namespace()->global_lock.lock();
BAN::ScopeGuard unlock_guard([&] {
@ -338,40 +442,18 @@ namespace Kernel::ACPI
Namespace::root_namespace()->global_lock.unlock();
});
uint64_t to_write = 0;
switch (access_rules.update_rule)
{
case FieldRules::UpdateRule::Preserve:
{
auto read_result = read_field(access_type->offset, access_type->access_size);
if (!read_result.has_value())
return false;
to_write = read_result.value();
to_write &= ~(access_type->mask << access_type->shift);
to_write |= (source_integer.value() & access_type->mask) << access_type->shift;
break;
}
case FieldRules::UpdateRule::WriteAsOnes:
to_write = ~(access_type->mask << access_type->shift);
to_write |= (source_integer.value() & access_type->mask) << access_type->shift;
break;
case FieldRules::UpdateRule::WriteAsZeros:
to_write = 0;
to_write |= (source_integer.value() & access_type->mask) << access_type->shift;
break;
}
return write_field(access_type->offset, access_type->access_size, to_write);
return store_internal(source_integer.value());
}
void AML::FieldElement::debug_print(int indent) const
{
AML_DEBUG_PRINT_INDENT(indent);
AML_DEBUG_PRINT("FieldElement ");
name.debug_print();
AML_DEBUG_PRINT("({}, offset {}, OpRegion ", bit_count, bit_offset);
op_region->name.debug_print();
AML_DEBUG_PRINT(")");
AML_DEBUG_PRINT("FieldElement {} ({}, offset {}, OpRegion {})",
name,
bit_count,
bit_offset,
op_region->name
);
}
AML::ParseResult AML::IndexField::parse(ParseContext& context)
@ -440,16 +522,88 @@ namespace Kernel::ACPI
return AML::ParseResult::Success;
}
BAN::RefPtr<AML::Node> AML::IndexFieldElement::evaluate()
{
auto access_size = determine_access_size(access_rules.access_type);
if (!access_size.has_value())
return {};
if (access_size.value() > data_element->bit_count)
{
AML_ERROR("IndexFieldElement read_field with access size {} > data element bit count {}", access_size.value(), data_element->bit_count);
return {};
}
auto read_func = [&](uint64_t byte_offset) -> BAN::Optional<uint64_t> {
if (!index_element->store_internal(byte_offset))
return {};
return data_element->evaluate_internal();
};
if (access_rules.lock_rule == FieldRules::LockRule::Lock)
Namespace::root_namespace()->global_lock.lock();
BAN::ScopeGuard unlock_guard([&] {
if (access_rules.lock_rule == FieldRules::LockRule::Lock)
Namespace::root_namespace()->global_lock.unlock();
});
auto result = perform_read_general(0, bit_count, bit_offset, access_size.value(), read_func);
if (!result.has_value())
return {};
return MUST(BAN::RefPtr<Integer>::create(result.value()));
}
bool AML::IndexFieldElement::store(BAN::RefPtr<Node> source)
{
auto source_integer = source->as_integer();
if (!source_integer.has_value())
{
AML_TODO("IndexFieldElement store with non-integer source, type {}", static_cast<uint8_t>(source->type));
return false;
}
auto access_size = determine_access_size(access_rules.access_type);
if (!access_size.has_value())
return false;
if (access_size.value() > data_element->bit_count)
{
AML_ERROR("IndexFieldElement write_field with access size {} > data element bit count {}", access_size.value(), data_element->bit_count);
return false;
}
auto read_func = [&](uint64_t byte_offset) -> BAN::Optional<uint64_t> {
if (!index_element->store_internal(byte_offset))
return {};
return data_element->evaluate_internal();
};
auto write_func = [&](uint64_t byte_offset, uint64_t value) -> bool {
if (!index_element->store_internal(byte_offset))
return false;
return data_element->store_internal(value);
};
if (access_rules.lock_rule == FieldRules::LockRule::Lock)
Namespace::root_namespace()->global_lock.lock();
BAN::ScopeGuard unlock_guard([&] {
if (access_rules.lock_rule == FieldRules::LockRule::Lock)
Namespace::root_namespace()->global_lock.unlock();
});
if (!perform_write_general(0, bit_count, bit_offset, access_size.value(), source_integer.value(), access_rules.update_rule, read_func, write_func))
return false;
return true;
}
void AML::IndexFieldElement::debug_print(int indent) const
{
AML_DEBUG_PRINT_INDENT(indent);
AML_DEBUG_PRINT("IndexFieldElement ");
name.debug_print();
AML_DEBUG_PRINT("({}, offset {}, IndexName ", bit_count, bit_offset);
index_element->name.debug_print();
AML_DEBUG_PRINT(", DataName ");
data_element->name.debug_print();
AML_DEBUG_PRINT(")");
AML_DEBUG_PRINT("IndexFieldElement {} ({}, offset {}, IndexName {}, DataName {})",
name,
bit_count,
bit_offset,
index_element->name,
data_element->name
);
}
}