/*
    This file is part of Magnum.

    Copyright © 2010, 2011, 2012, 2013, 2014, 2015, 2016, 2017, 2018, 2019,
                2020 Vladimír Vondruš <mosra@centrum.cz>

    Permission is hereby granted, free of charge, to any person obtaining a
    copy of this software and associated documentation files (the "Software"),
    to deal in the Software without restriction, including without limitation
    the rights to use, copy, modify, merge, publish, distribute, sublicense,
    and/or sell copies of the Software, and to permit persons to whom the
    Software is furnished to do so, subject to the following conditions:

    The above copyright notice and this permission notice shall be included
    in all copies or substantial portions of the Software.

    THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
    IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
    FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
    THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
    LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
    FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
    DEALINGS IN THE SOFTWARE.
*/

#include "DeviceProperties.h"

#include <Corrade/Containers/Array.h>
#include <Corrade/Containers/EnumSet.hpp>
#include <Corrade/Containers/Optional.h>
#include <Corrade/Containers/StaticArray.h>
#include <Corrade/Containers/StringView.h>
#include <Corrade/Utility/Arguments.h>
#include <Corrade/Utility/Debug.h>

#include "Magnum/Math/Functions.h"
#include "Magnum/Vk/Assert.h"
#include "Magnum/Vk/ExtensionProperties.h"
#include "Magnum/Vk/Extensions.h"
#include "Magnum/Vk/Instance.h"
#include "Magnum/Vk/LayerProperties.h"
#include "Magnum/Vk/Memory.h"
#include "Magnum/Vk/Version.h"
#include "Magnum/Vk/Implementation/Arguments.h"
#include "Magnum/Vk/Implementation/InstanceState.h"

namespace Magnum { namespace Vk {

struct DeviceProperties::State {
    VkPhysicalDeviceProperties2 properties{};
    VkPhysicalDeviceDriverProperties driverProperties{};
    VkPhysicalDeviceMemoryProperties2 memoryProperties{};
    Containers::Array<VkQueueFamilyProperties2> queueFamilyProperties;
};

DeviceProperties::DeviceProperties(NoCreateT) noexcept: _instance{}, _handle{} {}

DeviceProperties::DeviceProperties(Instance& instance, VkPhysicalDevice handle): _instance{&instance}, _handle{handle} {}

/* The VkDeviceProperties handle doesn't need to be destroyed so it's enough to
   just rely on the implicit behavior */
DeviceProperties::DeviceProperties(DeviceProperties&&) noexcept = default;

DeviceProperties::~DeviceProperties() = default;

DeviceProperties& DeviceProperties::operator=(DeviceProperties&&) noexcept = default;

Containers::StringView DeviceProperties::name() {
    return properties().properties.deviceName;
}

DeviceDriver DeviceProperties::driver() {
    /* Ensure the values are populated first */
    return properties(), DeviceDriver(_state->driverProperties.driverID);
}

Containers::StringView DeviceProperties::driverName() {
    /* Ensure the values are populated first */
    return properties(), _state->driverProperties.driverName;
}

Containers::StringView DeviceProperties::driverInfo() {
    /* Ensure the values are populated first */
    return properties(), _state->driverProperties.driverInfo;
}

const VkPhysicalDeviceProperties2& DeviceProperties::properties() {
    if(!_state) _state.emplace();

    /* Properties not fetched yet, do that now */
    if(!_state->properties.sType) {
        _state->properties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_PROPERTIES_2;

        Containers::Reference<void*> next = _state->properties.pNext;

        /* Device extension properties. Populated only if needed. */
        ExtensionProperties extensions{NoCreate};

        /* Fetch driver properties, if supported */
        if(_instance->isVersionSupported(Version::Vk12) || (extensions = enumerateExtensionProperties()).isSupported<Extensions::KHR::driver_properties>()) {
            *next = &_state->driverProperties;
            next = _state->driverProperties.pNext;
            _state->driverProperties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_DRIVER_PROPERTIES;
        }

        _instance->state().getPhysicalDevicePropertiesImplementation(*this, _state->properties);
    }

    return _state->properties;
}

void DeviceProperties::getPropertiesImplementationDefault(DeviceProperties& self, VkPhysicalDeviceProperties2& properties) {
    return (**self._instance).GetPhysicalDeviceProperties(self._handle, &properties.properties);
}

void DeviceProperties::getPropertiesImplementationKHR(DeviceProperties& self, VkPhysicalDeviceProperties2& properties) {
    return (**self._instance).GetPhysicalDeviceProperties2KHR(self._handle, &properties);
}

void DeviceProperties::getPropertiesImplementation11(DeviceProperties& self, VkPhysicalDeviceProperties2& properties) {
    return (**self._instance).GetPhysicalDeviceProperties2(self._handle, &properties);
}

ExtensionProperties DeviceProperties::enumerateExtensionProperties(Containers::ArrayView<const Containers::StringView> layers) {
    return InstanceExtensionProperties{layers, [](void* state, const char* const layer, UnsignedInt* count, VkExtensionProperties* properties) {
        auto& deviceProperties = *static_cast<DeviceProperties*>(state);
        return (**deviceProperties._instance).EnumerateDeviceExtensionProperties(deviceProperties._handle, layer, count, properties);
    }, this};
}

ExtensionProperties DeviceProperties::enumerateExtensionProperties(std::initializer_list<Containers::StringView> layers) {
    return enumerateExtensionProperties(Containers::arrayView(layers));
}

Containers::ArrayView<const VkQueueFamilyProperties2> DeviceProperties::queueFamilyProperties() {
    if(!_state) _state.emplace();

    /* Fetch if not already */
    if(_state->queueFamilyProperties.empty()) {
        UnsignedInt count;
        _instance->state().getPhysicalDeviceQueueFamilyPropertiesImplementation(*this, count, nullptr);

        _state->queueFamilyProperties = Containers::Array<VkQueueFamilyProperties2>{Containers::ValueInit, count};
        for(VkQueueFamilyProperties2& i: _state->queueFamilyProperties)
            i.sType = VK_STRUCTURE_TYPE_QUEUE_FAMILY_PROPERTIES_2;
        _instance->state().getPhysicalDeviceQueueFamilyPropertiesImplementation(*this, count, _state->queueFamilyProperties);
        CORRADE_INTERNAL_ASSERT(count == _state->queueFamilyProperties.size());
    }

    return _state->queueFamilyProperties;
}

void DeviceProperties::getQueueFamilyPropertiesImplementationDefault(DeviceProperties& self, UnsignedInt& count, VkQueueFamilyProperties2* properties) {
    (**self._instance).GetPhysicalDeviceQueueFamilyProperties(self._handle,  &count, reinterpret_cast<VkQueueFamilyProperties*>(properties));

    /* "Sparsen" the returned data to the version 2 structure layout. If the
       pointer is null we were just querying the count. */
    if(properties) {
        Containers::ArrayView<VkQueueFamilyProperties> src{reinterpret_cast<VkQueueFamilyProperties*>(properties), count};
        Containers::ArrayView<VkQueueFamilyProperties2> dst{properties, count};
        /* Go backwards so we don't overwrite the yet-to-be-processed data,
           additionally copy the VkQueueFamilyProperties first so we don't
           overwrite them by setting sType and pNext. */
        for(std::size_t i = count; i != 0; --i) {
            dst[i - 1].queueFamilyProperties = src[i - 1];
            dst[i - 1].sType = VK_STRUCTURE_TYPE_QUEUE_FAMILY_PROPERTIES_2;
            dst[i - 1].pNext = nullptr;
        }
    }
}

void DeviceProperties::getQueueFamilyPropertiesImplementationKHR(DeviceProperties& self, UnsignedInt& count, VkQueueFamilyProperties2* properties) {
    return (**self._instance).GetPhysicalDeviceQueueFamilyProperties2KHR(self._handle, &count, properties);
}

void DeviceProperties::getQueueFamilyPropertiesImplementation11(DeviceProperties& self, UnsignedInt& count, VkQueueFamilyProperties2* properties) {
    return (**self._instance).GetPhysicalDeviceQueueFamilyProperties2(self._handle, &count, properties);
}

UnsignedInt DeviceProperties::queueFamilyCount() {
    return queueFamilyProperties().size();
}

UnsignedInt DeviceProperties::queueFamilySize(const UnsignedInt id) {
    const Containers::ArrayView<const VkQueueFamilyProperties2> properties = queueFamilyProperties();
    CORRADE_ASSERT(id < properties.size(),
        "Vk::DeviceProperties::queueFamilySize(): index" << id << "out of range for" << properties.size() << "entries", {});
    return properties[id].queueFamilyProperties.queueCount;
}

QueueFlags DeviceProperties::queueFamilyFlags(const UnsignedInt id) {
    const Containers::ArrayView<const VkQueueFamilyProperties2> properties = queueFamilyProperties();
    CORRADE_ASSERT(id < properties.size(),
        "Vk::DeviceProperties::queueFamilyFlags(): index" << id << "out of range for" << properties.size() << "entries", {});
    return QueueFlag(properties[id].queueFamilyProperties.queueFlags);
}

UnsignedInt DeviceProperties::pickQueueFamily(const QueueFlags flags) {
    Containers::Optional<UnsignedInt> id = tryPickQueueFamily(flags);
    if(id) return *id;
    std::exit(1); /* LCOV_EXCL_LINE */
}

Containers::Optional<UnsignedInt> DeviceProperties::tryPickQueueFamily(const QueueFlags flags) {
    const Containers::ArrayView<const VkQueueFamilyProperties2> properties = queueFamilyProperties();
    for(UnsignedInt i = 0; i != properties.size(); ++i)
        if(QueueFlag(properties[i].queueFamilyProperties.queueFlags) >= flags) return i;

    Error{} << "Vk::DeviceProperties::tryPickQueueFamily(): no" << flags << "found among" << properties.size() << "queue families";
    return {};
}

const VkPhysicalDeviceMemoryProperties2& DeviceProperties::memoryProperties() {
    if(!_state) _state.emplace();

    if(!_state->memoryProperties.sType) {
        _state->memoryProperties.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_MEMORY_PROPERTIES_2;
        _instance->state().getPhysicalDeviceMemoryPropertiesImplementation(*this, _state->memoryProperties);
    }

    return _state->memoryProperties;
}

void DeviceProperties::getMemoryPropertiesImplementationDefault(DeviceProperties& self, VkPhysicalDeviceMemoryProperties2& properties) {
    return (**self._instance).GetPhysicalDeviceMemoryProperties(self._handle, &properties.memoryProperties);
}

void DeviceProperties::getMemoryPropertiesImplementationKHR(DeviceProperties& self, VkPhysicalDeviceMemoryProperties2& properties) {
    return (**self._instance).GetPhysicalDeviceMemoryProperties2KHR(self._handle, &properties);
}

void DeviceProperties::getMemoryPropertiesImplementation11(DeviceProperties& self, VkPhysicalDeviceMemoryProperties2& properties) {
    return (**self._instance).GetPhysicalDeviceMemoryProperties2(self._handle, &properties);
}

UnsignedInt DeviceProperties::memoryHeapCount() {
    return memoryProperties().memoryProperties.memoryHeapCount;
}

UnsignedLong DeviceProperties::memoryHeapSize(const UnsignedInt heap) {
    const VkPhysicalDeviceMemoryProperties& properties = memoryProperties().memoryProperties;
    CORRADE_ASSERT(heap < properties.memoryHeapCount,
        "Vk::DeviceProperties::memoryHeapSize(): index" << heap << "out of range for" << properties.memoryHeapCount << "memory heaps", {});
    return properties.memoryHeaps[heap].size;
}

MemoryHeapFlags DeviceProperties::memoryHeapFlags(const UnsignedInt heap) {
    const VkPhysicalDeviceMemoryProperties& properties = memoryProperties().memoryProperties;
    CORRADE_ASSERT(heap < properties.memoryHeapCount,
        "Vk::DeviceProperties::memoryHeapFlags(): index" << heap << "out of range for" << properties.memoryHeapCount << "memory heaps", {});
    return MemoryHeapFlag(properties.memoryHeaps[heap].flags);
}

UnsignedInt DeviceProperties::memoryCount() {
    return memoryProperties().memoryProperties.memoryTypeCount;
}

MemoryFlags DeviceProperties::memoryFlags(const UnsignedInt memory) {
    const VkPhysicalDeviceMemoryProperties& properties = memoryProperties().memoryProperties;
    CORRADE_ASSERT(memory < properties.memoryTypeCount,
        "Vk::DeviceProperties::memoryFlags(): index" << memory << "out of range for" << properties.memoryTypeCount << "memory types", {});
    return MemoryFlag(properties.memoryTypes[memory].propertyFlags);
}

UnsignedInt DeviceProperties::memoryHeapIndex(const UnsignedInt memory) {
    const VkPhysicalDeviceMemoryProperties& properties = memoryProperties().memoryProperties;
    CORRADE_ASSERT(memory < properties.memoryTypeCount,
        "Vk::DeviceProperties::memoryHeapIndex(): index" << memory << "out of range for" << properties.memoryTypeCount << "memory types", {});
    return properties.memoryTypes[memory].heapIndex;
}

UnsignedInt DeviceProperties::pickMemory(const MemoryFlags requiredFlags, const MemoryFlags preferredFlags, const UnsignedInt memories) {
    Containers::Optional<UnsignedInt> id = tryPickMemory(requiredFlags, preferredFlags, memories);
    if(id) return *id;
    std::exit(1); /* LCOV_EXCL_LINE */
}

UnsignedInt DeviceProperties::pickMemory(const MemoryFlags requiredFlags, const UnsignedInt memories) {
    return pickMemory(requiredFlags, {}, memories);
}

Containers::Optional<UnsignedInt> DeviceProperties::tryPickMemory(const MemoryFlags requiredFlags, const MemoryFlags preferredFlags, const UnsignedInt memories) {
    const VkPhysicalDeviceMemoryProperties properties = memoryProperties().memoryProperties;

    /* The picking strategy is basically equivalent to vmaFindMemoryTypeIndex()
       from AMD's Vulkan Memory Allocator -- choosing the one that has the most
       bits set. */
    Int maxPreferredBitCount = -1;
    UnsignedInt maxPreferredBitCountMemory = ~UnsignedInt{};
    UnsignedInt bit = 1;
    for(UnsignedInt i = 0; i != properties.memoryTypeCount; ++i, bit <<= 1) {
        /* Not among considered memory types, skip */
        if(!(memories & bit))
            continue;

        /* Not all required flags present, skip */
        if(!(MemoryFlag(properties.memoryTypes[i].propertyFlags) >= requiredFlags))
            continue;

        /* Check how many of the preferred flags are present and use the one
           with highest count */
        const Int preferredBitCount = Math::popcount(properties.memoryTypes[i].propertyFlags & UnsignedInt(preferredFlags));
        if(preferredBitCount > maxPreferredBitCount) {
            maxPreferredBitCount = preferredBitCount;
            maxPreferredBitCountMemory = i;
        }
    }

    if(maxPreferredBitCount >= 0) return maxPreferredBitCountMemory;

    Error{} << "Vk::DeviceProperties::tryPickMemory(): no" << requiredFlags << "found among" << Math::popcount(memories & ((1 << properties.memoryTypeCount) - 1)) << "considered memory types";
    return {};
}

Containers::Optional<UnsignedInt> DeviceProperties::tryPickMemory(const MemoryFlags requiredFlags, const UnsignedInt memories) {
    return tryPickMemory(requiredFlags, {}, memories);
}

/* Can't be inside an anonymous namespace as it's friended to DeviceProperties */
namespace Implementation {

UnsignedInt enumerateDevicesInto(Instance& instance, Containers::ArrayView<DeviceProperties> out) {
    /* Allocate memory for the output, fetch the handles into it */
    Containers::ArrayView<VkPhysicalDevice> handles{reinterpret_cast<VkPhysicalDevice*>(out.data()), out.size()};
    UnsignedInt count = out.size();
    MAGNUM_VK_INTERNAL_ASSERT_SUCCESS_OR_INCOMPLETE(instance->EnumeratePhysicalDevices(instance, &count, handles.data()));

    /* Expect the final count isn't larger than the output array */
    CORRADE_INTERNAL_ASSERT(count <= out.size());

    /* Construct actual DeviceProperties instances from these, go backwards so
       we don't overwrite the not-yet-processed handles */
    for(std::size_t i = count; i != 0; --i)
        new(out.data() + i - 1) DeviceProperties{instance, handles[i - 1]};
    /* Construct the remaining entries so the array destructor doesn't crash */
    for(std::size_t i = count; i != out.size(); ++i)
        new(out.data() + i) DeviceProperties{NoCreate};

    return count;
}

}

Containers::Array<DeviceProperties> enumerateDevices(Instance& instance) {
    /* Retrieve total device count */
    UnsignedInt count;
    MAGNUM_VK_INTERNAL_ASSERT_SUCCESS(instance->EnumeratePhysicalDevices(instance, &count, nullptr));

    /* Fetch device handles, expect the device count didn't change between
       calls */
    Containers::Array<DeviceProperties> out{Containers::NoInit, count};
    CORRADE_INTERNAL_ASSERT_OUTPUT(Implementation::enumerateDevicesInto(instance, out) == out.size());

    return out;
}

Containers::Optional<DeviceProperties> tryPickDevice(Instance& instance) {
    Utility::Arguments args = Implementation::arguments();
    args.parse(instance.state().argc, instance.state().argv);

    /* Pick the first by default */
    if(args.value("device").empty()) {
        Containers::Array1<DeviceProperties> devices{Containers::NoInit};
        if(!Implementation::enumerateDevicesInto(instance, devices)) {
            Error{} << "Vk::tryPickDevice(): no Vulkan devices found";
            return {};
        }

        return std::move(devices.front());
    }

    /* Pick by ID */
    if(args.value("device")[0] >= '0' && args.value("device")[0] <= '9') {
        const UnsignedInt id = args.value<UnsignedInt>("device");
        Containers::Array<DeviceProperties> devices{Containers::NoInit, id + 1};
        const UnsignedInt count = Implementation::enumerateDevicesInto(instance, devices);
        if(id >= count) {
            Error{} << "Vk::tryPickDevice(): index" << id << "out of bounds for" << count << "Vulkan devices";
            return {};
        }

        return std::move(devices[id]);
    }

    Containers::Array<DeviceProperties> devices = enumerateDevices(instance);

    /* Pick by type */
    DeviceType type;
    if(args.value("device") == "integrated")
        type = DeviceType::IntegratedGpu;
    else if(args.value("device") == "discrete")
        type = DeviceType::DiscreteGpu;
    else if(args.value("device") == "virtual")
        type = DeviceType::VirtualGpu;
    else if(args.value("device") == "cpu")
        type = DeviceType::Cpu;
    else {
        Error{} << "Vk::tryPickDevice(): unknown Vulkan device type" << args.value<Containers::StringView>("device");
        return {};
    }

    for(DeviceProperties& device: devices)
        if(device.type() == type) return std::move(device);

    Error{} << "Vk::tryPickDevice(): no" << type << "found among" << devices.size() << "Vulkan devices";
    return {};
}

DeviceProperties pickDevice(Instance& instance) {
    Containers::Optional<DeviceProperties> device = tryPickDevice(instance);
    if(device) return *std::move(device);
    std::exit(1); /* LCOV_EXCL_LINE */
}

Debug& operator<<(Debug& debug, const DeviceType value) {
    debug << "Vk::DeviceType" << Debug::nospace;

    switch(value) {
        /* LCOV_EXCL_START */
        #define _c(value) case Vk::DeviceType::value: return debug << "::" << Debug::nospace << #value;
        _c(Other)
        _c(IntegratedGpu)
        _c(DiscreteGpu)
        _c(VirtualGpu)
        _c(Cpu)
        #undef _c
        /* LCOV_EXCL_STOP */
    }

    /* Vulkan docs have the values in decimal, so not converting to hex */
    return debug << "(" << Debug::nospace << Int(value) << Debug::nospace << ")";
}

Debug& operator<<(Debug& debug, const DeviceDriver value) {
    debug << "Vk::DeviceDriver" << Debug::nospace;

    switch(value) {
        /* LCOV_EXCL_START */
        #define _c(value) case Vk::DeviceDriver::value: return debug << "::" << Debug::nospace << #value;
        _c(Unknown)
        _c(AmdOpenSource)
        _c(AmdProprietary)
        _c(ArmProprietary)
        _c(BroadcomProprietary)
        _c(GgpProprietary)
        _c(GoogleSwiftShader)
        _c(ImaginationProprietary)
        _c(IntelOpenSourceMesa)
        _c(IntelProprietaryWindows)
        _c(MesaLlvmpipe)
        _c(MesaRadv)
        _c(MoltenVk)
        _c(NVidiaProprietary)
        _c(QualcommProprietary)
        #undef _c
        /* LCOV_EXCL_STOP */
    }

    /* Vulkan docs have the values in decimal, so not converting to hex */
    return debug << "(" << Debug::nospace << Int(value) << Debug::nospace << ")";
}

Debug& operator<<(Debug& debug, const QueueFlag value) {
    debug << "Vk::QueueFlag" << Debug::nospace;

    switch(value) {
        /* LCOV_EXCL_START */
        #define _c(value) case Vk::QueueFlag::value: return debug << "::" << Debug::nospace << #value;
        _c(Graphics)
        _c(Compute)
        _c(Transfer)
        _c(SparseBinding)
        _c(Protected)
        #undef _c
        /* LCOV_EXCL_STOP */
    }

    /* Flag bits should be in hex, unlike plain values */
    return debug << "(" << Debug::nospace << reinterpret_cast<void*>(UnsignedInt(value)) << Debug::nospace << ")";
}

Debug& operator<<(Debug& debug, const QueueFlags value) {
    return Containers::enumSetDebugOutput(debug, value, "Vk::QueueFlags{}", {
        Vk::QueueFlag::Graphics,
        Vk::QueueFlag::Compute,
        Vk::QueueFlag::Transfer,
        Vk::QueueFlag::SparseBinding,
        Vk::QueueFlag::Protected});
}

Debug& operator<<(Debug& debug, const MemoryHeapFlag value) {
    debug << "Vk::MemoryHeapFlag" << Debug::nospace;

    switch(value) {
        /* LCOV_EXCL_START */
        #define _c(value) case Vk::MemoryHeapFlag::value: return debug << "::" << Debug::nospace << #value;
        _c(DeviceLocal)
        #undef _c
        /* LCOV_EXCL_STOP */
    }

    /* Flag bits should be in hex, unlike plain values */
    return debug << "(" << Debug::nospace << reinterpret_cast<void*>(UnsignedInt(value)) << Debug::nospace << ")";
}

Debug& operator<<(Debug& debug, const MemoryHeapFlags value) {
    return Containers::enumSetDebugOutput(debug, value, "Vk::MemoryHeapFlags{}", {
        Vk::MemoryHeapFlag::DeviceLocal});
}

}}