#include "boo/graphicsdev/NX.hpp" #include #include #include #include #include "boo/IGraphicsContext.hpp" #include "boo/graphicsdev/GLSLMacros.hpp" #include "lib/graphicsdev/Common.hpp" #include "main/shaderobj.h" #include "st_program.h" #include "pipe/p_state.h" #include "util/u_format.h" #include "state_tracker/winsys_handle.h" extern "C" { #include "main/viewport.h" #include "nouveau_winsys.h" #include "nouveau_screen.h" #include "nvc0/nvc0_program.h" #include "gallium/winsys/nouveau/switch/nouveau_switch_public.h" } #include #include #include namespace boo { static logvisor::Module Log("boo::NX"); struct NXCommandQueue; class NXDataFactoryImpl : public NXDataFactory, public GraphicsDataFactoryHead { public: float m_gamma = 1.f; ObjToken m_gammaBinding; IGraphicsContext* m_parent; NXContext* m_ctx; NXDataFactoryImpl(IGraphicsContext* parent, NXContext* ctx) : m_parent(parent), m_ctx(ctx) {} Platform platform() const { return Platform::NX; } const SystemChar* platformName() const { return _SYS_STR("NX"); } void SetupGammaResources() {} void DestroyGammaResources() {} void commitTransaction(const FactoryCommitFunc& __BooTraceArgs); boo::ObjToken newPoolBuffer(BufferUse use, size_t stride, size_t count __BooTraceArgs); void setDisplayGamma(float gamma) { m_gamma = gamma; // if (gamma != 1.f) // UpdateGammaLUT(m_gammaLUT.get(), gamma); } bool isTessellationSupported(uint32_t& maxPatchSizeOut) { maxPatchSizeOut = 0; if (!m_ctx->m_st->ctx->Extensions.ARB_tessellation_shader) return false; maxPatchSizeOut = m_ctx->m_st->ctx->Const.MaxPatchVertices; return true; } }; struct NXData : BaseGraphicsData { NXContext* m_ctx; /* Vertex, Index, Uniform */ struct pipe_resource* m_constantBuffers[3] = {}; explicit NXData(NXDataFactoryImpl& head __BooTraceArgs) : BaseGraphicsData(head __BooTraceArgsUse), m_ctx(head.m_ctx) {} ~NXData() { for (int i = 0; i < 3; ++i) pipe_resource_reference(&m_constantBuffers[i], nullptr); } }; struct NXPool : BaseGraphicsPool { NXContext* m_ctx; struct pipe_resource* m_constantBuffer; explicit NXPool(NXDataFactoryImpl& head __BooTraceArgs) : BaseGraphicsPool(head __BooTraceArgsUse), m_ctx(head.m_ctx) {} ~NXPool() { pipe_resource_reference(&m_constantBuffer, nullptr); } }; static const unsigned USE_TABLE[] = {0, PIPE_BIND_VERTEX_BUFFER, PIPE_BIND_INDEX_BUFFER, PIPE_BIND_CONSTANT_BUFFER}; union nx_buffer_info { pipe_vertex_buffer v; pipe_constant_buffer c; }; class NXGraphicsBufferS : public GraphicsDataNode { friend class NXDataFactory; friend struct NXCommandQueue; NXContext* m_ctx; size_t m_sz; std::unique_ptr m_stagingBuf; NXGraphicsBufferS(const boo::ObjToken& parent, BufferUse use, NXContext* ctx, const void* data, size_t stride, size_t count) : GraphicsDataNode(parent) , m_ctx(ctx) , m_sz(stride * count) , m_stagingBuf(new uint8_t[m_sz]) , m_use(use) { memmove(m_stagingBuf.get(), data, m_sz); if (m_use == BufferUse::Vertex) m_bufferInfo.v.stride = uint16_t(stride); } public: size_t size() const { return m_sz; } nx_buffer_info m_bufferInfo; BufferUse m_use; unsigned sizeForGPU(NXContext* ctx, unsigned offset) { if (m_use == BufferUse::Uniform) { unsigned minOffset = std::max(256u, ctx->m_st->ctx->Const.UniformBufferOffsetAlignment); offset = (offset + minOffset - 1) & ~(minOffset - 1); m_bufferInfo.c.buffer_offset = offset; m_bufferInfo.c.buffer_size = m_sz; } else { m_bufferInfo.v.buffer_offset = offset; } offset += m_sz; return offset; } void placeForGPU(struct pipe_resource* bufObj, uint8_t* buf) { if (m_use == BufferUse::Uniform) m_bufferInfo.c.buffer = bufObj; else m_bufferInfo.v.buffer.resource = bufObj; memmove(buf + m_bufferInfo.v.buffer_offset, m_stagingBuf.get(), m_sz); m_stagingBuf.reset(); } }; template class NXGraphicsBufferD : public GraphicsDataNode { friend class NXDataFactory; friend class NXDataFactoryImpl; friend struct NXCommandQueue; NXContext* m_ctx; size_t m_cpuSz; std::unique_ptr m_cpuBuf; int m_validSlots = 0; NXGraphicsBufferD(const boo::ObjToken& parent, BufferUse use, NXContext* ctx, size_t stride, size_t count) : GraphicsDataNode(parent) , m_ctx(ctx) , m_cpuSz(stride * count) , m_cpuBuf(new uint8_t[m_cpuSz]) , m_use(use) { if (m_use == BufferUse::Vertex) { m_bufferInfo[0].v.stride = stride; m_bufferInfo[1].v.stride = stride; } } void update(int b) { int slot = 1 << b; if ((slot & m_validSlots) == 0) { memcpy(m_bufferPtrs[b], m_cpuBuf.get(), m_cpuSz); m_validSlots |= slot; } } public: nx_buffer_info m_bufferInfo[2]; uint8_t* m_bufferPtrs[2] = {}; BufferUse m_use; void load(const void* data, size_t sz) { size_t bufSz = std::min(sz, m_cpuSz); memmove(m_cpuBuf.get(), data, bufSz); m_validSlots = 0; } void* map(size_t sz) { if (sz > m_cpuSz) return nullptr; return m_cpuBuf.get(); } void unmap() { m_validSlots = 0; } unsigned sizeForGPU(NXContext* ctx, unsigned offset) { for (int i = 0; i < 2; ++i) { if (m_use == BufferUse::Uniform) { size_t minOffset = std::max(256u, ctx->m_st->ctx->Const.UniformBufferOffsetAlignment); offset = (offset + minOffset - 1) & ~(minOffset - 1); m_bufferInfo[i].c.buffer_offset = offset; m_bufferInfo[i].c.buffer_size = m_cpuSz; } else { m_bufferInfo[i].v.buffer_offset = offset; } offset += m_cpuSz; } return offset; } void placeForGPU(struct pipe_resource* bufObj, uint8_t* buf) { if (m_use == BufferUse::Uniform) { m_bufferInfo[0].c.buffer = bufObj; m_bufferInfo[1].c.buffer = bufObj; m_bufferPtrs[0] = buf + m_bufferInfo[0].c.buffer_offset; m_bufferPtrs[1] = buf + m_bufferInfo[1].c.buffer_offset; } else { m_bufferInfo[0].v.buffer.resource = bufObj; m_bufferInfo[1].v.buffer.resource = bufObj; m_bufferPtrs[0] = buf + m_bufferInfo[0].v.buffer_offset; m_bufferPtrs[1] = buf + m_bufferInfo[1].v.buffer_offset; } } }; static void MakeSampler(NXContext* ctx, void*& sampOut, TextureClampMode mode, int mips) { uint32_t key = (uint32_t(mode) << 16) | mips; auto search = ctx->m_samplers.find(key); if (search != ctx->m_samplers.end()) { sampOut = search->second; return; } /* Create linear sampler */ pipe_sampler_state samplerInfo = {}; samplerInfo.min_img_filter = PIPE_TEX_FILTER_LINEAR; samplerInfo.min_mip_filter = PIPE_TEX_MIPFILTER_LINEAR; samplerInfo.mag_img_filter = PIPE_TEX_FILTER_LINEAR; samplerInfo.compare_mode = PIPE_TEX_COMPARE_NONE; samplerInfo.compare_func = PIPE_FUNC_ALWAYS; samplerInfo.normalized_coords = 1; samplerInfo.max_anisotropy = 16; samplerInfo.seamless_cube_map = 0; samplerInfo.lod_bias = 0; samplerInfo.min_lod = 0; samplerInfo.max_lod = mips - 1; switch (mode) { case TextureClampMode::Repeat: default: samplerInfo.wrap_s = PIPE_TEX_WRAP_REPEAT; samplerInfo.wrap_t = PIPE_TEX_WRAP_REPEAT; samplerInfo.wrap_r = PIPE_TEX_WRAP_REPEAT; break; case TextureClampMode::ClampToWhite: samplerInfo.wrap_s = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_BORDER; samplerInfo.wrap_t = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_BORDER; samplerInfo.wrap_r = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_BORDER; for (int i = 0; i < 4; ++i) samplerInfo.border_color.f[i] = 1.f; break; case TextureClampMode::ClampToBlack: samplerInfo.wrap_s = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_BORDER; samplerInfo.wrap_t = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_BORDER; samplerInfo.wrap_r = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_BORDER; samplerInfo.border_color.f[3] = 1.f; break; case TextureClampMode::ClampToEdge: samplerInfo.wrap_s = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_EDGE; samplerInfo.wrap_t = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_EDGE; samplerInfo.wrap_r = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_EDGE; break; case TextureClampMode::ClampToEdgeNearest: samplerInfo.mag_img_filter = PIPE_TEX_FILTER_NEAREST; samplerInfo.min_mip_filter = PIPE_TEX_MIPFILTER_NEAREST; samplerInfo.min_img_filter = PIPE_TEX_FILTER_NEAREST; samplerInfo.max_anisotropy = 0; samplerInfo.wrap_s = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_EDGE; samplerInfo.wrap_t = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_EDGE; samplerInfo.wrap_r = PIPE_TEX_WRAP_MIRROR_CLAMP_TO_EDGE; break; } sampOut = ctx->m_pctx->create_sampler_state(ctx->m_pctx, &samplerInfo); ctx->m_samplers[key] = sampOut; } class NXTextureS : public GraphicsDataNode { friend class NXDataFactory; NXContext* m_ctx; TextureFormat m_fmt; size_t m_sz; size_t m_width, m_height, m_mips; TextureClampMode m_clampMode; pipe_format m_nxFmt; int m_pixelPitchNum = 1; int m_pixelPitchDenom = 1; NXTextureS(const boo::ObjToken& parent, NXContext* ctx, size_t width, size_t height, size_t mips, TextureFormat fmt, TextureClampMode clampMode, const void* data, size_t sz) : GraphicsDataNode(parent) , m_ctx(ctx) , m_fmt(fmt) , m_sz(sz) , m_width(width) , m_height(height) , m_mips(mips) , m_clampMode(clampMode) { pipe_format pfmt; switch (fmt) { case TextureFormat::RGBA8: pfmt = PIPE_FORMAT_R8G8B8A8_UNORM; m_pixelPitchNum = 4; break; case TextureFormat::I8: pfmt = PIPE_FORMAT_R8_UNORM; break; case TextureFormat::I16: pfmt = PIPE_FORMAT_R16_UNORM; m_pixelPitchNum = 2; break; case TextureFormat::DXT1: pfmt = PIPE_FORMAT_DXT1_RGBA; m_pixelPitchNum = 1; m_pixelPitchDenom = 2; break; default: Log.report(logvisor::Fatal, FMT_STRING("unsupported tex format")); } m_nxFmt = pfmt; struct pipe_resource texTempl = {}; texTempl.target = PIPE_TEXTURE_2D; texTempl.format = m_nxFmt; texTempl.width0 = width; texTempl.height0 = height; texTempl.depth0 = 1; texTempl.last_level = mips - 1; texTempl.array_size = 1; texTempl.bind = PIPE_BIND_SAMPLER_VIEW; m_gpuTex = ctx->m_screen->resource_create(ctx->m_screen, &texTempl); if (!m_gpuTex) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create texture")); return; } uint blockSize = util_format_get_blocksize(m_nxFmt); uint8_t* ptr = (uint8_t*)data; for (int i = 0; i < mips; ++i) { size_t regionPitch = width * height * m_pixelPitchNum / m_pixelPitchDenom; size_t rowStride = width * blockSize; size_t imageBytes = rowStride * height; struct pipe_box box; u_box_2d(0, 0, width, height, &box); ctx->m_pctx->texture_subdata(ctx->m_pctx, m_gpuTex, i, PIPE_TRANSFER_WRITE, &box, ptr, rowStride, imageBytes); if (width > 1) width /= 2; if (height > 1) height /= 2; ptr += regionPitch; } struct pipe_sampler_view svTempl = {}; svTempl.format = m_nxFmt; svTempl.texture = m_gpuTex; svTempl.u.tex.last_level = mips - 1; svTempl.swizzle_r = PIPE_SWIZZLE_X; svTempl.swizzle_g = PIPE_SWIZZLE_Y; svTempl.swizzle_b = PIPE_SWIZZLE_Z; svTempl.swizzle_a = PIPE_SWIZZLE_W; m_gpuView = ctx->m_pctx->create_sampler_view(ctx->m_pctx, m_gpuTex, &svTempl); } public: struct pipe_resource* m_gpuTex; struct pipe_sampler_view* m_gpuView = nullptr; void* m_sampler = nullptr; ~NXTextureS() { pipe_resource_reference(&m_gpuTex, nullptr); pipe_sampler_view_reference(&m_gpuView, nullptr); } void setClampMode(TextureClampMode mode) { m_clampMode = mode; MakeSampler(m_ctx, m_sampler, mode, m_mips); } TextureFormat format() const { return m_fmt; } }; class NXTextureSA : public GraphicsDataNode { friend class NXDataFactory; NXContext* m_ctx; TextureFormat m_fmt; size_t m_sz; size_t m_width, m_height, m_layers, m_mips; TextureClampMode m_clampMode; pipe_format m_nxFmt; int m_pixelPitchNum = 1; int m_pixelPitchDenom = 1; NXTextureSA(const boo::ObjToken& parent, NXContext* ctx, size_t width, size_t height, size_t layers, size_t mips, TextureFormat fmt, TextureClampMode clampMode, const void* data, size_t sz) : GraphicsDataNode(parent) , m_ctx(ctx) , m_fmt(fmt) , m_sz(sz) , m_width(width) , m_height(height) , m_layers(layers) , m_mips(mips) , m_clampMode(clampMode) { pipe_format pfmt; switch (fmt) { case TextureFormat::RGBA8: pfmt = PIPE_FORMAT_R8G8B8A8_UNORM; m_pixelPitchNum = 4; break; case TextureFormat::I8: pfmt = PIPE_FORMAT_R8_UNORM; break; case TextureFormat::I16: pfmt = PIPE_FORMAT_R16_UNORM; m_pixelPitchNum = 2; break; default: Log.report(logvisor::Fatal, FMT_STRING("unsupported tex format")); } m_nxFmt = pfmt; struct pipe_resource texTempl = {}; texTempl.target = PIPE_TEXTURE_2D; texTempl.format = m_nxFmt; texTempl.width0 = width; texTempl.height0 = height; texTempl.depth0 = 1; texTempl.last_level = mips - 1; texTempl.array_size = layers; texTempl.bind = PIPE_BIND_SAMPLER_VIEW; m_gpuTex = ctx->m_screen->resource_create(ctx->m_screen, &texTempl); if (!m_gpuTex) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create texture")); return; } uint blockSize = util_format_get_blocksize(m_nxFmt); uint8_t* ptr = (uint8_t*)data; for (int i = 0; i < mips; ++i) { size_t regionPitch = width * height * m_layers * m_pixelPitchNum / m_pixelPitchDenom; size_t rowStride = width * blockSize; size_t imageBytes = rowStride * height; struct pipe_box box; u_box_2d(0, 0, width, height, &box); ctx->m_pctx->texture_subdata(ctx->m_pctx, m_gpuTex, i, PIPE_TRANSFER_WRITE, &box, ptr, rowStride, imageBytes); if (width > 1) width /= 2; if (height > 1) height /= 2; ptr += regionPitch; } struct pipe_sampler_view svTempl = {}; svTempl.format = m_nxFmt; svTempl.texture = m_gpuTex; svTempl.u.tex.last_layer = layers - 1; svTempl.u.tex.last_level = mips - 1; svTempl.swizzle_r = PIPE_SWIZZLE_X; svTempl.swizzle_g = PIPE_SWIZZLE_Y; svTempl.swizzle_b = PIPE_SWIZZLE_Z; svTempl.swizzle_a = PIPE_SWIZZLE_W; m_gpuView = ctx->m_pctx->create_sampler_view(ctx->m_pctx, m_gpuTex, &svTempl); } public: struct pipe_resource* m_gpuTex; struct pipe_sampler_view* m_gpuView = nullptr; void* m_sampler = nullptr; ~NXTextureSA() { pipe_resource_reference(&m_gpuTex, nullptr); pipe_sampler_view_reference(&m_gpuView, nullptr); } void setClampMode(TextureClampMode mode) { m_clampMode = mode; MakeSampler(m_ctx, m_sampler, mode, m_mips); } TextureFormat format() const { return m_fmt; } size_t layers() const { return m_layers; } }; class NXTextureD : public GraphicsDataNode { friend class NXDataFactory; friend class NXCommandQueue; NXCommandQueue* m_q; size_t m_width; size_t m_height; TextureFormat m_fmt; TextureClampMode m_clampMode; std::unique_ptr m_stagingBuf; size_t m_cpuSz; pipe_format m_nxFmt; int m_validSlots = 0; NXTextureD(const boo::ObjToken& parent, NXCommandQueue* q, size_t width, size_t height, TextureFormat fmt, TextureClampMode clampMode); void update(int b); public: struct pipe_resource* m_gpuTex[2]; struct pipe_sampler_view* m_gpuView[2]; void* m_sampler = nullptr; ~NXTextureD() { for (int i = 0; i < 2; ++i) { pipe_resource_reference(&m_gpuTex[i], nullptr); pipe_sampler_view_reference(&m_gpuView[i], nullptr); } } void setClampMode(TextureClampMode mode); void load(const void* data, size_t sz); void* map(size_t sz); void unmap(); TextureFormat format() const { return m_fmt; } }; #define MAX_BIND_TEXS 4 static constexpr pipe_format ColorFormat = PIPE_FORMAT_R8G8B8A8_UNORM; static constexpr pipe_format DepthFormat = PIPE_FORMAT_Z32_FLOAT; class NXTextureR : public GraphicsDataNode { NXContext* m_ctx; friend class NXDataFactory; friend struct NXCommandQueue; size_t m_width = 0; size_t m_height = 0; unsigned m_samplesColor, m_samplesDepth; size_t m_colorBindCount; size_t m_depthBindCount; void Setup(NXContext* ctx) { /* no-ops on first call */ doDestroy(); /* color target */ struct pipe_resource texTempl = {}; texTempl.target = PIPE_TEXTURE_2D; texTempl.format = ColorFormat; texTempl.width0 = m_width; texTempl.height0 = m_height; texTempl.depth0 = 1; texTempl.array_size = 1; texTempl.nr_samples = texTempl.nr_storage_samples = m_samplesColor; texTempl.bind = PIPE_BIND_RENDER_TARGET; m_colorTex = ctx->m_screen->resource_create(ctx->m_screen, &texTempl); if (!m_colorTex) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create color target texture")); return; } /* depth target */ texTempl.format = DepthFormat; texTempl.nr_samples = texTempl.nr_storage_samples = m_samplesDepth; texTempl.bind = PIPE_BIND_DEPTH_STENCIL; m_depthTex = ctx->m_screen->resource_create(ctx->m_screen, &texTempl); if (!m_depthTex) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create depth target texture")); return; } texTempl.nr_samples = texTempl.nr_storage_samples = 1; for (size_t i = 0; i < m_colorBindCount; ++i) { texTempl.format = ColorFormat; texTempl.bind = PIPE_BIND_SAMPLER_VIEW; m_colorBindTex[i] = ctx->m_screen->resource_create(ctx->m_screen, &texTempl); if (!m_colorBindTex[i]) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create color bind texture")); return; } } for (size_t i = 0; i < m_depthBindCount; ++i) { texTempl.format = DepthFormat; texTempl.bind = PIPE_BIND_SAMPLER_VIEW; m_depthBindTex[i] = ctx->m_screen->resource_create(ctx->m_screen, &texTempl); if (!m_depthBindTex[i]) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create depth bind texture")); return; } } /* Create resource views */ struct pipe_sampler_view svTempl = {}; svTempl.format = ColorFormat; svTempl.swizzle_r = PIPE_SWIZZLE_X; svTempl.swizzle_g = PIPE_SWIZZLE_Y; svTempl.swizzle_b = PIPE_SWIZZLE_Z; svTempl.swizzle_a = PIPE_SWIZZLE_W; svTempl.texture = m_colorTex; m_colorView = ctx->m_pctx->create_sampler_view(ctx->m_pctx, m_colorTex, &svTempl); if (!m_colorView) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create color sampler view")); return; } svTempl.format = DepthFormat; svTempl.texture = m_depthTex; m_depthView = ctx->m_pctx->create_sampler_view(ctx->m_pctx, m_depthTex, &svTempl); if (!m_depthView) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create depth sampler view")); return; } svTempl.format = ColorFormat; for (size_t i = 0; i < m_colorBindCount; ++i) { svTempl.texture = m_colorBindTex[i]; m_colorBindView[i] = ctx->m_pctx->create_sampler_view(ctx->m_pctx, m_colorBindTex[i], &svTempl); if (!m_colorBindView[i]) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create color bind sampler view")); return; } } svTempl.format = DepthFormat; for (size_t i = 0; i < m_depthBindCount; ++i) { svTempl.texture = m_depthBindTex[i]; m_depthBindView[i] = ctx->m_pctx->create_sampler_view(ctx->m_pctx, m_depthBindTex[i], &svTempl); if (!m_depthBindView[i]) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create depth bind sampler view")); return; } } /* surfaces */ struct pipe_surface surfTempl = {}; surfTempl.format = ColorFormat; m_colorSurface = ctx->m_pctx->create_surface(ctx->m_pctx, m_colorTex, &surfTempl); if (!m_colorSurface) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create color surface")); return; } surfTempl.format = DepthFormat; m_depthSurface = ctx->m_pctx->create_surface(ctx->m_pctx, m_depthTex, &surfTempl); if (!m_depthSurface) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create depth surface")); return; } /* framebuffer */ m_framebuffer.width = uint16_t(m_width); m_framebuffer.height = uint16_t(m_height); m_framebuffer.nr_cbufs = 1; m_framebuffer.cbufs[0] = m_colorSurface; m_framebuffer.zsbuf = m_depthSurface; } NXTextureR(const boo::ObjToken& parent, NXContext* ctx, size_t width, size_t height, TextureClampMode clampMode, size_t colorBindCount, size_t depthBindCount) : GraphicsDataNode(parent), m_ctx(ctx) { if (colorBindCount > MAX_BIND_TEXS) Log.report(logvisor::Fatal, FMT_STRING("too many color bindings for render texture")); if (depthBindCount > MAX_BIND_TEXS) Log.report(logvisor::Fatal, FMT_STRING("too many depth bindings for render texture")); if (m_samplesColor == 0) m_samplesColor = 1; if (m_samplesDepth == 0) m_samplesDepth = 1; setClampMode(clampMode); Setup(ctx); } public: struct pipe_resource* m_colorTex; struct pipe_sampler_view* m_colorView = nullptr; struct pipe_resource* m_depthTex; struct pipe_sampler_view* m_depthView = nullptr; struct pipe_resource* m_colorBindTex[MAX_BIND_TEXS] = {}; struct pipe_sampler_view* m_colorBindView[MAX_BIND_TEXS] = {}; struct pipe_resource* m_depthBindTex[MAX_BIND_TEXS] = {}; struct pipe_sampler_view* m_depthBindView[MAX_BIND_TEXS] = {}; struct pipe_surface* m_colorSurface = nullptr; struct pipe_surface* m_depthSurface = nullptr; void* m_sampler = nullptr; struct pipe_framebuffer_state m_framebuffer = {}; void setClampMode(TextureClampMode mode) { MakeSampler(m_ctx, m_sampler, mode, 1); } void doDestroy() { pipe_resource_reference(&m_colorTex, nullptr); pipe_sampler_view_reference(&m_colorView, nullptr); pipe_resource_reference(&m_depthTex, nullptr); pipe_sampler_view_reference(&m_depthView, nullptr); for (size_t i = 0; i < MAX_BIND_TEXS; ++i) { pipe_resource_reference(&m_colorBindTex[i], nullptr); pipe_sampler_view_reference(&m_colorBindView[i], nullptr); pipe_resource_reference(&m_depthBindTex[i], nullptr); pipe_sampler_view_reference(&m_depthBindView[i], nullptr); } pipe_surface_reference(&m_colorSurface, nullptr); pipe_surface_reference(&m_depthSurface, nullptr); } ~NXTextureR() { doDestroy(); } void resize(NXContext* ctx, size_t width, size_t height) { if (width < 1) width = 1; if (height < 1) height = 1; m_width = width; m_height = height; Setup(ctx); } }; static const size_t SEMANTIC_SIZE_TABLE[] = {0, 12, 16, 12, 16, 16, 4, 8, 16, 16, 16}; static const pipe_format SEMANTIC_TYPE_TABLE[] = {PIPE_FORMAT_NONE, PIPE_FORMAT_R32G32B32_FLOAT, PIPE_FORMAT_R32G32B32A32_FLOAT, PIPE_FORMAT_R32G32B32_FLOAT, PIPE_FORMAT_R32G32B32A32_FLOAT, PIPE_FORMAT_R32G32B32A32_FLOAT, PIPE_FORMAT_R8G8B8A8_UNORM, PIPE_FORMAT_R32G32_FLOAT, PIPE_FORMAT_R32G32B32A32_FLOAT, PIPE_FORMAT_R32G32B32A32_FLOAT, PIPE_FORMAT_R32G32B32A32_FLOAT}; struct NXVertexFormat { void* m_vtxElem; size_t m_stride = 0; size_t m_instStride = 0; NXVertexFormat(NXContext* ctx, const VertexFormatInfo& info) { std::unique_ptr attributes(new pipe_vertex_element[info.elementCount]); for (size_t i = 0; i < info.elementCount; ++i) { const VertexElementDescriptor* elemin = &info.elements[i]; pipe_vertex_element& attribute = attributes[i]; int semantic = int(elemin->semantic & boo::VertexSemantic::SemanticMask); attribute.src_format = SEMANTIC_TYPE_TABLE[semantic]; if ((elemin->semantic & boo::VertexSemantic::Instanced) != boo::VertexSemantic::None) { attribute.vertex_buffer_index = 1; attribute.instance_divisor = 1; attribute.src_offset = m_instStride; m_instStride += SEMANTIC_SIZE_TABLE[semantic]; } else { attribute.vertex_buffer_index = 0; attribute.instance_divisor = 0; attribute.src_offset = m_stride; m_stride += SEMANTIC_SIZE_TABLE[semantic]; } } uint64_t key = XXH64(attributes.get(), sizeof(pipe_vertex_element) * info.elementCount, 0); auto search = ctx->m_vtxElemStates.find(key); if (search != ctx->m_vtxElemStates.end()) { m_vtxElem = search->second; return; } m_vtxElem = ctx->m_pctx->create_vertex_elements_state(ctx->m_pctx, info.elementCount, attributes.get()); ctx->m_vtxElemStates[key] = m_vtxElem; } }; static const pipe_prim_type PRIMITIVE_TABLE[] = {PIPE_PRIM_TRIANGLES, PIPE_PRIM_TRIANGLE_STRIP, PIPE_PRIM_PATCHES}; static const nx_shader_stage SHADER_TYPE_TABLE[] = { nx_shader_stage::NONE, nx_shader_stage::VERTEX, nx_shader_stage::FRAGMENT, nx_shader_stage::GEOMETRY, nx_shader_stage::TESS_CTRL, nx_shader_stage::TESS_EVAL, }; class NXShaderStage : public GraphicsDataNode { friend class NXDataFactory; nx_shader_stage_object m_obj; NXShaderStage(const boo::ObjToken& parent, NXContext* ctx, const uint8_t* data, size_t size, PipelineStage stage) : GraphicsDataNode(parent), m_obj(ctx->m_compiler.compile(SHADER_TYPE_TABLE[int(stage)], (char*)data)) { if (!m_obj) Log.report(logvisor::Fatal, FMT_STRING("Shader compile fail:\n%s\n"), m_obj.info_log()); } public: const nx_shader_stage_object* shader() const { return &m_obj; } }; static const unsigned BLEND_FACTOR_TABLE[] = { PIPE_BLENDFACTOR_ZERO, PIPE_BLENDFACTOR_ONE, PIPE_BLENDFACTOR_SRC_COLOR, PIPE_BLENDFACTOR_INV_SRC_COLOR, PIPE_BLENDFACTOR_DST_COLOR, PIPE_BLENDFACTOR_INV_DST_COLOR, PIPE_BLENDFACTOR_SRC_ALPHA, PIPE_BLENDFACTOR_INV_SRC_ALPHA, PIPE_BLENDFACTOR_DST_ALPHA, PIPE_BLENDFACTOR_INV_DST_ALPHA, PIPE_BLENDFACTOR_SRC1_COLOR, PIPE_BLENDFACTOR_INV_SRC1_COLOR}; static void MakeBlendState(NXContext* ctx, void*& bsOut, const AdditionalPipelineInfo& info) { uint32_t key = (uint32_t(info.srcFac) << 16) | (uint32_t(info.dstFac) << 3) | info.colorWrite << 2 | info.alphaWrite << 1 | info.overwriteAlpha; auto search = ctx->m_blendStates.find(key); if (search != ctx->m_blendStates.end()) { bsOut = search->second; return; } pipe_blend_state bs = {}; bs.rt->blend_enable = info.srcFac != BlendFactor::One || info.dstFac != BlendFactor::Zero; if (info.srcFac == BlendFactor::Subtract || info.dstFac == BlendFactor::Subtract) { bs.rt[0].rgb_src_factor = PIPE_BLENDFACTOR_SRC_ALPHA; bs.rt[0].rgb_dst_factor = PIPE_BLENDFACTOR_ONE; bs.rt[0].rgb_func = PIPE_BLEND_REVERSE_SUBTRACT; if (info.overwriteAlpha) { bs.rt[0].alpha_src_factor = PIPE_BLENDFACTOR_ONE; bs.rt[0].alpha_dst_factor = PIPE_BLENDFACTOR_ZERO; bs.rt[0].alpha_func = PIPE_BLEND_ADD; } else { bs.rt[0].alpha_src_factor = PIPE_BLENDFACTOR_SRC_ALPHA; bs.rt[0].alpha_dst_factor = PIPE_BLENDFACTOR_ONE; bs.rt[0].alpha_func = PIPE_BLEND_REVERSE_SUBTRACT; } } else { bs.rt[0].rgb_src_factor = BLEND_FACTOR_TABLE[int(info.srcFac)]; bs.rt[0].rgb_dst_factor = BLEND_FACTOR_TABLE[int(info.dstFac)]; bs.rt[0].rgb_func = PIPE_BLEND_ADD; if (info.overwriteAlpha) { bs.rt[0].alpha_src_factor = PIPE_BLENDFACTOR_ONE; bs.rt[0].alpha_dst_factor = PIPE_BLENDFACTOR_ZERO; } else { bs.rt[0].alpha_src_factor = BLEND_FACTOR_TABLE[int(info.srcFac)]; bs.rt[0].alpha_dst_factor = BLEND_FACTOR_TABLE[int(info.dstFac)]; } bs.rt[0].alpha_func = PIPE_BLEND_ADD; } bs.rt[0].colormask = (info.colorWrite ? (PIPE_MASK_R | PIPE_MASK_G | PIPE_MASK_B) : 0) | (info.alphaWrite ? PIPE_MASK_A : 0); bsOut = ctx->m_pctx->create_blend_state(ctx->m_pctx, &bs); ctx->m_blendStates[key] = bsOut; } static void MakeRasterizerState(NXContext* ctx, void*& rasOut, const AdditionalPipelineInfo& info) { uint32_t key = uint32_t(info.culling); auto search = ctx->m_rasStates.find(key); if (search != ctx->m_rasStates.end()) { rasOut = search->second; return; } pipe_rasterizer_state ras = {}; ras.clamp_fragment_color = 1; ras.front_ccw = 1; switch (info.culling) { case CullMode::None: default: ras.cull_face = PIPE_FACE_NONE; break; case CullMode::Backface: ras.cull_face = PIPE_FACE_BACK; break; case CullMode::Frontface: ras.cull_face = PIPE_FACE_FRONT; break; } ras.scissor = 1; ras.multisample = unsigned(ctx->m_sampleCount > 1); ras.half_pixel_center = 1; ras.bottom_edge_rule = 1; ras.depth_clip_near = 1; ras.depth_clip_far = 1; rasOut = ctx->m_pctx->create_rasterizer_state(ctx->m_pctx, &ras); ctx->m_rasStates[key] = rasOut; } static void MakeDepthStencilState(NXContext* ctx, void*& dsOut, const AdditionalPipelineInfo& info) { uint32_t key = (uint32_t(info.depthTest) << 16) | info.depthWrite; auto search = ctx->m_dsStates.find(key); if (search != ctx->m_dsStates.end()) { dsOut = search->second; return; } pipe_depth_stencil_alpha_state ds = {}; ds.depth.enabled = info.depthTest != ZTest::None; ds.depth.writemask = info.depthWrite; switch (info.depthTest) { case ZTest::None: default: ds.depth.func = PIPE_FUNC_ALWAYS; break; case ZTest::LEqual: ds.depth.func = PIPE_FUNC_LEQUAL; break; case ZTest::Greater: ds.depth.func = PIPE_FUNC_GREATER; break; case ZTest::Equal: ds.depth.func = PIPE_FUNC_EQUAL; break; case ZTest::GEqual: ds.depth.func = PIPE_FUNC_GEQUAL; break; } dsOut = ctx->m_pctx->create_depth_stencil_alpha_state(ctx->m_pctx, &ds); ctx->m_dsStates[key] = dsOut; } class NXShaderPipeline : public GraphicsDataNode { protected: friend class NXDataFactory; friend struct NXShaderDataBinding; NXVertexFormat m_vtxFmt; nx_linked_shader m_shader; Primitive m_prim; pipe_prim_type m_nxPrim; uint32_t m_patchSize; void* m_blendState; void* m_rasState; void* m_dsState; NXShaderPipeline(const boo::ObjToken& parent, NXContext* ctx, ObjToken vertex, ObjToken fragment, ObjToken geometry, ObjToken control, ObjToken evaluation, const VertexFormatInfo& vtxFmt, const AdditionalPipelineInfo& info) : GraphicsDataNode(parent), m_vtxFmt(ctx, vtxFmt), m_prim(info.prim), m_patchSize(info.patchSize) { m_nxPrim = PRIMITIVE_TABLE[int(m_prim)]; MakeBlendState(ctx, m_blendState, info); MakeRasterizerState(ctx, m_rasState, info); MakeDepthStencilState(ctx, m_dsState, info); const nx_shader_stage_object* stages[5]; unsigned numStages = 0; if (vertex) stages[numStages++] = vertex.cast()->shader(); if (control) stages[numStages++] = control.cast()->shader(); if (evaluation) stages[numStages++] = evaluation.cast()->shader(); if (geometry) stages[numStages++] = geometry.cast()->shader(); if (fragment) stages[numStages++] = fragment.cast()->shader(); std::string infoLog; m_shader = ctx->m_compiler.link(numStages, stages, &infoLog); if (!m_shader) Log.report(logvisor::Fatal, FMT_STRING("Unable to link shader:\n%s\n"), infoLog.c_str()); } public: NXShaderPipeline& operator=(const NXShaderPipeline&) = delete; NXShaderPipeline(const NXShaderPipeline&) = delete; void bind(struct pipe_context* pctx) const { const struct gl_shader_program* prog = m_shader.program(); if (gl_linked_shader* fs = prog->_LinkedShaders[MESA_SHADER_FRAGMENT]) { struct st_fragment_program* p = (struct st_fragment_program*)fs->Program; pctx->bind_fs_state(pctx, p->variants->driver_shader); } if (gl_linked_shader* gs = prog->_LinkedShaders[MESA_SHADER_GEOMETRY]) { struct st_common_program* p = (struct st_common_program*)gs->Program; pctx->bind_gs_state(pctx, p->variants->driver_shader); } if (gl_linked_shader* tes = prog->_LinkedShaders[MESA_SHADER_TESS_EVAL]) { struct st_common_program* p = (struct st_common_program*)tes->Program; pctx->bind_tes_state(pctx, p->variants->driver_shader); } if (gl_linked_shader* tcs = prog->_LinkedShaders[MESA_SHADER_TESS_CTRL]) { struct st_common_program* p = (struct st_common_program*)tcs->Program; pctx->bind_tcs_state(pctx, p->variants->driver_shader); } if (gl_linked_shader* vs = prog->_LinkedShaders[MESA_SHADER_VERTEX]) { struct st_vertex_program* p = (struct st_vertex_program*)vs->Program; pctx->bind_vs_state(pctx, p->variants->driver_shader); } pctx->bind_blend_state(pctx, m_blendState); pctx->bind_rasterizer_state(pctx, m_rasState); pctx->bind_depth_stencil_alpha_state(pctx, m_dsState); } }; static const nx_buffer_info* GetBufferGPUResource(const IGraphicsBuffer* buf, int idx) { if (buf->dynamic()) { const NXGraphicsBufferD* cbuf = static_cast*>(buf); return &cbuf->m_bufferInfo[idx]; } else { const NXGraphicsBufferS* cbuf = static_cast(buf); return &cbuf->m_bufferInfo; } } static const struct pipe_sampler_view* GetTextureGPUResource(const ITexture* tex, int idx, int bindIdx, bool depth, void*& samplerOut) { switch (tex->type()) { case TextureType::Dynamic: { const NXTextureD* ctex = static_cast(tex); samplerOut = ctex->m_sampler; return ctex->m_gpuView[idx]; } case TextureType::Static: { const NXTextureS* ctex = static_cast(tex); samplerOut = ctex->m_sampler; return ctex->m_gpuView; } case TextureType::StaticArray: { const NXTextureSA* ctex = static_cast(tex); samplerOut = ctex->m_sampler; return ctex->m_gpuView; } case TextureType::Render: { const NXTextureR* ctex = static_cast(tex); samplerOut = ctex->m_sampler; return depth ? ctex->m_depthBindView[bindIdx] : ctex->m_colorBindView[bindIdx]; } default: break; } return nullptr; } struct NXShaderDataBinding : GraphicsDataNode { NXContext* m_ctx; boo::ObjToken m_pipeline; boo::ObjToken m_vbuf; boo::ObjToken m_instVbuf; boo::ObjToken m_ibuf; std::vector> m_ubufs; std::vector> m_ubufOffs; struct BindTex { boo::ObjToken tex; int idx; bool depth; }; std::vector m_texs; struct pipe_vertex_buffer m_vboBufs[2][2] = {{}, {}}; std::vector> m_ubufBinds[MESA_SHADER_STAGES]; size_t m_vertOffset; size_t m_instOffset; #ifndef NDEBUG /* Debugging aids */ bool m_committed = false; #endif NXShaderDataBinding(const boo::ObjToken& d, NXDataFactoryImpl& factory, const boo::ObjToken& pipeline, const boo::ObjToken& vbuf, const boo::ObjToken& instVbuf, const boo::ObjToken& ibuf, size_t ubufCount, const boo::ObjToken* ubufs, const size_t* ubufOffs, const size_t* ubufSizes, size_t texCount, const boo::ObjToken* texs, const int* bindIdxs, const bool* depthBinds, size_t baseVert, size_t baseInst) : GraphicsDataNode(d) , m_ctx(factory.m_ctx) , m_pipeline(pipeline) , m_vbuf(vbuf) , m_instVbuf(instVbuf) , m_ibuf(ibuf) { NXShaderPipeline* cpipeline = m_pipeline.cast(); NXVertexFormat& vtxFmt = cpipeline->m_vtxFmt; m_vertOffset = baseVert * vtxFmt.m_stride; m_instOffset = baseInst * vtxFmt.m_instStride; m_ubufs.reserve(ubufCount); if (ubufOffs && ubufSizes) m_ubufOffs.reserve(ubufCount); for (size_t i = 0; i < ubufCount; ++i) { #ifndef NDEBUG if (!ubufs[i]) Log.report(logvisor::Fatal, FMT_STRING("null uniform-buffer %d provided to newShaderDataBinding"), int(i)); #endif m_ubufs.push_back(ubufs[i]); if (ubufOffs && ubufSizes) m_ubufOffs.push_back({ubufOffs[i], ubufSizes[i]}); } m_texs.reserve(texCount); for (size_t i = 0; i < texCount; ++i) { m_texs.push_back({texs[i], bindIdxs ? bindIdxs[i] : 0, depthBinds ? depthBinds[i] : false}); } } void commit() { struct pipe_context* pctx = m_ctx->m_pctx; for (int i = 0; i < 2; ++i) { if (m_vbuf) { m_vboBufs[i][0] = GetBufferGPUResource(m_vbuf.get(), i)->v; m_vboBufs[i][0].buffer_offset += m_vertOffset; } if (m_instVbuf) { m_vboBufs[i][1] = GetBufferGPUResource(m_instVbuf.get(), i)->v; m_vboBufs[i][1].buffer_offset += m_instOffset; } } NXShaderPipeline* cpipeline = m_pipeline.cast(); const struct gl_shader_program* program = cpipeline->m_shader.program(); for (uint i = 0; i < MESA_SHADER_STAGES; ++i) { if (const struct gl_linked_shader* lsh = program->_LinkedShaders[i]) { std::vector>& bindings = m_ubufBinds[i]; const struct gl_shader_program_data* data = lsh->Program->sh.data; bindings.reserve(data->NumUniformBlocks); for (uint j = 0; j < data->NumUniformBlocks; ++j) { const struct gl_uniform_block* block = &data->UniformBlocks[j]; assert(block->Binding < m_ubufs.size() && "Uniform binding oob"); bindings.emplace_back(); for (int k = 0; k < 2; ++k) { struct pipe_constant_buffer& bufBind = bindings.back()[k]; const nx_buffer_info* buf = GetBufferGPUResource(m_ubufs[block->Binding].get(), k); bufBind = buf->c; if (!m_ubufOffs.empty()) { bufBind.buffer_offset += m_ubufOffs[block->Binding][0]; bufBind.buffer_size = unsigned(m_ubufOffs[block->Binding][1]); } } } } } #ifndef NDEBUG m_committed = true; #endif } void bind(int b) { #ifndef NDEBUG if (!m_committed) Log.report(logvisor::Fatal, FMT_STRING("attempted to use uncommitted NXShaderDataBinding")); #endif struct pipe_context* pctx = m_ctx->m_pctx; NXShaderPipeline* pipeline = m_pipeline.cast(); pipeline->bind(pctx); const struct gl_shader_program* program = pipeline->m_shader.program(); for (uint i = 0; i < MESA_SHADER_STAGES; ++i) { uint j = 0; for (const auto& bind : m_ubufBinds[i]) pctx->set_constant_buffer(pctx, pipe_shader_type(i), j++, &bind[b]); if (const struct gl_linked_shader* lsh = program->_LinkedShaders[i]) { void* samplers[BOO_GLSL_MAX_TEXTURE_COUNT] = {}; struct pipe_sampler_view* samplerViews[BOO_GLSL_MAX_TEXTURE_COUNT] = {}; unsigned numSamplers = 0; const struct gl_program* stprogram = lsh->Program; for (int t = 0; t < BOO_GLSL_MAX_TEXTURE_COUNT; ++t) { if (stprogram->SamplersUsed & (1 << t)) { GLubyte unit = GLubyte(stprogram->SamplerUnits[t] - BOO_GLSL_MAX_UNIFORM_COUNT); assert(unit < m_texs.size() && "Texture binding oob"); const BindTex& tex = m_texs[unit]; samplerViews[numSamplers] = (pipe_sampler_view*)GetTextureGPUResource(tex.tex.get(), t, tex.idx, tex.depth, samplers[numSamplers]); ++numSamplers; } } pctx->bind_sampler_states(pctx, pipe_shader_type(i), 0, numSamplers, samplers); pctx->set_sampler_views(pctx, pipe_shader_type(i), 0, numSamplers, samplerViews); } } if (m_vbuf && m_instVbuf) pctx->set_vertex_buffers(pctx, 0, 2, m_vboBufs[b]); else if (m_vbuf) pctx->set_vertex_buffers(pctx, 0, 1, m_vboBufs[b]); else if (m_instVbuf) pctx->set_vertex_buffers(pctx, 1, 1, &m_vboBufs[b][1]); } pipe_prim_type getPrimitive() const { return m_pipeline.cast()->m_nxPrim; } uint32_t getPatchVerts() const { return m_pipeline.cast()->m_patchSize; } struct pipe_resource* getIndexBuf(int b) const { return GetBufferGPUResource(m_ibuf.get(), b)->v.buffer.resource; } }; struct NXCommandQueue : IGraphicsCommandQueue { Platform platform() const { return IGraphicsDataFactory::Platform::Vulkan; } const SystemChar* platformName() const { return _SYS_STR("NX"); } NXContext* m_ctx; IGraphicsContext* m_parent; bool m_running = true; int m_fillBuf = 0; int m_drawBuf = 0; std::vector> m_drawResTokens[2]; NXCommandQueue(NXContext* ctx, IGraphicsContext* parent) : m_ctx(ctx), m_parent(parent) {} void startRenderer() { static_cast(m_parent->getDataFactory())->SetupGammaResources(); } void stopRenderer() { m_running = false; static_cast(m_parent->getDataFactory())->DestroyGammaResources(); m_drawResTokens[0].clear(); m_drawResTokens[1].clear(); m_boundTarget.reset(); m_resolveDispSource.reset(); } ~NXCommandQueue() { if (m_running) stopRenderer(); } boo::ObjToken m_curSDBinding; void setShaderDataBinding(const boo::ObjToken& binding) { m_curSDBinding = binding; NXShaderDataBinding* cbind = binding.cast(); cbind->bind(m_fillBuf); m_drawResTokens[m_fillBuf].push_back(binding.get()); } boo::ObjToken m_boundTarget; void setRenderTarget(const boo::ObjToken& target) { NXTextureR* ctarget = target.cast(); if (m_boundTarget.get() != ctarget) { m_boundTarget = target; m_drawResTokens[m_fillBuf].push_back(target.get()); } m_ctx->m_pctx->set_framebuffer_state(m_ctx->m_pctx, &ctarget->m_framebuffer); } void setViewport(const SWindowRect& rect, float znear, float zfar) { if (m_boundTarget) { NXTextureR* ctarget = m_boundTarget.cast(); struct gl_context* ctx = m_ctx->m_st->ctx; ctx->ViewportArray[0].X = float(rect.location[0]); ctx->ViewportArray[0].Y = float(std::max(0, int(ctarget->m_height) - rect.location[1] - rect.size[1])); ctx->ViewportArray[0].Width = float(rect.size[0]); ctx->ViewportArray[0].Height = float(rect.size[1]); ctx->ViewportArray[0].Near = znear; ctx->ViewportArray[0].Far = zfar; pipe_viewport_state vp = {}; _mesa_get_viewport_xform(ctx, 0, vp.scale, vp.translate); m_ctx->m_pctx->set_viewport_states(m_ctx->m_pctx, 0, 1, &vp); } } void setScissor(const SWindowRect& rect) { if (m_boundTarget) { NXTextureR* ctarget = m_boundTarget.cast(); pipe_scissor_state scissor = {}; scissor.minx = unsigned(rect.location[0]); scissor.miny = unsigned(std::max(0, int(ctarget->m_height) - rect.location[1] - rect.size[1])); scissor.maxx = scissor.minx + unsigned(rect.size[0]); scissor.maxy = scissor.miny + unsigned(rect.size[1]); m_ctx->m_pctx->set_scissor_states(m_ctx->m_pctx, 0, 1, &scissor); } } std::unordered_map> m_texResizes; void resizeRenderTexture(const boo::ObjToken& tex, size_t width, size_t height) { NXTextureR* ctex = tex.cast(); m_texResizes[ctex] = std::make_pair(width, height); m_drawResTokens[m_fillBuf].push_back(tex.get()); } void schedulePostFrameHandler(std::function&& func) { func(); } float m_clearColor[4] = {0.0, 0.0, 0.0, 0.0}; void setClearColor(const float rgba[4]) { m_clearColor[0] = rgba[0]; m_clearColor[1] = rgba[1]; m_clearColor[2] = rgba[2]; m_clearColor[3] = rgba[3]; } void clearTarget(bool render = true, bool depth = true) { if (!m_boundTarget) return; unsigned buffers = 0; if (render) buffers |= PIPE_CLEAR_COLOR0; if (depth) buffers |= PIPE_CLEAR_DEPTH; pipe_color_union cunion; for (int i = 0; i < 4; ++i) cunion.f[i] = m_clearColor[i]; m_ctx->m_pctx->clear(m_ctx->m_pctx, buffers, &cunion, 1.f, 0); } void draw(size_t start, size_t count) { pipe_draw_info info = {}; NXShaderDataBinding* sdBinding = m_curSDBinding.cast(); info.mode = sdBinding->getPrimitive(); info.vertices_per_patch = sdBinding->getPatchVerts(); info.start = start; info.count = count; m_ctx->m_pctx->draw_vbo(m_ctx->m_pctx, &info); } void drawIndexed(size_t start, size_t count) { pipe_draw_info info = {}; NXShaderDataBinding* sdBinding = m_curSDBinding.cast(); info.index_size = 4; info.mode = sdBinding->getPrimitive(); info.primitive_restart = 1; info.vertices_per_patch = sdBinding->getPatchVerts(); info.start = start; info.count = count; info.restart_index = 0xffffffff; info.index.resource = sdBinding->getIndexBuf(m_fillBuf); m_ctx->m_pctx->draw_vbo(m_ctx->m_pctx, &info); } void drawInstances(size_t start, size_t count, size_t instCount) { pipe_draw_info info = {}; NXShaderDataBinding* sdBinding = m_curSDBinding.cast(); info.mode = sdBinding->getPrimitive(); info.vertices_per_patch = sdBinding->getPatchVerts(); info.start = start; info.count = count; info.instance_count = instCount; m_ctx->m_pctx->draw_vbo(m_ctx->m_pctx, &info); } void drawInstancesIndexed(size_t start, size_t count, size_t instCount) { pipe_draw_info info = {}; NXShaderDataBinding* sdBinding = m_curSDBinding.cast(); info.index_size = 4; info.mode = sdBinding->getPrimitive(); info.primitive_restart = 1; info.vertices_per_patch = sdBinding->getPatchVerts(); info.start = start; info.count = count; info.instance_count = instCount; info.restart_index = 0xffffffff; info.index.resource = sdBinding->getIndexBuf(m_fillBuf); m_ctx->m_pctx->draw_vbo(m_ctx->m_pctx, &info); } boo::ObjToken m_resolveDispSource; void resolveDisplay(const boo::ObjToken& source) { m_resolveDispSource = source; } bool _resolveDisplay() { if (!m_resolveDispSource) return false; NXTextureR* csource = m_resolveDispSource.cast(); #ifndef NDEBUG if (!csource->m_colorBindCount) Log.report(logvisor::Fatal, FMT_STRING("texture provided to resolveDisplay() must have at least 1 color binding")); #endif struct pipe_surface* backBuf = m_ctx->m_windowSurfaces[ST_ATTACHMENT_BACK_LEFT]; NXDataFactoryImpl* dataFactory = static_cast(m_parent->getDataFactory()); if (dataFactory->m_gamma != 1.f) { SWindowRect rect(0, 0, csource->m_width, csource->m_height); _resolveBindTexture(csource, rect, true, 0, true, false); NXShaderDataBinding* gammaBinding = dataFactory->m_gammaBinding.cast(); pipe_framebuffer_state fstate = {}; fstate.width = backBuf->texture->width0; fstate.height = backBuf->texture->height0; fstate.nr_cbufs = 1; fstate.cbufs[0] = backBuf; m_ctx->m_pctx->set_framebuffer_state(m_ctx->m_pctx, &fstate); gammaBinding->m_texs[0].tex = m_resolveDispSource.get(); gammaBinding->bind(m_drawBuf); pipe_draw_info info = {}; info.mode = PIPE_PRIM_TRIANGLE_STRIP; info.start = 0; info.count = 4; info.instance_count = 1; m_ctx->m_pctx->draw_vbo(m_ctx->m_pctx, &info); gammaBinding->m_texs[0].tex.reset(); } else { pipe_blit_info binfo = {}; binfo.src.resource = csource->m_colorTex; binfo.dst.resource = backBuf->texture; u_box_2d(0, 0, csource->m_width, csource->m_height, &binfo.src.box); binfo.dst.box = binfo.src.box; binfo.src.format = binfo.dst.format = PIPE_FORMAT_R8G8B8A8_UNORM; binfo.mask = PIPE_MASK_RGBA; binfo.filter = PIPE_TEX_FILTER_NEAREST; m_ctx->m_pctx->blit(m_ctx->m_pctx, &binfo); } m_resolveDispSource.reset(); return true; } void _resolveBindTexture(NXTextureR* ctexture, const SWindowRect& rect, bool tlOrigin, int bindIdx, bool color, bool depth) { SWindowRect intersectRect = rect.intersect(SWindowRect(0, 0, ctexture->m_width, ctexture->m_height)); if (color && ctexture->m_colorBindCount) { pipe_blit_info binfo = {}; binfo.src.resource = ctexture->m_colorTex; binfo.dst.resource = ctexture->m_colorBindTex[bindIdx]; u_box_2d(intersectRect.location[0], tlOrigin ? intersectRect.location[1] : (ctexture->m_height - intersectRect.size[1] - intersectRect.location[1]), intersectRect.size[0], intersectRect.size[1], &binfo.src.box); binfo.dst.box = binfo.src.box; binfo.src.format = binfo.dst.format = PIPE_FORMAT_R8G8B8A8_UNORM; binfo.mask = PIPE_MASK_RGBA; binfo.filter = PIPE_TEX_FILTER_NEAREST; m_ctx->m_pctx->blit(m_ctx->m_pctx, &binfo); } if (depth && ctexture->m_depthBindCount) { pipe_blit_info binfo = {}; binfo.src.resource = ctexture->m_depthTex; binfo.dst.resource = ctexture->m_depthBindTex[bindIdx]; u_box_2d(intersectRect.location[0], tlOrigin ? intersectRect.location[1] : (ctexture->m_height - intersectRect.size[1] - intersectRect.location[1]), intersectRect.size[0], intersectRect.size[1], &binfo.src.box); binfo.dst.box = binfo.src.box; binfo.src.format = binfo.dst.format = PIPE_FORMAT_Z32_FLOAT; binfo.mask = PIPE_MASK_Z; binfo.filter = PIPE_TEX_FILTER_NEAREST; m_ctx->m_pctx->blit(m_ctx->m_pctx, &binfo); } } void resolveBindTexture(const boo::ObjToken& texture, const SWindowRect& rect, bool tlOrigin, int bindIdx, bool color, bool depth, bool clearDepth) { NXTextureR* ctexture = texture.cast(); _resolveBindTexture(ctexture, rect, tlOrigin, bindIdx, color, depth); if (clearDepth) m_ctx->m_pctx->clear(m_ctx->m_pctx, PIPE_CLEAR_DEPTH, nullptr, 1.f, 0); } void execute(); }; NXDataFactory::Context::Context(NXDataFactory& parent __BooTraceArgs) : m_parent(parent), m_data(new NXData(static_cast(parent) __BooTraceArgsUse)) {} NXDataFactory::Context::~Context() {} boo::ObjToken NXDataFactory::Context::newStaticBuffer(BufferUse use, const void* data, size_t stride, size_t count) { NXDataFactoryImpl& factory = static_cast(m_parent); return {new NXGraphicsBufferS(m_data, use, factory.m_ctx, data, stride, count)}; } boo::ObjToken NXDataFactory::Context::newDynamicBuffer(BufferUse use, size_t stride, size_t count) { NXDataFactoryImpl& factory = static_cast(m_parent); return {new NXGraphicsBufferD(m_data, use, factory.m_ctx, stride, count)}; } boo::ObjToken NXDataFactory::Context::newStaticTexture(size_t width, size_t height, size_t mips, TextureFormat fmt, TextureClampMode clampMode, const void* data, size_t sz) { NXDataFactoryImpl& factory = static_cast(m_parent); return {new NXTextureS(m_data, factory.m_ctx, width, height, mips, fmt, clampMode, data, sz)}; } boo::ObjToken NXDataFactory::Context::newStaticArrayTexture(size_t width, size_t height, size_t layers, size_t mips, TextureFormat fmt, TextureClampMode clampMode, const void* data, size_t sz) { NXDataFactoryImpl& factory = static_cast(m_parent); return {new NXTextureSA(m_data, factory.m_ctx, width, height, layers, mips, fmt, clampMode, data, sz)}; } boo::ObjToken NXDataFactory::Context::newDynamicTexture(size_t width, size_t height, TextureFormat fmt, TextureClampMode clampMode) { NXDataFactoryImpl& factory = static_cast(m_parent); NXCommandQueue* q = static_cast(factory.m_parent->getCommandQueue()); return {new NXTextureD(m_data, q, width, height, fmt, clampMode)}; } boo::ObjToken NXDataFactory::Context::newRenderTexture(size_t width, size_t height, TextureClampMode clampMode, size_t colorBindCount, size_t depthBindCount) { NXDataFactoryImpl& factory = static_cast(m_parent); return {new NXTextureR(m_data, factory.m_ctx, width, height, clampMode, colorBindCount, depthBindCount)}; } ObjToken NXDataFactory::Context::newShaderStage(const uint8_t* data, size_t size, PipelineStage stage) { NXDataFactoryImpl& factory = static_cast(m_parent); return {new NXShaderStage(m_data, factory.m_ctx, data, size, stage)}; } ObjToken NXDataFactory::Context::newShaderPipeline( ObjToken vertex, ObjToken fragment, ObjToken geometry, ObjToken control, ObjToken evaluation, const VertexFormatInfo& vtxFmt, const AdditionalPipelineInfo& info) { NXDataFactoryImpl& factory = static_cast(m_parent); return {new NXShaderPipeline(m_data, factory.m_ctx, vertex, fragment, geometry, control, evaluation, vtxFmt, info)}; } boo::ObjToken NXDataFactory::Context::newShaderDataBinding( const boo::ObjToken& pipeline, const boo::ObjToken& vbo, const boo::ObjToken& instVbo, const boo::ObjToken& ibo, size_t ubufCount, const boo::ObjToken* ubufs, const PipelineStage* ubufStages, const size_t* ubufOffs, const size_t* ubufSizes, size_t texCount, const boo::ObjToken* texs, const int* bindIdxs, const bool* bindDepth, size_t baseVert, size_t baseInst) { NXDataFactoryImpl& factory = static_cast(m_parent); return {new NXShaderDataBinding(m_data, factory, pipeline, vbo, instVbo, ibo, ubufCount, ubufs, ubufOffs, ubufSizes, texCount, texs, bindIdxs, bindDepth, baseVert, baseInst)}; } NXTextureD::NXTextureD(const boo::ObjToken& parent, NXCommandQueue* q, size_t width, size_t height, TextureFormat fmt, TextureClampMode clampMode) : GraphicsDataNode(parent), m_q(q), m_width(width), m_height(height), m_fmt(fmt), m_clampMode(clampMode) { NXContext* ctx = m_q->m_ctx; pipe_format pfmt; switch (fmt) { case TextureFormat::RGBA8: pfmt = PIPE_FORMAT_R8G8B8A8_UNORM; m_cpuSz = width * height * 4; break; case TextureFormat::I8: pfmt = PIPE_FORMAT_R8_UNORM; m_cpuSz = width * height; break; case TextureFormat::I16: pfmt = PIPE_FORMAT_R16_UNORM; m_cpuSz = width * height * 2; break; default: Log.report(logvisor::Fatal, FMT_STRING("unsupported tex format")); } m_nxFmt = pfmt; m_stagingBuf.reset(new uint8_t[m_cpuSz]); struct pipe_resource texTempl = {}; texTempl.target = PIPE_TEXTURE_2D; texTempl.format = m_nxFmt; texTempl.width0 = width; texTempl.height0 = height; texTempl.depth0 = 1; texTempl.array_size = 1; texTempl.bind = PIPE_BIND_SAMPLER_VIEW; for (int i = 0; i < 2; ++i) { m_gpuTex[i] = ctx->m_screen->resource_create(ctx->m_screen, &texTempl); if (!m_gpuTex[i]) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create texture")); return; } } struct pipe_sampler_view svTempl = {}; svTempl.format = m_nxFmt; svTempl.swizzle_r = PIPE_SWIZZLE_X; svTempl.swizzle_g = PIPE_SWIZZLE_Y; svTempl.swizzle_b = PIPE_SWIZZLE_Z; svTempl.swizzle_a = PIPE_SWIZZLE_W; for (int i = 0; i < 2; ++i) { svTempl.texture = m_gpuTex[i]; m_gpuView[i] = ctx->m_pctx->create_sampler_view(ctx->m_pctx, m_gpuTex[i], &svTempl); } } void NXTextureD::update(int b) { int slot = 1 << b; if ((slot & m_validSlots) == 0) { NXContext* ctx = m_q->m_ctx; uint blockSize = util_format_get_blocksize(m_nxFmt); uint8_t* ptr = m_stagingBuf.get(); size_t rowStride = m_width * blockSize; size_t imageBytes = rowStride * m_height; struct pipe_box box; u_box_2d(0, 0, m_width, m_height, &box); ctx->m_pctx->texture_subdata(ctx->m_pctx, m_gpuTex[m_q->m_fillBuf], 0, PIPE_TRANSFER_WRITE, &box, ptr, rowStride, imageBytes); m_validSlots |= slot; } } void NXTextureD::setClampMode(TextureClampMode mode) { m_clampMode = mode; MakeSampler(m_q->m_ctx, m_sampler, mode, 1); } void NXTextureD::load(const void* data, size_t sz) { size_t bufSz = std::min(sz, m_cpuSz); memmove(m_stagingBuf.get(), data, bufSz); m_validSlots = 0; } void* NXTextureD::map(size_t sz) { if (sz > m_cpuSz) return nullptr; return m_stagingBuf.get(); } void NXTextureD::unmap() { m_validSlots = 0; } static inline struct pipe_resource* pipe_buffer_create_flags(struct pipe_screen* screen, unsigned bind, enum pipe_resource_usage usage, unsigned flags, unsigned size) { struct pipe_resource buffer; memset(&buffer, 0, sizeof buffer); buffer.target = PIPE_BUFFER; buffer.format = PIPE_FORMAT_R8_UNORM; /* want TYPELESS or similar */ buffer.bind = bind; buffer.usage = usage; buffer.flags = flags; buffer.width0 = size; buffer.height0 = 1; buffer.depth0 = 1; buffer.array_size = 1; return screen->resource_create(screen, &buffer); } void NXDataFactoryImpl::commitTransaction( const std::function& trans __BooTraceArgs) { Context ctx(*this __BooTraceArgsUse); if (!trans(ctx)) return; NXData* data = ctx.m_data.cast(); /* size up resources */ unsigned constantMemSizes[3] = {}; if (data->m_SBufs) for (IGraphicsBufferS& buf : *data->m_SBufs) { auto& cbuf = static_cast(buf); if (cbuf.m_use == BufferUse::Null) continue; unsigned& sz = constantMemSizes[int(cbuf.m_use) - 1]; sz = cbuf.sizeForGPU(m_ctx, sz); } if (data->m_DBufs) for (IGraphicsBufferD& buf : *data->m_DBufs) { auto& cbuf = static_cast&>(buf); if (cbuf.m_use == BufferUse::Null) continue; unsigned& sz = constantMemSizes[int(cbuf.m_use) - 1]; sz = cbuf.sizeForGPU(m_ctx, sz); } /* allocate memory and place buffers */ for (int i = 0; i < 3; ++i) { if (constantMemSizes[i]) { struct pipe_resource* poolBuf = pipe_buffer_create_flags( m_ctx->m_screen, USE_TABLE[i + 1], PIPE_USAGE_DEFAULT, PIPE_RESOURCE_FLAG_MAP_PERSISTENT | PIPE_RESOURCE_FLAG_MAP_COHERENT, constantMemSizes[i]); data->m_constantBuffers[i] = poolBuf; pipe_transfer* xfer; uint8_t* mappedData = (uint8_t*)pipe_buffer_map( m_ctx->m_pctx, poolBuf, PIPE_TRANSFER_WRITE | PIPE_TRANSFER_MAP_DIRECTLY | PIPE_TRANSFER_PERSISTENT | PIPE_TRANSFER_COHERENT, &xfer); if (data->m_SBufs) for (IGraphicsBufferS& buf : *data->m_SBufs) { auto& cbuf = static_cast(buf); if (int(cbuf.m_use) - 1 != i) continue; cbuf.placeForGPU(poolBuf, mappedData); } if (data->m_DBufs) for (IGraphicsBufferD& buf : *data->m_DBufs) { auto& cbuf = static_cast&>(buf); if (int(cbuf.m_use) - 1 != i) continue; cbuf.placeForGPU(poolBuf, mappedData); } } } /* Commit data bindings (create descriptor sets) */ if (data->m_SBinds) for (IShaderDataBinding& bind : *data->m_SBinds) static_cast(bind).commit(); } boo::ObjToken NXDataFactoryImpl::newPoolBuffer(BufferUse use, size_t stride, size_t count __BooTraceArgs) { boo::ObjToken pool(new NXPool(*this __BooTraceArgsUse)); NXPool* cpool = pool.cast(); NXGraphicsBufferD* retval = new NXGraphicsBufferD(pool, use, m_ctx, stride, count); unsigned size = retval->sizeForGPU(m_ctx, 0); /* allocate memory */ if (size) { struct pipe_resource* poolBuf = pipe_buffer_create_flags(m_ctx->m_screen, USE_TABLE[int(use)], PIPE_USAGE_DEFAULT, PIPE_RESOURCE_FLAG_MAP_PERSISTENT | PIPE_RESOURCE_FLAG_MAP_COHERENT, size); cpool->m_constantBuffer = poolBuf; pipe_transfer* xfer; uint8_t* mappedData = (uint8_t*)pipe_buffer_map( m_ctx->m_pctx, poolBuf, PIPE_TRANSFER_WRITE | PIPE_TRANSFER_MAP_DIRECTLY | PIPE_TRANSFER_PERSISTENT | PIPE_TRANSFER_COHERENT, &xfer); retval->placeForGPU(poolBuf, mappedData); } return {retval}; } void NXCommandQueue::execute() { if (!m_running) return; /* Stage dynamic uploads */ NXDataFactoryImpl* gfxF = static_cast(m_parent->getDataFactory()); std::unique_lock datalk(gfxF->m_dataMutex); if (gfxF->m_dataHead) { for (BaseGraphicsData& d : *gfxF->m_dataHead) { if (d.m_DBufs) for (IGraphicsBufferD& b : *d.m_DBufs) static_cast&>(b).update(m_fillBuf); if (d.m_DTexs) for (ITextureD& t : *d.m_DTexs) static_cast(t).update(m_fillBuf); } } if (gfxF->m_poolHead) { for (BaseGraphicsPool& p : *gfxF->m_poolHead) { if (p.m_DBufs) for (IGraphicsBufferD& b : *p.m_DBufs) static_cast&>(b).update(m_fillBuf); } } datalk.unlock(); /* Perform texture and swap-chain resizes */ if (m_ctx->_resizeWindowSurfaces() || m_texResizes.size()) { for (const auto& resize : m_texResizes) { if (m_boundTarget.get() == resize.first) m_boundTarget.reset(); resize.first->resize(m_ctx, resize.second.first, resize.second.second); } m_texResizes.clear(); m_resolveDispSource = nullptr; return; } /* Clear dead data */ m_drawResTokens[m_drawBuf].clear(); /* Swap internal buffers */ m_drawBuf = m_fillBuf; m_fillBuf ^= 1; /* Flush the pipe */ m_ctx->m_pctx->flush(m_ctx->m_pctx, nullptr, PIPE_FLUSH_END_OF_FRAME); /* Set framebuffer fence */ NvFence fence; struct pipe_surface* old_back = m_ctx->m_windowSurfaces[ST_ATTACHMENT_BACK_LEFT]; fence.id = nouveau_switch_resource_get_syncpoint(old_back->texture, &fence.value); if ((int)fence.id >= 0) { NvFence* surf_fence = &m_ctx->m_fences[m_ctx->m_fence_swap]; if (surf_fence->id != fence.id || surf_fence->value != fence.value) { *surf_fence = fence; NvMultiFence mf; nvMultiFenceCreate(&mf, &fence); gfxAppendFence(&mf); } } gfxSwapBuffers(); /* Swap buffer attachments and invalidate framebuffer */ m_ctx->m_fence_swap = !m_ctx->m_fence_swap; m_ctx->m_windowSurfaces[ST_ATTACHMENT_BACK_LEFT] = m_ctx->m_windowSurfaces[ST_ATTACHMENT_FRONT_LEFT]; m_ctx->m_windowSurfaces[ST_ATTACHMENT_FRONT_LEFT] = old_back; } static void setMesaConfig() { // Uncomment below to disable error checking and save CPU time (useful for production): // setenv("MESA_NO_ERROR", "1", 1); // Uncomment below to enable Mesa logging: setenv("EGL_LOG_LEVEL", "debug", 1); setenv("MESA_VERBOSE", "all", 1); setenv("NOUVEAU_MESA_DEBUG", "1", 1); // Uncomment below to enable shader debugging in Nouveau: setenv("NV50_PROG_OPTIMIZE", "0", 1); setenv("NV50_PROG_DEBUG", "1", 1); setenv("NV50_PROG_CHIPSET", "0x120", 1); } bool NXContext::initialize() { /* Set mesa configuration (useful for debugging) */ setMesaConfig(); gfxInitDefault(); gfxSetMode(GfxMode_TiledDouble); consoleInit(nullptr); printf("Activated console\n\n"); m_screen = nouveau_switch_screen_create(); if (!m_screen) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create nouveau screen")); return false; } printf("nouveau_switch_screen_create done\n"); fflush(stdout); m_pctx = m_screen->context_create(m_screen, nullptr, 0); if (!m_pctx) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create pipe context")); m_screen->destroy(m_screen); return false; } printf("m_screen->context_create done\n"); st_config_options opts = {}; m_st = st_create_context(API_OPENGL_CORE, m_pctx, nullptr, nullptr, &opts, false); if (!m_st) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create st context")); m_screen->destroy(m_screen); return false; } u32 width, height; gfxGetFramebufferResolution(&width, &height); for (int i = 0; i < 2; ++i) { /* color target */ struct pipe_resource texTempl = {}; texTempl.target = PIPE_TEXTURE_RECT; texTempl.format = ColorFormat; texTempl.width0 = width; texTempl.height0 = height; texTempl.depth0 = 1; texTempl.array_size = 1; texTempl.usage = PIPE_USAGE_DEFAULT; texTempl.nr_samples = texTempl.nr_storage_samples = 1; texTempl.bind = PIPE_BIND_RENDER_TARGET; u32 index = i == ST_ATTACHMENT_FRONT_LEFT ? 1 : 0; struct winsys_handle whandle; whandle.type = WINSYS_HANDLE_TYPE_SHARED; whandle.handle = gfxGetFramebufferHandle(index, &whandle.offset); whandle.stride = gfxGetFramebufferPitch(); struct pipe_resource* tex = m_screen->resource_from_handle(m_screen, &texTempl, &whandle, 0); if (!tex) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create color target texture")); return false; } /* surface */ struct pipe_surface surfTempl = {}; surfTempl.format = ColorFormat; m_windowSurfaces[i] = m_pctx->create_surface(m_pctx, tex, &surfTempl); if (!m_windowSurfaces[i]) { Log.report(logvisor::Fatal, FMT_STRING("Failed to create color surface")); return false; } m_fences[i].id = UINT32_MAX; } return m_compiler.initialize(m_screen, m_st); } bool NXContext::terminate() { if (m_st) st_destroy_context(m_st); if (m_screen) m_screen->destroy(m_screen); gfxExit(); return true; } bool NXContext::_resizeWindowSurfaces() { return false; } std::unique_ptr _NewNXCommandQueue(NXContext* ctx, IGraphicsContext* parent) { return std::make_unique(ctx, parent); } std::unique_ptr _NewNXDataFactory(IGraphicsContext* parent, NXContext* ctx) { return std::make_unique(parent, ctx); } } // namespace boo