use super::conv; use arrayvec::ArrayVec; use ash::{extensions::ext, vk}; use std::{mem, ops::Range, slice}; const ALLOCATION_GRANULARITY: u32 = 16; const DST_IMAGE_LAYOUT: vk::ImageLayout = vk::ImageLayout::TRANSFER_DST_OPTIMAL; impl super::Texture { fn map_buffer_copies(&self, regions: T) -> impl Iterator where T: Iterator, { let (block_width, block_height) = self.format.block_dimensions(); let format = self.format; let copy_size = self.copy_size; regions.map(move |r| { let extent = r.texture_base.max_copy_size(©_size).min(&r.size); let (image_subresource, image_offset) = conv::map_subresource_layers(&r.texture_base); vk::BufferImageCopy { buffer_offset: r.buffer_layout.offset, buffer_row_length: r.buffer_layout.bytes_per_row.map_or(0, |bpr| { let block_size = format .block_copy_size(Some(r.texture_base.aspect.map())) .unwrap(); block_width * (bpr / block_size) }), buffer_image_height: r .buffer_layout .rows_per_image .map_or(0, |rpi| rpi * block_height), image_subresource, image_offset, image_extent: conv::map_copy_extent(&extent), } }) } } impl super::DeviceShared { fn debug_messenger(&self) -> Option<&ext::DebugUtils> { Some(&self.instance.debug_utils.as_ref()?.extension) } } impl super::CommandEncoder { fn write_pass_end_timestamp_if_requested(&mut self) { if let Some((query_set, index)) = self.end_of_pass_timer_query.take() { unsafe { self.device.raw.cmd_write_timestamp( self.active, vk::PipelineStageFlags::BOTTOM_OF_PIPE, query_set, index, ); } } } } impl crate::CommandEncoder for super::CommandEncoder { type A = super::Api; unsafe fn begin_encoding(&mut self, label: crate::Label) -> Result<(), crate::DeviceError> { if self.free.is_empty() { let vk_info = vk::CommandBufferAllocateInfo::builder() .command_pool(self.raw) .command_buffer_count(ALLOCATION_GRANULARITY) .build(); let cmd_buf_vec = unsafe { self.device.raw.allocate_command_buffers(&vk_info)? }; self.free.extend(cmd_buf_vec); } let raw = self.free.pop().unwrap(); // Set the name unconditionally, since there might be a // previous name assigned to this. unsafe { self.device.set_object_name( vk::ObjectType::COMMAND_BUFFER, raw, label.unwrap_or_default(), ) }; // Reset this in case the last renderpass was never ended. self.rpass_debug_marker_active = false; let vk_info = vk::CommandBufferBeginInfo::builder() .flags(vk::CommandBufferUsageFlags::ONE_TIME_SUBMIT) .build(); unsafe { self.device.raw.begin_command_buffer(raw, &vk_info) }?; self.active = raw; Ok(()) } unsafe fn end_encoding(&mut self) -> Result { let raw = self.active; self.active = vk::CommandBuffer::null(); unsafe { self.device.raw.end_command_buffer(raw) }?; Ok(super::CommandBuffer { raw }) } unsafe fn discard_encoding(&mut self) { // Safe use requires this is not called in the "closed" state, so the buffer // shouldn't be null. Assert this to make sure we're not pushing null // buffers to the discard pile. assert_ne!(self.active, vk::CommandBuffer::null()); self.discarded.push(self.active); self.active = vk::CommandBuffer::null(); } unsafe fn reset_all(&mut self, cmd_bufs: I) where I: Iterator, { self.temp.clear(); self.free .extend(cmd_bufs.into_iter().map(|cmd_buf| cmd_buf.raw)); self.free.append(&mut self.discarded); let _ = unsafe { self.device .raw .reset_command_pool(self.raw, vk::CommandPoolResetFlags::default()) }; } unsafe fn transition_buffers<'a, T>(&mut self, barriers: T) where T: Iterator>, { //Note: this is done so that we never end up with empty stage flags let mut src_stages = vk::PipelineStageFlags::TOP_OF_PIPE; let mut dst_stages = vk::PipelineStageFlags::BOTTOM_OF_PIPE; let vk_barriers = &mut self.temp.buffer_barriers; vk_barriers.clear(); for bar in barriers { let (src_stage, src_access) = conv::map_buffer_usage_to_barrier(bar.usage.start); src_stages |= src_stage; let (dst_stage, dst_access) = conv::map_buffer_usage_to_barrier(bar.usage.end); dst_stages |= dst_stage; vk_barriers.push( vk::BufferMemoryBarrier::builder() .buffer(bar.buffer.raw) .size(vk::WHOLE_SIZE) .src_access_mask(src_access) .dst_access_mask(dst_access) .build(), ) } if !vk_barriers.is_empty() { unsafe { self.device.raw.cmd_pipeline_barrier( self.active, src_stages, dst_stages, vk::DependencyFlags::empty(), &[], vk_barriers, &[], ) }; } } unsafe fn transition_textures<'a, T>(&mut self, barriers: T) where T: Iterator>, { let mut src_stages = vk::PipelineStageFlags::empty(); let mut dst_stages = vk::PipelineStageFlags::empty(); let vk_barriers = &mut self.temp.image_barriers; vk_barriers.clear(); for bar in barriers { let range = conv::map_subresource_range_combined_aspect( &bar.range, bar.texture.format, &self.device.private_caps, ); let (src_stage, src_access) = conv::map_texture_usage_to_barrier(bar.usage.start); let src_layout = conv::derive_image_layout(bar.usage.start, bar.texture.format); src_stages |= src_stage; let (dst_stage, dst_access) = conv::map_texture_usage_to_barrier(bar.usage.end); let dst_layout = conv::derive_image_layout(bar.usage.end, bar.texture.format); dst_stages |= dst_stage; vk_barriers.push( vk::ImageMemoryBarrier::builder() .image(bar.texture.raw) .subresource_range(range) .src_access_mask(src_access) .dst_access_mask(dst_access) .old_layout(src_layout) .new_layout(dst_layout) .build(), ); } if !vk_barriers.is_empty() { unsafe { self.device.raw.cmd_pipeline_barrier( self.active, src_stages, dst_stages, vk::DependencyFlags::empty(), &[], &[], vk_barriers, ) }; } } unsafe fn clear_buffer(&mut self, buffer: &super::Buffer, range: crate::MemoryRange) { let range_size = range.end - range.start; if self.device.workarounds.contains( super::Workarounds::FORCE_FILL_BUFFER_WITH_SIZE_GREATER_4096_ALIGNED_OFFSET_16, ) && range_size >= 4096 && range.start % 16 != 0 { let rounded_start = wgt::math::align_to(range.start, 16); let prefix_size = rounded_start - range.start; unsafe { self.device.raw.cmd_fill_buffer( self.active, buffer.raw, range.start, prefix_size, 0, ) }; // This will never be zero, as rounding can only add up to 12 bytes, and the total size is 4096. let suffix_size = range.end - rounded_start; unsafe { self.device.raw.cmd_fill_buffer( self.active, buffer.raw, rounded_start, suffix_size, 0, ) }; } else { unsafe { self.device .raw .cmd_fill_buffer(self.active, buffer.raw, range.start, range_size, 0) }; } } unsafe fn copy_buffer_to_buffer( &mut self, src: &super::Buffer, dst: &super::Buffer, regions: T, ) where T: Iterator, { let vk_regions_iter = regions.map(|r| vk::BufferCopy { src_offset: r.src_offset, dst_offset: r.dst_offset, size: r.size.get(), }); unsafe { self.device.raw.cmd_copy_buffer( self.active, src.raw, dst.raw, &smallvec::SmallVec::<[vk::BufferCopy; 32]>::from_iter(vk_regions_iter), ) }; } unsafe fn copy_texture_to_texture( &mut self, src: &super::Texture, src_usage: crate::TextureUses, dst: &super::Texture, regions: T, ) where T: Iterator, { let src_layout = conv::derive_image_layout(src_usage, src.format); let vk_regions_iter = regions.map(|r| { let (src_subresource, src_offset) = conv::map_subresource_layers(&r.src_base); let (dst_subresource, dst_offset) = conv::map_subresource_layers(&r.dst_base); let extent = r .size .min(&r.src_base.max_copy_size(&src.copy_size)) .min(&r.dst_base.max_copy_size(&dst.copy_size)); vk::ImageCopy { src_subresource, src_offset, dst_subresource, dst_offset, extent: conv::map_copy_extent(&extent), } }); unsafe { self.device.raw.cmd_copy_image( self.active, src.raw, src_layout, dst.raw, DST_IMAGE_LAYOUT, &smallvec::SmallVec::<[vk::ImageCopy; 32]>::from_iter(vk_regions_iter), ) }; } unsafe fn copy_buffer_to_texture( &mut self, src: &super::Buffer, dst: &super::Texture, regions: T, ) where T: Iterator, { let vk_regions_iter = dst.map_buffer_copies(regions); unsafe { self.device.raw.cmd_copy_buffer_to_image( self.active, src.raw, dst.raw, DST_IMAGE_LAYOUT, &smallvec::SmallVec::<[vk::BufferImageCopy; 32]>::from_iter(vk_regions_iter), ) }; } unsafe fn copy_texture_to_buffer( &mut self, src: &super::Texture, src_usage: crate::TextureUses, dst: &super::Buffer, regions: T, ) where T: Iterator, { let src_layout = conv::derive_image_layout(src_usage, src.format); let vk_regions_iter = src.map_buffer_copies(regions); unsafe { self.device.raw.cmd_copy_image_to_buffer( self.active, src.raw, src_layout, dst.raw, &smallvec::SmallVec::<[vk::BufferImageCopy; 32]>::from_iter(vk_regions_iter), ) }; } unsafe fn begin_query(&mut self, set: &super::QuerySet, index: u32) { unsafe { self.device.raw.cmd_begin_query( self.active, set.raw, index, vk::QueryControlFlags::empty(), ) }; } unsafe fn end_query(&mut self, set: &super::QuerySet, index: u32) { unsafe { self.device.raw.cmd_end_query(self.active, set.raw, index) }; } unsafe fn write_timestamp(&mut self, set: &super::QuerySet, index: u32) { unsafe { self.device.raw.cmd_write_timestamp( self.active, vk::PipelineStageFlags::BOTTOM_OF_PIPE, set.raw, index, ) }; } unsafe fn reset_queries(&mut self, set: &super::QuerySet, range: Range) { unsafe { self.device.raw.cmd_reset_query_pool( self.active, set.raw, range.start, range.end - range.start, ) }; } unsafe fn copy_query_results( &mut self, set: &super::QuerySet, range: Range, buffer: &super::Buffer, offset: wgt::BufferAddress, stride: wgt::BufferSize, ) { unsafe { self.device.raw.cmd_copy_query_pool_results( self.active, set.raw, range.start, range.end - range.start, buffer.raw, offset, stride.get(), vk::QueryResultFlags::TYPE_64 | vk::QueryResultFlags::WAIT, ) }; } unsafe fn build_acceleration_structures<'a, T>(&mut self, descriptor_count: u32, descriptors: T) where super::Api: 'a, T: IntoIterator>, { const CAPACITY_OUTER: usize = 8; const CAPACITY_INNER: usize = 1; let descriptor_count = descriptor_count as usize; let ray_tracing_functions = self .device .extension_fns .ray_tracing .as_ref() .expect("Feature `RAY_TRACING` not enabled"); let get_device_address = |buffer: Option<&super::Buffer>| unsafe { match buffer { Some(buffer) => ray_tracing_functions .buffer_device_address .get_buffer_device_address( &vk::BufferDeviceAddressInfo::builder().buffer(buffer.raw), ), None => panic!("Buffers are required to build acceleration structures"), } }; // storage to all the data required for cmd_build_acceleration_structures let mut ranges_storage = smallvec::SmallVec::< [smallvec::SmallVec<[vk::AccelerationStructureBuildRangeInfoKHR; CAPACITY_INNER]>; CAPACITY_OUTER], >::with_capacity(descriptor_count); let mut geometries_storage = smallvec::SmallVec::< [smallvec::SmallVec<[vk::AccelerationStructureGeometryKHR; CAPACITY_INNER]>; CAPACITY_OUTER], >::with_capacity(descriptor_count); // pointers to all the data required for cmd_build_acceleration_structures let mut geometry_infos = smallvec::SmallVec::< [vk::AccelerationStructureBuildGeometryInfoKHR; CAPACITY_OUTER], >::with_capacity(descriptor_count); let mut ranges_ptrs = smallvec::SmallVec::< [&[vk::AccelerationStructureBuildRangeInfoKHR]; CAPACITY_OUTER], >::with_capacity(descriptor_count); for desc in descriptors { let (geometries, ranges) = match *desc.entries { crate::AccelerationStructureEntries::Instances(ref instances) => { let instance_data = vk::AccelerationStructureGeometryInstancesDataKHR::builder( ) .data(vk::DeviceOrHostAddressConstKHR { device_address: get_device_address(instances.buffer), }); let geometry = vk::AccelerationStructureGeometryKHR::builder() .geometry_type(vk::GeometryTypeKHR::INSTANCES) .geometry(vk::AccelerationStructureGeometryDataKHR { instances: *instance_data, }); let range = vk::AccelerationStructureBuildRangeInfoKHR::builder() .primitive_count(instances.count) .primitive_offset(instances.offset); (smallvec::smallvec![*geometry], smallvec::smallvec![*range]) } crate::AccelerationStructureEntries::Triangles(ref in_geometries) => { let mut ranges = smallvec::SmallVec::< [vk::AccelerationStructureBuildRangeInfoKHR; CAPACITY_INNER], >::with_capacity(in_geometries.len()); let mut geometries = smallvec::SmallVec::< [vk::AccelerationStructureGeometryKHR; CAPACITY_INNER], >::with_capacity(in_geometries.len()); for triangles in in_geometries { let mut triangle_data = vk::AccelerationStructureGeometryTrianglesDataKHR::builder() .vertex_data(vk::DeviceOrHostAddressConstKHR { device_address: get_device_address(triangles.vertex_buffer), }) .vertex_format(conv::map_vertex_format(triangles.vertex_format)) .max_vertex(triangles.vertex_count) .vertex_stride(triangles.vertex_stride); let mut range = vk::AccelerationStructureBuildRangeInfoKHR::builder(); if let Some(ref indices) = triangles.indices { triangle_data = triangle_data .index_data(vk::DeviceOrHostAddressConstKHR { device_address: get_device_address(indices.buffer), }) .index_type(conv::map_index_format(indices.format)); range = range .primitive_count(indices.count / 3) .primitive_offset(indices.offset) .first_vertex(triangles.first_vertex); } else { range = range .primitive_count(triangles.vertex_count) .first_vertex(triangles.first_vertex); } if let Some(ref transform) = triangles.transform { let transform_device_address = unsafe { ray_tracing_functions .buffer_device_address .get_buffer_device_address( &vk::BufferDeviceAddressInfo::builder() .buffer(transform.buffer.raw), ) }; triangle_data = triangle_data.transform_data(vk::DeviceOrHostAddressConstKHR { device_address: transform_device_address, }); range = range.transform_offset(transform.offset); } let geometry = vk::AccelerationStructureGeometryKHR::builder() .geometry_type(vk::GeometryTypeKHR::TRIANGLES) .geometry(vk::AccelerationStructureGeometryDataKHR { triangles: *triangle_data, }) .flags(conv::map_acceleration_structure_geometry_flags( triangles.flags, )); geometries.push(*geometry); ranges.push(*range); } (geometries, ranges) } crate::AccelerationStructureEntries::AABBs(ref in_geometries) => { let mut ranges = smallvec::SmallVec::< [vk::AccelerationStructureBuildRangeInfoKHR; CAPACITY_INNER], >::with_capacity(in_geometries.len()); let mut geometries = smallvec::SmallVec::< [vk::AccelerationStructureGeometryKHR; CAPACITY_INNER], >::with_capacity(in_geometries.len()); for aabb in in_geometries { let aabbs_data = vk::AccelerationStructureGeometryAabbsDataKHR::builder() .data(vk::DeviceOrHostAddressConstKHR { device_address: get_device_address(aabb.buffer), }) .stride(aabb.stride); let range = vk::AccelerationStructureBuildRangeInfoKHR::builder() .primitive_count(aabb.count) .primitive_offset(aabb.offset); let geometry = vk::AccelerationStructureGeometryKHR::builder() .geometry_type(vk::GeometryTypeKHR::AABBS) .geometry(vk::AccelerationStructureGeometryDataKHR { aabbs: *aabbs_data, }) .flags(conv::map_acceleration_structure_geometry_flags(aabb.flags)); geometries.push(*geometry); ranges.push(*range); } (geometries, ranges) } }; ranges_storage.push(ranges); geometries_storage.push(geometries); let scratch_device_address = unsafe { ray_tracing_functions .buffer_device_address .get_buffer_device_address( &vk::BufferDeviceAddressInfo::builder().buffer(desc.scratch_buffer.raw), ) }; let ty = match *desc.entries { crate::AccelerationStructureEntries::Instances(_) => { vk::AccelerationStructureTypeKHR::TOP_LEVEL } _ => vk::AccelerationStructureTypeKHR::BOTTOM_LEVEL, }; let mut geometry_info = vk::AccelerationStructureBuildGeometryInfoKHR::builder() .ty(ty) .mode(conv::map_acceleration_structure_build_mode(desc.mode)) .flags(conv::map_acceleration_structure_flags(desc.flags)) .dst_acceleration_structure(desc.destination_acceleration_structure.raw) .scratch_data(vk::DeviceOrHostAddressKHR { device_address: scratch_device_address + desc.scratch_buffer_offset, }); if desc.mode == crate::AccelerationStructureBuildMode::Update { geometry_info.src_acceleration_structure = desc .source_acceleration_structure .unwrap_or(desc.destination_acceleration_structure) .raw; } geometry_infos.push(*geometry_info); } for (i, geometry_info) in geometry_infos.iter_mut().enumerate() { geometry_info.geometry_count = geometries_storage[i].len() as u32; geometry_info.p_geometries = geometries_storage[i].as_ptr(); ranges_ptrs.push(&ranges_storage[i]); } unsafe { ray_tracing_functions .acceleration_structure .cmd_build_acceleration_structures(self.active, &geometry_infos, &ranges_ptrs); } } unsafe fn place_acceleration_structure_barrier( &mut self, barrier: crate::AccelerationStructureBarrier, ) { let (src_stage, src_access) = conv::map_acceleration_structure_usage_to_barrier(barrier.usage.start); let (dst_stage, dst_access) = conv::map_acceleration_structure_usage_to_barrier(barrier.usage.end); unsafe { self.device.raw.cmd_pipeline_barrier( self.active, src_stage | vk::PipelineStageFlags::TOP_OF_PIPE, dst_stage | vk::PipelineStageFlags::BOTTOM_OF_PIPE, vk::DependencyFlags::empty(), &[vk::MemoryBarrier::builder() .src_access_mask(src_access) .dst_access_mask(dst_access) .build()], &[], &[], ) }; } // render unsafe fn begin_render_pass(&mut self, desc: &crate::RenderPassDescriptor) { let mut vk_clear_values = ArrayVec::::new(); let mut vk_image_views = ArrayVec::::new(); let mut rp_key = super::RenderPassKey::default(); let mut fb_key = super::FramebufferKey { attachments: ArrayVec::default(), extent: desc.extent, sample_count: desc.sample_count, }; let caps = &self.device.private_caps; for cat in desc.color_attachments { if let Some(cat) = cat.as_ref() { vk_clear_values.push(vk::ClearValue { color: unsafe { cat.make_vk_clear_color() }, }); vk_image_views.push(cat.target.view.raw); let color = super::ColorAttachmentKey { base: cat.target.make_attachment_key(cat.ops, caps), resolve: cat.resolve_target.as_ref().map(|target| { target.make_attachment_key(crate::AttachmentOps::STORE, caps) }), }; rp_key.colors.push(Some(color)); fb_key.attachments.push(cat.target.view.attachment.clone()); if let Some(ref at) = cat.resolve_target { vk_clear_values.push(unsafe { mem::zeroed() }); vk_image_views.push(at.view.raw); fb_key.attachments.push(at.view.attachment.clone()); } // Assert this attachment is valid for the detected multiview, as a sanity check // The driver crash for this is really bad on AMD, so the check is worth it if let Some(multiview) = desc.multiview { assert_eq!(cat.target.view.layers, multiview); if let Some(ref resolve_target) = cat.resolve_target { assert_eq!(resolve_target.view.layers, multiview); } } } else { rp_key.colors.push(None); } } if let Some(ref ds) = desc.depth_stencil_attachment { vk_clear_values.push(vk::ClearValue { depth_stencil: vk::ClearDepthStencilValue { depth: ds.clear_value.0, stencil: ds.clear_value.1, }, }); vk_image_views.push(ds.target.view.raw); rp_key.depth_stencil = Some(super::DepthStencilAttachmentKey { base: ds.target.make_attachment_key(ds.depth_ops, caps), stencil_ops: ds.stencil_ops, }); fb_key.attachments.push(ds.target.view.attachment.clone()); // Assert this attachment is valid for the detected multiview, as a sanity check // The driver crash for this is really bad on AMD, so the check is worth it if let Some(multiview) = desc.multiview { assert_eq!(ds.target.view.layers, multiview); } } rp_key.sample_count = fb_key.sample_count; rp_key.multiview = desc.multiview; let render_area = vk::Rect2D { offset: vk::Offset2D { x: 0, y: 0 }, extent: vk::Extent2D { width: desc.extent.width, height: desc.extent.height, }, }; let vk_viewports = [vk::Viewport { x: 0.0, y: if self.device.private_caps.flip_y_requires_shift { desc.extent.height as f32 } else { 0.0 }, width: desc.extent.width as f32, height: -(desc.extent.height as f32), min_depth: 0.0, max_depth: 1.0, }]; let raw_pass = self.device.make_render_pass(rp_key).unwrap(); let raw_framebuffer = self .device .make_framebuffer(fb_key, raw_pass, desc.label) .unwrap(); let mut vk_info = vk::RenderPassBeginInfo::builder() .render_pass(raw_pass) .render_area(render_area) .clear_values(&vk_clear_values) .framebuffer(raw_framebuffer); let mut vk_attachment_info = if caps.imageless_framebuffers { Some( vk::RenderPassAttachmentBeginInfo::builder() .attachments(&vk_image_views) .build(), ) } else { None }; if let Some(attachment_info) = vk_attachment_info.as_mut() { vk_info = vk_info.push_next(attachment_info); } if let Some(label) = desc.label { unsafe { self.begin_debug_marker(label) }; self.rpass_debug_marker_active = true; } // Start timestamp if any (before all other commands but after debug marker) if let Some(timestamp_writes) = desc.timestamp_writes.as_ref() { if let Some(index) = timestamp_writes.beginning_of_pass_write_index { unsafe { self.write_timestamp(timestamp_writes.query_set, index); } } self.end_of_pass_timer_query = timestamp_writes .end_of_pass_write_index .map(|index| (timestamp_writes.query_set.raw, index)); } unsafe { self.device .raw .cmd_set_viewport(self.active, 0, &vk_viewports); self.device .raw .cmd_set_scissor(self.active, 0, &[render_area]); self.device.raw.cmd_begin_render_pass( self.active, &vk_info, vk::SubpassContents::INLINE, ); }; self.bind_point = vk::PipelineBindPoint::GRAPHICS; } unsafe fn end_render_pass(&mut self) { unsafe { self.device.raw.cmd_end_render_pass(self.active); } // After all other commands but before debug marker, so this is still seen as part of this pass. self.write_pass_end_timestamp_if_requested(); if self.rpass_debug_marker_active { unsafe { self.end_debug_marker(); } self.rpass_debug_marker_active = false; } } unsafe fn set_bind_group( &mut self, layout: &super::PipelineLayout, index: u32, group: &super::BindGroup, dynamic_offsets: &[wgt::DynamicOffset], ) { let sets = [*group.set.raw()]; unsafe { self.device.raw.cmd_bind_descriptor_sets( self.active, self.bind_point, layout.raw, index, &sets, dynamic_offsets, ) }; } unsafe fn set_push_constants( &mut self, layout: &super::PipelineLayout, stages: wgt::ShaderStages, offset_bytes: u32, data: &[u32], ) { unsafe { self.device.raw.cmd_push_constants( self.active, layout.raw, conv::map_shader_stage(stages), offset_bytes, slice::from_raw_parts(data.as_ptr() as _, data.len() * 4), ) }; } unsafe fn insert_debug_marker(&mut self, label: &str) { if let Some(ext) = self.device.debug_messenger() { let cstr = self.temp.make_c_str(label); let vk_label = vk::DebugUtilsLabelEXT::builder().label_name(cstr).build(); unsafe { ext.cmd_insert_debug_utils_label(self.active, &vk_label) }; } } unsafe fn begin_debug_marker(&mut self, group_label: &str) { if let Some(ext) = self.device.debug_messenger() { let cstr = self.temp.make_c_str(group_label); let vk_label = vk::DebugUtilsLabelEXT::builder().label_name(cstr).build(); unsafe { ext.cmd_begin_debug_utils_label(self.active, &vk_label) }; } } unsafe fn end_debug_marker(&mut self) { if let Some(ext) = self.device.debug_messenger() { unsafe { ext.cmd_end_debug_utils_label(self.active) }; } } unsafe fn set_render_pipeline(&mut self, pipeline: &super::RenderPipeline) { unsafe { self.device.raw.cmd_bind_pipeline( self.active, vk::PipelineBindPoint::GRAPHICS, pipeline.raw, ) }; } unsafe fn set_index_buffer<'a>( &mut self, binding: crate::BufferBinding<'a, super::Api>, format: wgt::IndexFormat, ) { unsafe { self.device.raw.cmd_bind_index_buffer( self.active, binding.buffer.raw, binding.offset, conv::map_index_format(format), ) }; } unsafe fn set_vertex_buffer<'a>( &mut self, index: u32, binding: crate::BufferBinding<'a, super::Api>, ) { let vk_buffers = [binding.buffer.raw]; let vk_offsets = [binding.offset]; unsafe { self.device .raw .cmd_bind_vertex_buffers(self.active, index, &vk_buffers, &vk_offsets) }; } unsafe fn set_viewport(&mut self, rect: &crate::Rect, depth_range: Range) { let vk_viewports = [vk::Viewport { x: rect.x, y: if self.device.private_caps.flip_y_requires_shift { rect.y + rect.h } else { rect.y }, width: rect.w, height: -rect.h, // flip Y min_depth: depth_range.start, max_depth: depth_range.end, }]; unsafe { self.device .raw .cmd_set_viewport(self.active, 0, &vk_viewports) }; } unsafe fn set_scissor_rect(&mut self, rect: &crate::Rect) { let vk_scissors = [vk::Rect2D { offset: vk::Offset2D { x: rect.x as i32, y: rect.y as i32, }, extent: vk::Extent2D { width: rect.w, height: rect.h, }, }]; unsafe { self.device .raw .cmd_set_scissor(self.active, 0, &vk_scissors) }; } unsafe fn set_stencil_reference(&mut self, value: u32) { unsafe { self.device.raw.cmd_set_stencil_reference( self.active, vk::StencilFaceFlags::FRONT_AND_BACK, value, ) }; } unsafe fn set_blend_constants(&mut self, color: &[f32; 4]) { unsafe { self.device.raw.cmd_set_blend_constants(self.active, color) }; } unsafe fn draw( &mut self, first_vertex: u32, vertex_count: u32, first_instance: u32, instance_count: u32, ) { unsafe { self.device.raw.cmd_draw( self.active, vertex_count, instance_count, first_vertex, first_instance, ) }; } unsafe fn draw_indexed( &mut self, first_index: u32, index_count: u32, base_vertex: i32, first_instance: u32, instance_count: u32, ) { unsafe { self.device.raw.cmd_draw_indexed( self.active, index_count, instance_count, first_index, base_vertex, first_instance, ) }; } unsafe fn draw_indirect( &mut self, buffer: &super::Buffer, offset: wgt::BufferAddress, draw_count: u32, ) { unsafe { self.device.raw.cmd_draw_indirect( self.active, buffer.raw, offset, draw_count, mem::size_of::() as u32, ) }; } unsafe fn draw_indexed_indirect( &mut self, buffer: &super::Buffer, offset: wgt::BufferAddress, draw_count: u32, ) { unsafe { self.device.raw.cmd_draw_indexed_indirect( self.active, buffer.raw, offset, draw_count, mem::size_of::() as u32, ) }; } unsafe fn draw_indirect_count( &mut self, buffer: &super::Buffer, offset: wgt::BufferAddress, count_buffer: &super::Buffer, count_offset: wgt::BufferAddress, max_count: u32, ) { let stride = mem::size_of::() as u32; match self.device.extension_fns.draw_indirect_count { Some(ref t) => { unsafe { t.cmd_draw_indirect_count( self.active, buffer.raw, offset, count_buffer.raw, count_offset, max_count, stride, ) }; } None => panic!("Feature `DRAW_INDIRECT_COUNT` not enabled"), } } unsafe fn draw_indexed_indirect_count( &mut self, buffer: &super::Buffer, offset: wgt::BufferAddress, count_buffer: &super::Buffer, count_offset: wgt::BufferAddress, max_count: u32, ) { let stride = mem::size_of::() as u32; match self.device.extension_fns.draw_indirect_count { Some(ref t) => { unsafe { t.cmd_draw_indexed_indirect_count( self.active, buffer.raw, offset, count_buffer.raw, count_offset, max_count, stride, ) }; } None => panic!("Feature `DRAW_INDIRECT_COUNT` not enabled"), } } // compute unsafe fn begin_compute_pass(&mut self, desc: &crate::ComputePassDescriptor<'_, super::Api>) { self.bind_point = vk::PipelineBindPoint::COMPUTE; if let Some(label) = desc.label { unsafe { self.begin_debug_marker(label) }; self.rpass_debug_marker_active = true; } if let Some(timestamp_writes) = desc.timestamp_writes.as_ref() { if let Some(index) = timestamp_writes.beginning_of_pass_write_index { unsafe { self.write_timestamp(timestamp_writes.query_set, index); } } self.end_of_pass_timer_query = timestamp_writes .end_of_pass_write_index .map(|index| (timestamp_writes.query_set.raw, index)); } } unsafe fn end_compute_pass(&mut self) { self.write_pass_end_timestamp_if_requested(); if self.rpass_debug_marker_active { unsafe { self.end_debug_marker() }; self.rpass_debug_marker_active = false } } unsafe fn set_compute_pipeline(&mut self, pipeline: &super::ComputePipeline) { unsafe { self.device.raw.cmd_bind_pipeline( self.active, vk::PipelineBindPoint::COMPUTE, pipeline.raw, ) }; } unsafe fn dispatch(&mut self, count: [u32; 3]) { unsafe { self.device .raw .cmd_dispatch(self.active, count[0], count[1], count[2]) }; } unsafe fn dispatch_indirect(&mut self, buffer: &super::Buffer, offset: wgt::BufferAddress) { unsafe { self.device .raw .cmd_dispatch_indirect(self.active, buffer.raw, offset) } } } #[test] fn check_dst_image_layout() { assert_eq!( conv::derive_image_layout(crate::TextureUses::COPY_DST, wgt::TextureFormat::Rgba8Unorm), DST_IMAGE_LAYOUT ); }