From fa342cae227666c861806b9bf63e4286aff1e4d7 Mon Sep 17 00:00:00 2001 From: Morph <39850852+Morph1984@users.noreply.github.com> Date: Wed, 29 Jun 2022 20:33:04 -0400 Subject: address_space: Address feedback --- src/common/address_space.h | 105 ++++--- src/common/address_space.inc | 319 +++++++++++---------- .../hle/service/nvdrv/devices/nvhost_as_gpu.cpp | 8 +- 3 files changed, 237 insertions(+), 195 deletions(-) (limited to 'src') diff --git a/src/common/address_space.h b/src/common/address_space.h index 5b3832f07..bf649018c 100644 --- a/src/common/address_space.h +++ b/src/common/address_space.h @@ -23,9 +23,29 @@ template requires AddressSpaceValid class FlatAddressSpaceMap { -private: - std::function - unmapCallback{}; //!< Callback called when the mappings in an region have changed +public: + /// The maximum VA that this AS can technically reach + static constexpr VaType VaMaximum{(1ULL << (AddressSpaceBits - 1)) + + ((1ULL << (AddressSpaceBits - 1)) - 1)}; + + explicit FlatAddressSpaceMap(VaType va_limit, + std::function unmap_callback = {}); + + FlatAddressSpaceMap() = default; + + void Map(VaType virt, PaType phys, VaType size, ExtraBlockInfo extra_info = {}) { + std::scoped_lock lock(block_mutex); + MapLocked(virt, phys, size, extra_info); + } + + void Unmap(VaType virt, VaType size) { + std::scoped_lock lock(block_mutex); + UnmapLocked(virt, size); + } + + VaType GetVALimit() const { + return va_limit; + } protected: /** @@ -33,68 +53,55 @@ protected: * another block with a different phys address is hit */ struct Block { - VaType virt{UnmappedVa}; //!< VA of the block - PaType phys{UnmappedPa}; //!< PA of the block, will increase 1-1 with VA until a new block - //!< is encountered - [[no_unique_address]] ExtraBlockInfo extraInfo; + /// VA of the block + VaType virt{UnmappedVa}; + /// PA of the block, will increase 1-1 with VA until a new block is encountered + PaType phys{UnmappedPa}; + [[no_unique_address]] ExtraBlockInfo extra_info; Block() = default; - Block(VaType virt_, PaType phys_, ExtraBlockInfo extraInfo_) - : virt(virt_), phys(phys_), extraInfo(extraInfo_) {} + Block(VaType virt_, PaType phys_, ExtraBlockInfo extra_info_) + : virt(virt_), phys(phys_), extra_info(extra_info_) {} - constexpr bool Valid() { + bool Valid() const { return virt != UnmappedVa; } - constexpr bool Mapped() { + bool Mapped() const { return phys != UnmappedPa; } - constexpr bool Unmapped() { + bool Unmapped() const { return phys == UnmappedPa; } - bool operator<(const VaType& pVirt) const { - return virt < pVirt; + bool operator<(const VaType& p_virt) const { + return virt < p_virt; } }; - std::mutex blockMutex; - std::vector blocks{Block{}}; - /** * @brief Maps a PA range into the given AS region - * @note blockMutex MUST be locked when calling this + * @note block_mutex MUST be locked when calling this */ - void MapLocked(VaType virt, PaType phys, VaType size, ExtraBlockInfo extraInfo); + void MapLocked(VaType virt, PaType phys, VaType size, ExtraBlockInfo extra_info); /** * @brief Unmaps the given range and merges it with other unmapped regions - * @note blockMutex MUST be locked when calling this + * @note block_mutex MUST be locked when calling this */ void UnmapLocked(VaType virt, VaType size); -public: - static constexpr VaType VaMaximum{(1ULL << (AddressSpaceBits - 1)) + - ((1ULL << (AddressSpaceBits - 1)) - - 1)}; //!< The maximum VA that this AS can technically reach - - VaType vaLimit{VaMaximum}; //!< A soft limit on the maximum VA of the AS - - FlatAddressSpaceMap(VaType vaLimit, std::function unmapCallback = {}); - - FlatAddressSpaceMap() = default; + std::mutex block_mutex; + std::vector blocks{Block{}}; - void Map(VaType virt, PaType phys, VaType size, ExtraBlockInfo extraInfo = {}) { - std::scoped_lock lock(blockMutex); - MapLocked(virt, phys, size, extraInfo); - } + /// a soft limit on the maximum VA of the AS + VaType va_limit{VaMaximum}; - void Unmap(VaType virt, VaType size) { - std::scoped_lock lock(blockMutex); - UnmapLocked(virt, size); - } +private: + /// Callback called when the mappings in an region have changed + std::function unmap_callback{}; }; /** @@ -108,14 +115,8 @@ class FlatAllocator private: using Base = FlatAddressSpaceMap; - VaType currentLinearAllocEnd; //!< The end address for the initial linear allocation pass, once - //!< this reaches the AS limit the slower allocation path will be - //!< used - public: - VaType vaStart; //!< The base VA of the allocator, no allocations will be below this - - FlatAllocator(VaType vaStart, VaType vaLimit = Base::VaMaximum); + explicit FlatAllocator(VaType va_start, VaType va_limit = Base::VaMaximum); /** * @brief Allocates a region in the AS of the given size and returns its address @@ -131,5 +132,19 @@ public: * @brief Frees an AS region so it can be used again */ void Free(VaType virt, VaType size); + + VaType GetVAStart() const { + return va_start; + } + +private: + /// The base VA of the allocator, no allocations will be below this + VaType va_start; + + /** + * The end address for the initial linear allocation pass + * Once this reaches the AS limit the slower allocation path will be used + */ + VaType current_linear_alloc_end; }; } // namespace Common diff --git a/src/common/address_space.inc b/src/common/address_space.inc index a063782b3..3661b298e 100644 --- a/src/common/address_space.inc +++ b/src/common/address_space.inc @@ -30,137 +30,151 @@ FlatAllocator namespace Common { -MAP_MEMBER_CONST()::FlatAddressSpaceMap(VaType vaLimit_, - std::function unmapCallback_) - : unmapCallback(std::move(unmapCallback_)), vaLimit(vaLimit_) { - if (vaLimit > VaMaximum) +MAP_MEMBER_CONST()::FlatAddressSpaceMap(VaType va_limit_, + std::function unmap_callback_) + : va_limit{va_limit_}, unmap_callback{std::move(unmap_callback_)} { + if (va_limit > VaMaximum) { UNREACHABLE_MSG("Invalid VA limit!"); + } } -MAP_MEMBER(void)::MapLocked(VaType virt, PaType phys, VaType size, ExtraBlockInfo extraInfo) { - VaType virtEnd{virt + size}; +MAP_MEMBER(void)::MapLocked(VaType virt, PaType phys, VaType size, ExtraBlockInfo extra_info) { + VaType virt_end{virt + size}; - if (virtEnd > vaLimit) - UNREACHABLE_MSG("Trying to map a block past the VA limit: virtEnd: 0x{:X}, vaLimit: 0x{:X}", - virtEnd, vaLimit); + if (virt_end > va_limit) { + UNREACHABLE_MSG( + "Trying to map a block past the VA limit: virt_end: 0x{:X}, va_limit: 0x{:X}", virt_end, + va_limit); + } - auto blockEndSuccessor{std::lower_bound(blocks.begin(), blocks.end(), virtEnd)}; - if (blockEndSuccessor == blocks.begin()) - UNREACHABLE_MSG("Trying to map a block before the VA start: virtEnd: 0x{:X}", virtEnd); + auto block_end_successor{std::lower_bound(blocks.begin(), blocks.end(), virt_end)}; + if (block_end_successor == blocks.begin()) { + UNREACHABLE_MSG("Trying to map a block before the VA start: virt_end: 0x{:X}", virt_end); + } - auto blockEndPredecessor{std::prev(blockEndSuccessor)}; + auto block_end_predecessor{std::prev(block_end_successor)}; - if (blockEndSuccessor != blocks.end()) { + if (block_end_successor != blocks.end()) { // We have blocks in front of us, if one is directly in front then we don't have to add a // tail - if (blockEndSuccessor->virt != virtEnd) { + if (block_end_successor->virt != virt_end) { PaType tailPhys{[&]() -> PaType { if constexpr (!PaContigSplit) { - return blockEndPredecessor - ->phys; // Always propagate unmapped regions rather than calculating offset + // Always propagate unmapped regions rather than calculating offset + return block_end_predecessor->phys; } else { - if (blockEndPredecessor->Unmapped()) - return blockEndPredecessor->phys; // Always propagate unmapped regions - // rather than calculating offset - else - return blockEndPredecessor->phys + virtEnd - blockEndPredecessor->virt; + if (block_end_predecessor->Unmapped()) { + // Always propagate unmapped regions rather than calculating offset + return block_end_predecessor->phys; + } else { + return block_end_predecessor->phys + virt_end - block_end_predecessor->virt; + } } }()}; - if (blockEndPredecessor->virt >= virt) { + if (block_end_predecessor->virt >= virt) { // If this block's start would be overlapped by the map then reuse it as a tail // block - blockEndPredecessor->virt = virtEnd; - blockEndPredecessor->phys = tailPhys; - blockEndPredecessor->extraInfo = blockEndPredecessor->extraInfo; + block_end_predecessor->virt = virt_end; + block_end_predecessor->phys = tailPhys; + block_end_predecessor->extra_info = block_end_predecessor->extra_info; // No longer predecessor anymore - blockEndSuccessor = blockEndPredecessor--; + block_end_successor = block_end_predecessor--; } else { // Else insert a new one and we're done - blocks.insert(blockEndSuccessor, - {Block(virt, phys, extraInfo), - Block(virtEnd, tailPhys, blockEndPredecessor->extraInfo)}); - if (unmapCallback) - unmapCallback(virt, size); + blocks.insert(block_end_successor, + {Block(virt, phys, extra_info), + Block(virt_end, tailPhys, block_end_predecessor->extra_info)}); + if (unmap_callback) { + unmap_callback(virt, size); + } return; } } } else { - // blockEndPredecessor will always be unmapped as blocks has to be terminated by an unmapped - // chunk - if (blockEndPredecessor != blocks.begin() && blockEndPredecessor->virt >= virt) { + // block_end_predecessor will always be unmapped as blocks has to be terminated by an + // unmapped chunk + if (block_end_predecessor != blocks.begin() && block_end_predecessor->virt >= virt) { // Move the unmapped block start backwards - blockEndPredecessor->virt = virtEnd; + block_end_predecessor->virt = virt_end; // No longer predecessor anymore - blockEndSuccessor = blockEndPredecessor--; + block_end_successor = block_end_predecessor--; } else { // Else insert a new one and we're done - blocks.insert(blockEndSuccessor, - {Block(virt, phys, extraInfo), Block(virtEnd, UnmappedPa, {})}); - if (unmapCallback) - unmapCallback(virt, size); + blocks.insert(block_end_successor, + {Block(virt, phys, extra_info), Block(virt_end, UnmappedPa, {})}); + if (unmap_callback) { + unmap_callback(virt, size); + } return; } } - auto blockStartSuccessor{blockEndSuccessor}; + auto block_start_successor{block_end_successor}; // Walk the block vector to find the start successor as this is more efficient than another // binary search in most scenarios - while (std::prev(blockStartSuccessor)->virt >= virt) - blockStartSuccessor--; + while (std::prev(block_start_successor)->virt >= virt) { + block_start_successor--; + } // Check that the start successor is either the end block or something in between - if (blockStartSuccessor->virt > virtEnd) { - UNREACHABLE_MSG("Unsorted block in AS map: virt: 0x{:X}", blockStartSuccessor->virt); - } else if (blockStartSuccessor->virt == virtEnd) { + if (block_start_successor->virt > virt_end) { + UNREACHABLE_MSG("Unsorted block in AS map: virt: 0x{:X}", block_start_successor->virt); + } else if (block_start_successor->virt == virt_end) { // We need to create a new block as there are none spare that we would overwrite - blocks.insert(blockStartSuccessor, Block(virt, phys, extraInfo)); + blocks.insert(block_start_successor, Block(virt, phys, extra_info)); } else { // Erase overwritten blocks - if (auto eraseStart{std::next(blockStartSuccessor)}; eraseStart != blockEndSuccessor) - blocks.erase(eraseStart, blockEndSuccessor); + if (auto eraseStart{std::next(block_start_successor)}; eraseStart != block_end_successor) { + blocks.erase(eraseStart, block_end_successor); + } // Reuse a block that would otherwise be overwritten as a start block - blockStartSuccessor->virt = virt; - blockStartSuccessor->phys = phys; - blockStartSuccessor->extraInfo = extraInfo; + block_start_successor->virt = virt; + block_start_successor->phys = phys; + block_start_successor->extra_info = extra_info; } - if (unmapCallback) - unmapCallback(virt, size); + if (unmap_callback) { + unmap_callback(virt, size); + } } MAP_MEMBER(void)::UnmapLocked(VaType virt, VaType size) { - VaType virtEnd{virt + size}; + VaType virt_end{virt + size}; - if (virtEnd > vaLimit) - UNREACHABLE_MSG("Trying to map a block past the VA limit: virtEnd: 0x{:X}, vaLimit: 0x{:X}", - virtEnd, vaLimit); + if (virt_end > va_limit) { + UNREACHABLE_MSG( + "Trying to map a block past the VA limit: virt_end: 0x{:X}, va_limit: 0x{:X}", virt_end, + va_limit); + } - auto blockEndSuccessor{std::lower_bound(blocks.begin(), blocks.end(), virtEnd)}; - if (blockEndSuccessor == blocks.begin()) - UNREACHABLE_MSG("Trying to unmap a block before the VA start: virtEnd: 0x{:X}", virtEnd); + auto block_end_successor{std::lower_bound(blocks.begin(), blocks.end(), virt_end)}; + if (block_end_successor == blocks.begin()) { + UNREACHABLE_MSG("Trying to unmap a block before the VA start: virt_end: 0x{:X}", virt_end); + } - auto blockEndPredecessor{std::prev(blockEndSuccessor)}; + auto block_end_predecessor{std::prev(block_end_successor)}; - auto walkBackToPredecessor{[&](auto iter) { - while (iter->virt >= virt) + auto walk_back_to_predecessor{[&](auto iter) { + while (iter->virt >= virt) { iter--; + } return iter; }}; - auto eraseBlocksWithEndUnmapped{[&](auto unmappedEnd) { - auto blockStartPredecessor{walkBackToPredecessor(unmappedEnd)}; - auto blockStartSuccessor{std::next(blockStartPredecessor)}; + auto erase_blocks_with_end_unmapped{[&](auto unmappedEnd) { + auto block_start_predecessor{walk_back_to_predecessor(unmappedEnd)}; + auto block_start_successor{std::next(block_start_predecessor)}; auto eraseEnd{[&]() { - if (blockStartPredecessor->Unmapped()) { + if (block_start_predecessor->Unmapped()) { // If the start predecessor is unmapped then we can erase everything in our region // and be done return std::next(unmappedEnd); @@ -174,158 +188,171 @@ MAP_MEMBER(void)::UnmapLocked(VaType virt, VaType size) { // We can't have two unmapped regions after each other if (eraseEnd != blocks.end() && - (eraseEnd == blockStartSuccessor || - (blockStartPredecessor->Unmapped() && eraseEnd->Unmapped()))) + (eraseEnd == block_start_successor || + (block_start_predecessor->Unmapped() && eraseEnd->Unmapped()))) { UNREACHABLE_MSG("Multiple contiguous unmapped regions are unsupported!"); + } - blocks.erase(blockStartSuccessor, eraseEnd); + blocks.erase(block_start_successor, eraseEnd); }}; // We can avoid any splitting logic if these are the case - if (blockEndPredecessor->Unmapped()) { - if (blockEndPredecessor->virt > virt) - eraseBlocksWithEndUnmapped(blockEndPredecessor); + if (block_end_predecessor->Unmapped()) { + if (block_end_predecessor->virt > virt) { + erase_blocks_with_end_unmapped(block_end_predecessor); + } - if (unmapCallback) - unmapCallback(virt, size); + if (unmap_callback) { + unmap_callback(virt, size); + } return; // The region is unmapped, bail out early - } else if (blockEndSuccessor->virt == virtEnd && blockEndSuccessor->Unmapped()) { - eraseBlocksWithEndUnmapped(blockEndSuccessor); + } else if (block_end_successor->virt == virt_end && block_end_successor->Unmapped()) { + erase_blocks_with_end_unmapped(block_end_successor); - if (unmapCallback) - unmapCallback(virt, size); + if (unmap_callback) { + unmap_callback(virt, size); + } return; // The region is unmapped here and doesn't need splitting, bail out early - } else if (blockEndSuccessor == blocks.end()) { + } else if (block_end_successor == blocks.end()) { // This should never happen as the end should always follow an unmapped block UNREACHABLE_MSG("Unexpected Memory Manager state!"); - } else if (blockEndSuccessor->virt != virtEnd) { + } else if (block_end_successor->virt != virt_end) { // If one block is directly in front then we don't have to add a tail // The previous block is mapped so we will need to add a tail with an offset PaType tailPhys{[&]() { - if constexpr (PaContigSplit) - return blockEndPredecessor->phys + virtEnd - blockEndPredecessor->virt; - else - return blockEndPredecessor->phys; + if constexpr (PaContigSplit) { + return block_end_predecessor->phys + virt_end - block_end_predecessor->virt; + } else { + return block_end_predecessor->phys; + } }()}; - if (blockEndPredecessor->virt >= virt) { + if (block_end_predecessor->virt >= virt) { // If this block's start would be overlapped by the unmap then reuse it as a tail block - blockEndPredecessor->virt = virtEnd; - blockEndPredecessor->phys = tailPhys; + block_end_predecessor->virt = virt_end; + block_end_predecessor->phys = tailPhys; // No longer predecessor anymore - blockEndSuccessor = blockEndPredecessor--; + block_end_successor = block_end_predecessor--; } else { - blocks.insert(blockEndSuccessor, + blocks.insert(block_end_successor, {Block(virt, UnmappedPa, {}), - Block(virtEnd, tailPhys, blockEndPredecessor->extraInfo)}); - if (unmapCallback) - unmapCallback(virt, size); + Block(virt_end, tailPhys, block_end_predecessor->extra_info)}); + if (unmap_callback) { + unmap_callback(virt, size); + } - return; // The previous block is mapped and ends before + // The previous block is mapped and ends before + return; } } // Walk the block vector to find the start predecessor as this is more efficient than another // binary search in most scenarios - auto blockStartPredecessor{walkBackToPredecessor(blockEndSuccessor)}; - auto blockStartSuccessor{std::next(blockStartPredecessor)}; + auto block_start_predecessor{walk_back_to_predecessor(block_end_successor)}; + auto block_start_successor{std::next(block_start_predecessor)}; - if (blockStartSuccessor->virt > virtEnd) { - UNREACHABLE_MSG("Unsorted block in AS map: virt: 0x{:X}", blockStartSuccessor->virt); - } else if (blockStartSuccessor->virt == virtEnd) { + if (block_start_successor->virt > virt_end) { + UNREACHABLE_MSG("Unsorted block in AS map: virt: 0x{:X}", block_start_successor->virt); + } else if (block_start_successor->virt == virt_end) { // There are no blocks between the start and the end that would let us skip inserting a new // one for head // The previous block is may be unmapped, if so we don't need to insert any unmaps after it - if (blockStartPredecessor->Mapped()) - blocks.insert(blockStartSuccessor, Block(virt, UnmappedPa, {})); - } else if (blockStartPredecessor->Unmapped()) { + if (block_start_predecessor->Mapped()) { + blocks.insert(block_start_successor, Block(virt, UnmappedPa, {})); + } + } else if (block_start_predecessor->Unmapped()) { // If the previous block is unmapped - blocks.erase(blockStartSuccessor, blockEndPredecessor); + blocks.erase(block_start_successor, block_end_predecessor); } else { // Erase overwritten blocks, skipping the first one as we have written the unmapped start // block there - if (auto eraseStart{std::next(blockStartSuccessor)}; eraseStart != blockEndSuccessor) - blocks.erase(eraseStart, blockEndSuccessor); + if (auto eraseStart{std::next(block_start_successor)}; eraseStart != block_end_successor) { + blocks.erase(eraseStart, block_end_successor); + } // Add in the unmapped block header - blockStartSuccessor->virt = virt; - blockStartSuccessor->phys = UnmappedPa; + block_start_successor->virt = virt; + block_start_successor->phys = UnmappedPa; } - if (unmapCallback) - unmapCallback(virt, size); + if (unmap_callback) + unmap_callback(virt, size); } -ALLOC_MEMBER_CONST()::FlatAllocator(VaType vaStart_, VaType vaLimit_) - : Base(vaLimit_), currentLinearAllocEnd(vaStart_), vaStart(vaStart_) {} +ALLOC_MEMBER_CONST()::FlatAllocator(VaType va_start_, VaType va_limit_) + : Base{va_limit_}, va_start{va_start_}, current_linear_alloc_end{va_start_} {} ALLOC_MEMBER(VaType)::Allocate(VaType size) { - std::scoped_lock lock(this->blockMutex); + std::scoped_lock lock(this->block_mutex); - VaType allocStart{UnmappedVa}; - VaType allocEnd{currentLinearAllocEnd + size}; + VaType alloc_start{UnmappedVa}; + VaType alloc_end{current_linear_alloc_end + size}; // Avoid searching backwards in the address space if possible - if (allocEnd >= currentLinearAllocEnd && allocEnd <= this->vaLimit) { - auto allocEndSuccessor{ - std::lower_bound(this->blocks.begin(), this->blocks.end(), allocEnd)}; - if (allocEndSuccessor == this->blocks.begin()) + if (alloc_end >= current_linear_alloc_end && alloc_end <= this->va_limit) { + auto alloc_end_successor{ + std::lower_bound(this->blocks.begin(), this->blocks.end(), alloc_end)}; + if (alloc_end_successor == this->blocks.begin()) { UNREACHABLE_MSG("First block in AS map is invalid!"); + } - auto allocEndPredecessor{std::prev(allocEndSuccessor)}; - if (allocEndPredecessor->virt <= currentLinearAllocEnd) { - allocStart = currentLinearAllocEnd; + auto alloc_end_predecessor{std::prev(alloc_end_successor)}; + if (alloc_end_predecessor->virt <= current_linear_alloc_end) { + alloc_start = current_linear_alloc_end; } else { // Skip over fixed any mappings in front of us - while (allocEndSuccessor != this->blocks.end()) { - if (allocEndSuccessor->virt - allocEndPredecessor->virt < size || - allocEndPredecessor->Mapped()) { - allocStart = allocEndPredecessor->virt; + while (alloc_end_successor != this->blocks.end()) { + if (alloc_end_successor->virt - alloc_end_predecessor->virt < size || + alloc_end_predecessor->Mapped()) { + alloc_start = alloc_end_predecessor->virt; break; } - allocEndPredecessor = allocEndSuccessor++; + alloc_end_predecessor = alloc_end_successor++; // Use the VA limit to calculate if we can fit in the final block since it has no // successor - if (allocEndSuccessor == this->blocks.end()) { - allocEnd = allocEndPredecessor->virt + size; + if (alloc_end_successor == this->blocks.end()) { + alloc_end = alloc_end_predecessor->virt + size; - if (allocEnd >= allocEndPredecessor->virt && allocEnd <= this->vaLimit) - allocStart = allocEndPredecessor->virt; + if (alloc_end >= alloc_end_predecessor->virt && alloc_end <= this->va_limit) { + alloc_start = alloc_end_predecessor->virt; + } } } } } - if (allocStart != UnmappedVa) { - currentLinearAllocEnd = allocStart + size; + if (alloc_start != UnmappedVa) { + current_linear_alloc_end = alloc_start + size; } else { // If linear allocation overflows the AS then find a gap - if (this->blocks.size() <= 2) + if (this->blocks.size() <= 2) { UNREACHABLE_MSG("Unexpected allocator state!"); + } - auto searchPredecessor{this->blocks.begin()}; - auto searchSuccessor{std::next(searchPredecessor)}; + auto search_predecessor{this->blocks.begin()}; + auto search_successor{std::next(search_predecessor)}; - while (searchSuccessor != this->blocks.end() && - (searchSuccessor->virt - searchPredecessor->virt < size || - searchPredecessor->Mapped())) { - searchPredecessor = searchSuccessor++; + while (search_successor != this->blocks.end() && + (search_successor->virt - search_predecessor->virt < size || + search_predecessor->Mapped())) { + search_predecessor = search_successor++; } - if (searchSuccessor != this->blocks.end()) - allocStart = searchPredecessor->virt; - else + if (search_successor != this->blocks.end()) { + alloc_start = search_predecessor->virt; + } else { return {}; // AS is full + } } - this->MapLocked(allocStart, true, size, {}); - return allocStart; + this->MapLocked(alloc_start, true, size, {}); + return alloc_start; } ALLOC_MEMBER(void)::AllocateFixed(VaType virt, VaType size) { diff --git a/src/core/hle/service/nvdrv/devices/nvhost_as_gpu.cpp b/src/core/hle/service/nvdrv/devices/nvhost_as_gpu.cpp index b48f7fcaf..7a95f5305 100644 --- a/src/core/hle/service/nvdrv/devices/nvhost_as_gpu.cpp +++ b/src/core/hle/service/nvdrv/devices/nvhost_as_gpu.cpp @@ -472,16 +472,16 @@ void nvhost_as_gpu::GetVARegionsImpl(IoctlGetVaRegions& params) { params.regions = std::array{ VaRegion{ - .offset = vm.small_page_allocator->vaStart << VM::PAGE_SIZE_BITS, + .offset = vm.small_page_allocator->GetVAStart() << VM::PAGE_SIZE_BITS, .page_size = VM::YUZU_PAGESIZE, ._pad0_{}, - .pages = vm.small_page_allocator->vaLimit - vm.small_page_allocator->vaStart, + .pages = vm.small_page_allocator->GetVALimit() - vm.small_page_allocator->GetVAStart(), }, VaRegion{ - .offset = vm.big_page_allocator->vaStart << vm.big_page_size_bits, + .offset = vm.big_page_allocator->GetVAStart() << vm.big_page_size_bits, .page_size = vm.big_page_size, ._pad0_{}, - .pages = vm.big_page_allocator->vaLimit - vm.big_page_allocator->vaStart, + .pages = vm.big_page_allocator->GetVALimit() - vm.big_page_allocator->GetVAStart(), }, }; } -- cgit v1.2.3