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@ -10,23 +10,28 @@ namespace skyline {
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template<typename VaType, size_t AddressSpaceBits>
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concept AddressSpaceValid = std::is_unsigned_v<VaType> && sizeof(VaType) * 8 >= AddressSpaceBits;
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struct EmptyStruct {};
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/**
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* @brief FlatAddressSpaceMap provides a generic VA->PA mapping implementation using a sorted vector
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*/
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template<typename VaType, VaType UnmappedVa, typename PaType, PaType UnmappedPa, bool PaContigSplit, size_t AddressSpaceBits> requires AddressSpaceValid<VaType, AddressSpaceBits>
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extern class FlatAddressSpaceMap {
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template<typename VaType, VaType UnmappedVa, typename PaType, PaType UnmappedPa, bool PaContigSplit, size_t AddressSpaceBits, typename ExtraBlockInfo = EmptyStruct> requires AddressSpaceValid<VaType, AddressSpaceBits>
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class FlatAddressSpaceMap {
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private:
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std::function<void(VaType, VaType)> unmapCallback{}; //!< Callback called when the mappings in an region have changed
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protected:
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/**
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* @brief Represents a block of memory in the AS, the physical mapping is contiguous until another block with a different phys address is hit
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*/
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struct Block {
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VaType virt{UnmappedVa}; //!< VA of the block
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PaType phys{UnmappedPa}; //!< PA of the block, will increase 1-1 with VA until a new block is encountered
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bool flag{}; //!< General purpose flag for use by derived classes
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[[no_unique_address]] ExtraBlockInfo extraInfo;
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Block() = default;
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Block(VaType virt, PaType phys, bool flag) : virt(virt), phys(phys), flag(flag) {}
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Block(VaType virt, PaType phys, ExtraBlockInfo extraInfo) : virt(virt), phys(phys), extraInfo(extraInfo) {}
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constexpr bool Valid() {
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return virt != UnmappedVa;
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@ -45,15 +50,14 @@ namespace skyline {
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}
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};
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protected:
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std::mutex blockMutex;
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std::vector<Block> blocks{Block{}};
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/**
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* @brief Maps a PA range into the given AS region, optionally setting the flag
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* @brief Maps a PA range into the given AS region
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* @note blockMutex MUST be locked when calling this
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*/
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void MapLocked(VaType virt, PaType phys, VaType size, bool flag = {});
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void MapLocked(VaType virt, PaType phys, VaType size, ExtraBlockInfo extraInfo);
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/**
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* @brief Unmaps the given range and merges it with other unmapped regions
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@ -66,13 +70,13 @@ namespace skyline {
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VaType vaLimit{VaMaximum}; //!< A soft limit on the maximum VA of the AS
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FlatAddressSpaceMap(VaType pVaLimit);
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FlatAddressSpaceMap(VaType vaLimit, std::function<void(VaType, VaType)> unmapCallback = {});
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FlatAddressSpaceMap() = default;
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void Map(VaType virt, PaType phys, VaType size, bool flag = {}) {
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void Map(VaType virt, PaType phys, VaType size, ExtraBlockInfo extraInfo = {}) {
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std::scoped_lock lock(blockMutex);
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MapLocked(virt, phys, size, flag);
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MapLocked(virt, phys, size, extraInfo);
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}
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void Unmap(VaType virt, VaType size) {
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@ -82,11 +86,26 @@ namespace skyline {
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};
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/**
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* @brief FlatMemoryManager specialises FlatAddressSpaceMap to focus on pointers as PAs, adding read/write functions
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* @brief Hold memory manager specific block info
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*/
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struct MemoryManagerBlockInfo {
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bool sparseMapped;
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};
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/**
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* @brief FlatMemoryManager specialises FlatAddressSpaceMap to focus on pointers as PAs, adding read/write functions and sparse mapping support
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*/
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template<typename VaType, VaType UnmappedVa, size_t AddressSpaceBits> requires AddressSpaceValid<VaType, AddressSpaceBits>
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class FlatMemoryManager : public FlatAddressSpaceMap<VaType, UnmappedVa, u8 *, nullptr, true, AddressSpaceBits> {
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class FlatMemoryManager : public FlatAddressSpaceMap<VaType, UnmappedVa, u8 *, nullptr, true, AddressSpaceBits, MemoryManagerBlockInfo> {
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private:
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static constexpr u64 SparseMapSize{0x400000000}; //!< 16GiB pool size for sparse mappings returned by TranslateRange, this number is arbritary and should be large enough to fit the largest sparse mapping in the AS
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u8 *sparseMap; //!< Pointer to a zero filled memory region that is returned by TranslateRange for sparse mappings
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public:
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FlatMemoryManager();
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~FlatMemoryManager();
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/**
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* @return A placeholder address for sparse mapped regions, this means nothing
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*/
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@ -94,6 +113,11 @@ namespace skyline {
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return reinterpret_cast<u8 *>(0xCAFEBABE);
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}
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/**
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* @brief Returns a vector of all physical ranges inside of the given virtual range
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*/
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std::vector<span<u8>> TranslateRange(VaType virt, VaType size);
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void Read(u8 *destination, VaType virt, VaType size);
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template<typename T>
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@ -5,19 +5,21 @@
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#include <kernel/types/KProcess.h>
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#include "address_space.h"
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#define MAP_MEMBER(returnType) template<typename VaType, VaType UnmappedVa, typename PaType, PaType UnmappedPa, bool PaContigSplit, size_t AddressSpaceBits> requires AddressSpaceValid<VaType, AddressSpaceBits> returnType FlatAddressSpaceMap<VaType, UnmappedVa, PaType, UnmappedPa, PaContigSplit, AddressSpaceBits>
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#define MAP_MEMBER(returnType) template<typename VaType, VaType UnmappedVa, typename PaType, PaType UnmappedPa, bool PaContigSplit, size_t AddressSpaceBits, typename ExtraBlockInfo> requires AddressSpaceValid<VaType, AddressSpaceBits> returnType FlatAddressSpaceMap<VaType, UnmappedVa, PaType, UnmappedPa, PaContigSplit, AddressSpaceBits, ExtraBlockInfo>
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#define MM_MEMBER(returnType) template<typename VaType, VaType UnmappedVa, size_t AddressSpaceBits> requires AddressSpaceValid<VaType, AddressSpaceBits> returnType FlatMemoryManager<VaType, UnmappedVa, AddressSpaceBits>
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#define ALLOC_MEMBER(returnType) template<typename VaType, VaType UnmappedVa, size_t AddressSpaceBits> requires AddressSpaceValid<VaType, AddressSpaceBits> returnType FlatAllocator<VaType, UnmappedVa, AddressSpaceBits>
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namespace skyline {
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MAP_MEMBER()::FlatAddressSpaceMap(VaType pVaLimit) : vaLimit(pVaLimit) {
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if (pVaLimit > VaMaximum)
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MAP_MEMBER()::FlatAddressSpaceMap(VaType vaLimit, std::function<void(VaType, VaType)> unmapCallback) :
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vaLimit(vaLimit),
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unmapCallback(std::move(unmapCallback)) {
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if (vaLimit > VaMaximum)
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throw exception("Invalid VA limit!");
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}
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MAP_MEMBER(void)::MapLocked(VaType virt, PaType phys, VaType size, bool flag) {
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MAP_MEMBER(void)::MapLocked(VaType virt, PaType phys, VaType size, ExtraBlockInfo extraInfo) {
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TRACE_EVENT("containers", "FlatAddressSpaceMap::Map");
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VaType virtEnd{virt + size};
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@ -45,10 +47,13 @@ namespace skyline {
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// If this block's start would be overlapped by the map then reuse it as a tail block
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blockEndPredecessor->virt = virtEnd;
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blockEndPredecessor->phys = tailPhys;
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blockEndPredecessor->flag = blockEndPredecessor->flag;
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blockEndPredecessor->extraInfo = blockEndPredecessor->extraInfo;
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} else {
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// Else insert a new one and we're done
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blocks.insert(blockEndSuccessor, {Block(virt, phys, flag), Block(virtEnd, tailPhys, blockEndPredecessor->flag)});
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blocks.insert(blockEndSuccessor, {Block(virt, phys, extraInfo), Block(virtEnd, tailPhys, blockEndPredecessor->extraInfo)});
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if (unmapCallback)
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unmapCallback(virt, size);
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return;
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}
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}
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@ -59,7 +64,10 @@ namespace skyline {
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blockEndPredecessor->virt = virtEnd;
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} else {
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// Else insert a new one and we're done
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blocks.insert(blockEndSuccessor, {Block(virt, phys, flag), Block(virtEnd, UnmappedPa, false)});
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blocks.insert(blockEndSuccessor, {Block(virt, phys, extraInfo), Block(virtEnd, UnmappedPa, {})});
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if (unmapCallback)
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unmapCallback(virt, size);
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return;
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}
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}
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@ -75,13 +83,12 @@ namespace skyline {
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throw exception("Unsorted block in AS map: virt: 0x{:X}", blockStartSuccessor->virt);
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} else if (blockStartSuccessor->virt == virtEnd) {
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// We need to create a new block as there are none spare that we would overwrite
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blocks.insert(blockStartSuccessor, Block(virt, phys, flag));
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return;
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blocks.insert(blockStartSuccessor, Block(virt, phys, extraInfo));
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} else {
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// Reuse a block that would otherwise be overwritten as a start block
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blockStartSuccessor->virt = virt;
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blockStartSuccessor->phys = phys;
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blockStartSuccessor->flag = flag;
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blockStartSuccessor->extraInfo = extraInfo;
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// Erase overwritten blocks
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if (auto eraseStart{std::next(blockStartSuccessor)}; blockStartSuccessor != blockEndPredecessor) {
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@ -91,6 +98,9 @@ namespace skyline {
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blocks.erase(eraseStart, blockEndPredecessor);
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}
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}
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if (unmapCallback)
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unmapCallback(virt, size);
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}
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MAP_MEMBER(void)::UnmapLocked(VaType virt, VaType size) {
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@ -141,9 +151,16 @@ namespace skyline {
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if (blockEndPredecessor->virt > virt)
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eraseBlocksWithEndUnmapped(blockEndPredecessor);
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if (unmapCallback)
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unmapCallback(virt, size);
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return; // The region is unmapped, bail out early
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} else if (blockEndSuccessor->virt == virtEnd && blockEndSuccessor->Unmapped()) {
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eraseBlocksWithEndUnmapped(blockEndSuccessor);
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if (unmapCallback)
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unmapCallback(virt, size);
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return; // The region is unmapped here and doesn't need splitting, bail out early
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} else if (blockEndSuccessor == blocks.end()) {
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// This should never happen as the end should always follow an unmapped block
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@ -164,8 +181,11 @@ namespace skyline {
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blockEndPredecessor->virt = virtEnd;
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blockEndPredecessor->phys = tailPhys;
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} else {
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blocks.insert(blockEndSuccessor, {Block(virt, UnmappedPa, false), Block(virtEnd, tailPhys, blockEndPredecessor->flag)});
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return; // The previous block is mapped and ends bef
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blocks.insert(blockEndSuccessor, {Block(virt, UnmappedPa, {}), Block(virtEnd, tailPhys, blockEndPredecessor->extraInfo)});
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if (unmapCallback)
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unmapCallback(virt, size);
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return; // The previous block is mapped and ends before
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}
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}
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@ -180,7 +200,7 @@ namespace skyline {
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// The previous block is may be unmapped, if so we don't need to insert any unmaps after it
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if (blockStartPredecessor->Mapped())
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blocks.insert(blockStartSuccessor, Block(virt, UnmappedPa, false));
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blocks.insert(blockStartSuccessor, Block(virt, UnmappedPa, {}));
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} else if (blockStartPredecessor->Unmapped()) {
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// If the previous block is unmapped
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blocks.erase(blockStartSuccessor, blockEndPredecessor);
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@ -197,13 +217,67 @@ namespace skyline {
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blocks.erase(eraseStart, blockEndPredecessor);
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}
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}
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if (unmapCallback)
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unmapCallback(virt, size);
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}
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MM_MEMBER()::FlatMemoryManager() {
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sparseMap = static_cast<u8 *>(mmap(0, SparseMapSize, PROT_READ, MAP_ANONYMOUS | MAP_PRIVATE, -1, 0));
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if (!sparseMap)
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throw exception("Failed to mmap sparse map!");
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}
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MM_MEMBER()::~FlatMemoryManager() {
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munmap(sparseMap, SparseMapSize);
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}
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MM_MEMBER(std::vector<span<u8>>)::TranslateRange(VaType virt, VaType size) {
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TRACE_EVENT("containers", "FlatMemoryManager::TranslateRange");
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std::scoped_lock lock(this->blockMutex);
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VaType virtEnd{virt + size};
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auto successor{std::upper_bound(this->blocks.begin(), this->blocks.end(), virt, [] (auto virt, const auto &block) {
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return virt < block.virt;
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})};
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auto predecessor{std::prev(successor)};
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u8 *blockPhys{predecessor->phys + (virt - predecessor->virt)};
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VaType blockSize{std::min(successor->virt - virt, size)};
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std::vector<span<u8>> ranges;
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while (size) {
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// Return a zeroed out map to emulate sparse mappings
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if (predecessor->extraInfo.sparseMapped) {
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if (blockSize > SparseMapSize)
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throw exception("Size of the sparse map is too small to fit block of size: 0x{:X}", blockSize);
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blockPhys = sparseMap;
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}
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ranges.push_back(span(blockPhys, blockSize));
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size -= blockSize;
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if (size) {
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predecessor = successor++;
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blockPhys = predecessor->phys;
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blockSize = std::min(successor->virt - predecessor->virt, size);
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}
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}
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return ranges;
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}
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MM_MEMBER(void)::Read(u8 *destination, VaType virt, VaType size) {
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std::scoped_lock lock(this->blockMutex);
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TRACE_EVENT("containers", "FlatMemoryManager::Read");
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std::scoped_lock lock(this->blockMutex);
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VaType virtEnd{virt + size};
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auto successor{std::upper_bound(this->blocks.begin(), this->blocks.end(), virt, [] (auto virt, const auto &block) {
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@ -218,12 +292,12 @@ namespace skyline {
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// Reads may span across multiple individual blocks
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while (size) {
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if (predecessor->phys == nullptr) {
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if (predecessor->flag) // Sparse mapping
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throw exception("Page fault at 0x{:X}", predecessor->virt);
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} else {
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if (predecessor->extraInfo.sparseMapped) // Sparse mappings read all zeroes
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std::memset(destination, 0, blockReadSize);
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else
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throw exception("Page fault at 0x{:X}", predecessor->virt);
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} else {
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std::memcpy(destination, blockPhys, blockReadSize);
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std::memcpy(destination, blockPhys, blockReadSize);
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}
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destination += blockReadSize;
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@ -238,10 +312,10 @@ namespace skyline {
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}
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MM_MEMBER(void)::Write(VaType virt, u8 *source, VaType size) {
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std::scoped_lock lock(this->blockMutex);
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TRACE_EVENT("containers", "FlatMemoryManager::Write");
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std::scoped_lock lock(this->blockMutex);
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VaType virtEnd{virt + size};
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auto successor{std::upper_bound(this->blocks.begin(), this->blocks.end(), virt, [] (auto virt, const auto &block) {
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@ -256,10 +330,10 @@ namespace skyline {
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// Writes may span across multiple individual blocks
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while (size) {
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if (predecessor->phys == nullptr) {
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if (!predecessor->flag) // Sparse mappings allow unmapped writes
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throw exception("Page fault at 0x{:X}", predecessor->virt);
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throw exception("Page fault at 0x{:X}", predecessor->virt);
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} else {
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std::memcpy(blockPhys, source, blockWriteSize);
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if (!predecessor->extraInfo.sparseMapped) // Sparse mappings ignore writes
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std::memcpy(blockPhys, source, blockWriteSize);
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}
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source += blockWriteSize;
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@ -277,10 +351,10 @@ namespace skyline {
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ALLOC_MEMBER()::FlatAllocator(VaType vaStart, VaType vaLimit) : Base(vaLimit), vaStart(vaStart), currentLinearAllocEnd(vaStart) {}
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ALLOC_MEMBER(VaType)::Allocate(VaType size) {
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std::scoped_lock lock(this->blockMutex);
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TRACE_EVENT("containers", "FlatAllocator::Allocate");
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std::scoped_lock lock(this->blockMutex);
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VaType allocStart{UnmappedVa};
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VaType allocEnd{currentLinearAllocEnd + size};
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@ -335,7 +409,7 @@ namespace skyline {
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}
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this->MapLocked(allocStart, true, size);
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this->MapLocked(allocStart, true, size, {});
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return allocStart;
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}
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@ -13,7 +13,7 @@ namespace skyline::kernel::type {
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if (fd < 0)
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throw exception("An error occurred while creating shared memory: {}", fd);
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host.ptr = reinterpret_cast<u8 *>(mmap(nullptr, size, PROT_READ | PROT_WRITE | PROT_EXEC, MAP_SHARED, fd, 0));
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host.ptr = static_cast<u8 *>(mmap(nullptr, size, PROT_READ | PROT_WRITE | PROT_EXEC, MAP_SHARED, fd, 0));
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if (host.ptr == MAP_FAILED)
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throw exception("An occurred while mapping shared memory: {}", strerror(errno));
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@ -28,7 +28,7 @@ namespace skyline::kernel::type {
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if (guest.Valid())
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throw exception("Mapping KSharedMemory multiple times on guest is not supported: Requested Mapping: 0x{:X} - 0x{:X} (0x{:X}), Current Mapping: 0x{:X} - 0x{:X} (0x{:X})", ptr, ptr + size, size, guest.ptr, guest.ptr + guest.size, guest.size);
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guest.ptr = reinterpret_cast<u8 *>(mmap(ptr, size, permission.Get(), MAP_SHARED | (ptr ? MAP_FIXED : 0), fd, 0));
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guest.ptr = static_cast<u8 *>(mmap(ptr, size, permission.Get(), MAP_SHARED | (ptr ? MAP_FIXED : 0), fd, 0));
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if (guest.ptr == MAP_FAILED)
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throw exception("An error occurred while mapping shared memory in guest: {}", strerror(errno));
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guest.size = size;
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@ -108,10 +108,10 @@ namespace skyline::service::nvdrv::core {
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if (internalSession) {
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if (--handleDesc->internalDupes < 0)
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state.logger->Warn("Internal duplicate count inbalance detected!");
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state.logger->Warn("Internal duplicate count imbalance detected!");
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} else {
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if (--handleDesc->dupes < 0) {
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state.logger->Warn("User duplicate count inbalance detected!");
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state.logger->Warn("User duplicate count imbalance detected!");
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} else if (handleDesc->dupes == 0) {
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// TODO: unpin
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}
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@ -53,7 +53,7 @@ namespace skyline::service::nvdrv::device::nvhost {
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u64 size{static_cast<u64>(pages) * pageSize};
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if (flags.sparse)
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state.soc->gm20b.gmmu.Map(offset, GMMU::SparsePlaceholderAddress(), size, true);
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state.soc->gm20b.gmmu.Map(offset, GMMU::SparsePlaceholderAddress(), size, {true});
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allocationMap[offset] = {
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.size = size,
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@ -77,7 +77,7 @@ namespace skyline::service::nvdrv::device::nvhost {
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// Sparse mappings shouldn't be fully unmapped, just returned to their sparse state
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// Only FreeSpace can unmap them fully
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if (mapping->sparseAlloc)
|
||||
state.soc->gm20b.gmmu.Map(offset, GMMU::SparsePlaceholderAddress(), mapping->size, true);
|
||||
state.soc->gm20b.gmmu.Map(offset, GMMU::SparsePlaceholderAddress(), mapping->size, {true});
|
||||
else
|
||||
state.soc->gm20b.gmmu.Unmap(offset, mapping->size);
|
||||
|
||||
@ -138,7 +138,7 @@ namespace skyline::service::nvdrv::device::nvhost {
|
||||
// Sparse mappings shouldn't be fully unmapped, just returned to their sparse state
|
||||
// Only FreeSpace can unmap them fully
|
||||
if (mapping->sparseAlloc)
|
||||
state.soc->gm20b.gmmu.Map(offset, GMMU::SparsePlaceholderAddress(), mapping->size, true);
|
||||
state.soc->gm20b.gmmu.Map(offset, GMMU::SparsePlaceholderAddress(), mapping->size, {true});
|
||||
else
|
||||
state.soc->gm20b.gmmu.Unmap(offset, mapping->size);
|
||||
|
||||
@ -320,7 +320,7 @@ namespace skyline::service::nvdrv::device::nvhost {
|
||||
}
|
||||
|
||||
if (!entry.handle) {
|
||||
state.soc->gm20b.gmmu.Map(virtAddr, soc::gm20b::GM20B::GMMU::SparsePlaceholderAddress(), size, true);
|
||||
state.soc->gm20b.gmmu.Map(virtAddr, soc::gm20b::GM20B::GMMU::SparsePlaceholderAddress(), size, {true});
|
||||
} else {
|
||||
auto h{core.nvMap.GetHandle(entry.handle)};
|
||||
if (!h)
|
||||
|
@ -43,7 +43,7 @@ namespace skyline::service::nvdrv {
|
||||
};
|
||||
|
||||
/**
|
||||
* @brief An bitfield struct that unpacks an ioctl number, used as an alternative to Linux's macros
|
||||
* @brief A bitfield struct that unpacks an ioctl number, used as an alternative to Linux's macros
|
||||
*/
|
||||
union IoctlDescriptor {
|
||||
struct {
|
||||
|
@ -17,7 +17,7 @@ namespace skyline::soc::gm20b::engine::maxwell3d {
|
||||
std::array<size_t, 0x80> macroPositions{}; //!< The positions of each individual macro in macro memory, there can be a maximum of 0x80 macros at any one time
|
||||
|
||||
struct {
|
||||
i32 index;
|
||||
i32 index{-1};
|
||||
std::vector<u32> arguments;
|
||||
} macroInvocation{}; //!< Data for a macro that is pending execution
|
||||
|
||||
|
Loading…
Reference in New Issue
Block a user