texture_cache: Remove preserve_contents
preserve_contents was always true. We can't assume we don't have to preserve clears because scissored and color masked clears exist. This removes preserve_contents and assumes it as true at all times.
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51c6688e21
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94b0e2e5da
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@ -345,7 +345,7 @@ void RasterizerOpenGL::ConfigureFramebuffers() {
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texture_cache.GuardRenderTargets(true);
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View depth_surface = texture_cache.GetDepthBufferSurface(true);
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View depth_surface = texture_cache.GetDepthBufferSurface();
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const auto& regs = gpu.regs;
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UNIMPLEMENTED_IF(regs.rt_separate_frag_data == 0);
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@ -354,7 +354,7 @@ void RasterizerOpenGL::ConfigureFramebuffers() {
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FramebufferCacheKey key;
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const auto colors_count = static_cast<std::size_t>(regs.rt_control.count);
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for (std::size_t index = 0; index < colors_count; ++index) {
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View color_surface{texture_cache.GetColorBufferSurface(index, true)};
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View color_surface{texture_cache.GetColorBufferSurface(index)};
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if (!color_surface) {
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continue;
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}
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@ -387,12 +387,12 @@ void RasterizerOpenGL::ConfigureClearFramebuffer(bool using_color_fb, bool using
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View color_surface;
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if (using_color_fb) {
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const std::size_t index = regs.clear_buffers.RT;
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color_surface = texture_cache.GetColorBufferSurface(index, true);
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color_surface = texture_cache.GetColorBufferSurface(index);
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texture_cache.MarkColorBufferInUse(index);
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}
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View depth_surface;
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if (using_depth_fb || using_stencil_fb) {
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depth_surface = texture_cache.GetDepthBufferSurface(true);
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depth_surface = texture_cache.GetDepthBufferSurface();
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texture_cache.MarkDepthBufferInUse();
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}
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texture_cache.GuardRenderTargets(false);
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@ -599,7 +599,7 @@ RasterizerVulkan::Texceptions RasterizerVulkan::UpdateAttachments() {
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Texceptions texceptions;
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for (std::size_t rt = 0; rt < Maxwell::NumRenderTargets; ++rt) {
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if (update_rendertargets) {
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color_attachments[rt] = texture_cache.GetColorBufferSurface(rt, true);
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color_attachments[rt] = texture_cache.GetColorBufferSurface(rt);
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}
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if (color_attachments[rt] && WalkAttachmentOverlaps(*color_attachments[rt])) {
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texceptions[rt] = true;
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@ -607,7 +607,7 @@ RasterizerVulkan::Texceptions RasterizerVulkan::UpdateAttachments() {
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}
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if (update_rendertargets) {
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zeta_attachment = texture_cache.GetDepthBufferSurface(true);
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zeta_attachment = texture_cache.GetDepthBufferSurface();
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}
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if (zeta_attachment && WalkAttachmentOverlaps(*zeta_attachment)) {
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texceptions[ZETA_TEXCEPTION_INDEX] = true;
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@ -108,7 +108,7 @@ public:
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}
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const auto params{SurfaceParams::CreateForTexture(format_lookup_table, tic, entry)};
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const auto [surface, view] = GetSurface(gpu_addr, *cpu_addr, params, true, false);
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const auto [surface, view] = GetSurface(gpu_addr, *cpu_addr, params, false);
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if (guard_samplers) {
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sampled_textures.push_back(surface);
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}
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@ -128,7 +128,7 @@ public:
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return GetNullSurface(SurfaceParams::ExpectedTarget(entry));
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}
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const auto params{SurfaceParams::CreateForImage(format_lookup_table, tic, entry)};
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const auto [surface, view] = GetSurface(gpu_addr, *cpu_addr, params, true, false);
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const auto [surface, view] = GetSurface(gpu_addr, *cpu_addr, params, false);
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if (guard_samplers) {
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sampled_textures.push_back(surface);
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}
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@ -143,7 +143,7 @@ public:
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return any_rt;
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}
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TView GetDepthBufferSurface(bool preserve_contents) {
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TView GetDepthBufferSurface() {
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std::lock_guard lock{mutex};
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auto& maxwell3d = system.GPU().Maxwell3D();
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if (!maxwell3d.dirty.flags[VideoCommon::Dirty::ZetaBuffer]) {
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@ -164,7 +164,7 @@ public:
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return {};
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}
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const auto depth_params{SurfaceParams::CreateForDepthBuffer(system)};
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auto surface_view = GetSurface(gpu_addr, *cpu_addr, depth_params, preserve_contents, true);
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auto surface_view = GetSurface(gpu_addr, *cpu_addr, depth_params, true);
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if (depth_buffer.target)
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depth_buffer.target->MarkAsRenderTarget(false, NO_RT);
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depth_buffer.target = surface_view.first;
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@ -174,7 +174,7 @@ public:
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return surface_view.second;
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}
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TView GetColorBufferSurface(std::size_t index, bool preserve_contents) {
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TView GetColorBufferSurface(std::size_t index) {
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std::lock_guard lock{mutex};
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ASSERT(index < Tegra::Engines::Maxwell3D::Regs::NumRenderTargets);
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auto& maxwell3d = system.GPU().Maxwell3D();
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@ -204,9 +204,8 @@ public:
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return {};
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}
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auto surface_view =
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GetSurface(gpu_addr, *cpu_addr, SurfaceParams::CreateForFramebuffer(system, index),
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preserve_contents, true);
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auto surface_view = GetSurface(gpu_addr, *cpu_addr,
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SurfaceParams::CreateForFramebuffer(system, index), true);
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if (render_targets[index].target)
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render_targets[index].target->MarkAsRenderTarget(false, NO_RT);
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render_targets[index].target = surface_view.first;
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@ -260,9 +259,9 @@ public:
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const std::optional<VAddr> src_cpu_addr =
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system.GPU().MemoryManager().GpuToCpuAddress(src_gpu_addr);
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std::pair<TSurface, TView> dst_surface =
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GetSurface(dst_gpu_addr, *dst_cpu_addr, dst_params, true, false);
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GetSurface(dst_gpu_addr, *dst_cpu_addr, dst_params, false);
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std::pair<TSurface, TView> src_surface =
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GetSurface(src_gpu_addr, *src_cpu_addr, src_params, true, false);
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GetSurface(src_gpu_addr, *src_cpu_addr, src_params, false);
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ImageBlit(src_surface.second, dst_surface.second, copy_config);
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dst_surface.first->MarkAsModified(true, Tick());
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}
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@ -451,22 +450,18 @@ private:
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* @param overlaps The overlapping surfaces registered in the cache.
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* @param params The parameters for the new surface.
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* @param gpu_addr The starting address of the new surface.
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* @param preserve_contents Indicates that the new surface should be loaded from memory or left
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* blank.
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* @param untopological Indicates to the recycler that the texture has no way to match the
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* overlaps due to topological reasons.
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**/
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std::pair<TSurface, TView> RecycleSurface(std::vector<TSurface>& overlaps,
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const SurfaceParams& params, const GPUVAddr gpu_addr,
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const bool preserve_contents,
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const MatchTopologyResult untopological) {
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const bool do_load = preserve_contents && Settings::values.use_accurate_gpu_emulation;
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for (auto& surface : overlaps) {
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Unregister(surface);
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}
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switch (PickStrategy(overlaps, params, gpu_addr, untopological)) {
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case RecycleStrategy::Ignore: {
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return InitializeSurface(gpu_addr, params, do_load);
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return InitializeSurface(gpu_addr, params, Settings::values.use_accurate_gpu_emulation);
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}
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case RecycleStrategy::Flush: {
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std::sort(overlaps.begin(), overlaps.end(),
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@ -476,7 +471,7 @@ private:
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for (auto& surface : overlaps) {
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FlushSurface(surface);
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}
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return InitializeSurface(gpu_addr, params, preserve_contents);
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return InitializeSurface(gpu_addr, params);
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}
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case RecycleStrategy::BufferCopy: {
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auto new_surface = GetUncachedSurface(gpu_addr, params);
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@ -485,7 +480,7 @@ private:
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}
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default: {
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UNIMPLEMENTED_MSG("Unimplemented Texture Cache Recycling Strategy!");
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return InitializeSurface(gpu_addr, params, do_load);
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return InitializeSurface(gpu_addr, params);
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}
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}
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}
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@ -621,14 +616,11 @@ private:
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* @param params The parameters on the new surface.
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* @param gpu_addr The starting address of the new surface.
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* @param cache_addr The starting address of the new surface on physical memory.
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* @param preserve_contents Indicates that the new surface should be loaded from memory or
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* left blank.
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*/
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std::optional<std::pair<TSurface, TView>> Manage3DSurfaces(std::vector<TSurface>& overlaps,
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const SurfaceParams& params,
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const GPUVAddr gpu_addr,
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const VAddr cpu_addr,
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bool preserve_contents) {
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const VAddr cpu_addr) {
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if (params.target == SurfaceTarget::Texture3D) {
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bool failed = false;
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if (params.num_levels > 1) {
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@ -677,7 +669,7 @@ private:
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return std::nullopt;
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}
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Unregister(surface);
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return InitializeSurface(gpu_addr, params, preserve_contents);
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return InitializeSurface(gpu_addr, params);
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}
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return std::nullopt;
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}
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@ -688,7 +680,7 @@ private:
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return {{surface, surface->GetMainView()}};
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}
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}
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return InitializeSurface(gpu_addr, params, preserve_contents);
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return InitializeSurface(gpu_addr, params);
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}
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}
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@ -711,13 +703,10 @@ private:
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*
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* @param gpu_addr The starting address of the candidate surface.
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* @param params The parameters on the candidate surface.
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* @param preserve_contents Indicates that the new surface should be loaded from memory or
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* left blank.
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* @param is_render Whether or not the surface is a render target.
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**/
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std::pair<TSurface, TView> GetSurface(const GPUVAddr gpu_addr, const VAddr cpu_addr,
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const SurfaceParams& params, bool preserve_contents,
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bool is_render) {
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const SurfaceParams& params, bool is_render) {
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// Step 1
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// Check Level 1 Cache for a fast structural match. If candidate surface
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// matches at certain level we are pretty much done.
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@ -726,8 +715,7 @@ private:
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const auto topological_result = current_surface->MatchesTopology(params);
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if (topological_result != MatchTopologyResult::FullMatch) {
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std::vector<TSurface> overlaps{current_surface};
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return RecycleSurface(overlaps, params, gpu_addr, preserve_contents,
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topological_result);
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return RecycleSurface(overlaps, params, gpu_addr, topological_result);
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}
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const auto struct_result = current_surface->MatchesStructure(params);
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@ -752,7 +740,7 @@ private:
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// If none are found, we are done. we just load the surface and create it.
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if (overlaps.empty()) {
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return InitializeSurface(gpu_addr, params, preserve_contents);
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return InitializeSurface(gpu_addr, params);
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}
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// Step 3
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@ -762,15 +750,13 @@ private:
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for (const auto& surface : overlaps) {
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const auto topological_result = surface->MatchesTopology(params);
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if (topological_result != MatchTopologyResult::FullMatch) {
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return RecycleSurface(overlaps, params, gpu_addr, preserve_contents,
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topological_result);
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return RecycleSurface(overlaps, params, gpu_addr, topological_result);
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}
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}
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// Check if it's a 3D texture
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if (params.block_depth > 0) {
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auto surface =
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Manage3DSurfaces(overlaps, params, gpu_addr, cpu_addr, preserve_contents);
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auto surface = Manage3DSurfaces(overlaps, params, gpu_addr, cpu_addr);
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if (surface) {
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return *surface;
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}
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@ -790,8 +776,7 @@ private:
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return *view;
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}
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}
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return RecycleSurface(overlaps, params, gpu_addr, preserve_contents,
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MatchTopologyResult::FullMatch);
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return RecycleSurface(overlaps, params, gpu_addr, MatchTopologyResult::FullMatch);
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}
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// Now we check if the candidate is a mipmap/layer of the overlap
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std::optional<TView> view =
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@ -815,7 +800,7 @@ private:
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pair.first->EmplaceView(params, gpu_addr, candidate_size);
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if (mirage_view)
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return {pair.first, *mirage_view};
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return RecycleSurface(overlaps, params, gpu_addr, preserve_contents,
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return RecycleSurface(overlaps, params, gpu_addr,
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MatchTopologyResult::FullMatch);
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}
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return {current_surface, *view};
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@ -831,8 +816,7 @@ private:
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}
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}
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// We failed all the tests, recycle the overlaps into a new texture.
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return RecycleSurface(overlaps, params, gpu_addr, preserve_contents,
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MatchTopologyResult::FullMatch);
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return RecycleSurface(overlaps, params, gpu_addr, MatchTopologyResult::FullMatch);
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}
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/**
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@ -990,10 +974,10 @@ private:
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}
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std::pair<TSurface, TView> InitializeSurface(GPUVAddr gpu_addr, const SurfaceParams& params,
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bool preserve_contents) {
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bool do_load = true) {
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auto new_surface{GetUncachedSurface(gpu_addr, params)};
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Register(new_surface);
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if (preserve_contents) {
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if (do_load) {
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LoadSurface(new_surface);
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}
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return {new_surface, new_surface->GetMainView()};
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