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@ -337,67 +337,23 @@ impl<'a> VkProcessor<'a> {
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println!("Allocating Buffers...");
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println!("Allocating Buffers...");
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// Pull out the image data and place it in a buffer for the kernel to write to and for us to read from
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let write_buffer = {
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let mut buff = self.image_buffer.iter();
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let data_iter = (0..data_length).map(|n| *(buff.next().unwrap()));
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CpuAccessibleBuffer::from_iter(self.device.clone(), BufferUsage::all(), data_iter).unwrap()
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};
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// Pull out the image data and place it in a buffer for the kernel to read from
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let read_buffer = {
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let mut buff = self.image_buffer.iter();
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let data_iter = (0..data_length).map(|n| *(buff.next().unwrap()));
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CpuAccessibleBuffer::from_iter(self.device.clone(), BufferUsage::all(), data_iter).unwrap()
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};
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// A buffer to hold many i32 values to use as settings
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let settings_buffer = {
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let vec = vec![self.xy.0, self.xy.1];
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let mut buff = vec.iter();
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let data_iter =
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(0..2).map(|n| *(buff.next().unwrap()));
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CpuAccessibleBuffer::from_iter(self.device.clone(),
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BufferUsage::all(),
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data_iter).unwrap()
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};
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println!("Done");
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// Create the data descriptor set for our previously created shader pipeline
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let mut set =
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PersistentDescriptorSet::start(self.compute_pipeline.clone().unwrap().clone(), 0)
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.add_buffer(write_buffer.clone()).unwrap()
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.add_buffer(read_buffer.clone()).unwrap()
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.add_buffer(settings_buffer.clone()).unwrap();
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self.compute_set = Some(Arc::new(set.build().unwrap()));
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self.compute_image_buffers.push(write_buffer);
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self.compute_image_buffers.push(read_buffer);
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self.settings_buffer = Some(settings_buffer);
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let vertex_buffer = {
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let vertex_buffer = {
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vulkano::impl_vertex!(tVertex, position);
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vulkano::impl_vertex!(tVertex, position);
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CpuAccessibleBuffer::from_iter(self.device.clone(), BufferUsage::all(), [
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CpuAccessibleBuffer::from_iter(self.device.clone(), BufferUsage::all(), [
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tVertex { position: [-1.0, -1.0 ] },
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tVertex { position: [-1.0, 1.0 ] },
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tVertex { position: [ 1.0, 1.0 ] },
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tVertex { position: [ 1.0, 1.0 ] },
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tVertex { position: [ 1.0, -1.0 ] },
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tVertex { position: [ 1.0, 0.5 ] },
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tVertex { position: [ 0.5, 0.5 ] },
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tVertex { position: [ 0.5, 1.0 ] },
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].iter().cloned()).unwrap()
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].iter().cloned()).unwrap()
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};
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};
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let vertex_buffer2 = {
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let vertex_buffer2 = {
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CpuAccessibleBuffer::from_iter(self.device.clone(), BufferUsage::all(), [
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CpuAccessibleBuffer::from_iter(self.device.clone(), BufferUsage::all(), [
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tVertex { position: [-1.0, -1.0 ] },
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tVertex { position: [-1.0, -1.0 ] },
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tVertex { position: [-1.0, -0.5 ] },
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tVertex { position: [-1.0, -0.5 ] },
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tVertex { position: [-0.5, 0.5 ] },
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tVertex { position: [-0.5, -0.5 ] },
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tVertex { position: [-0.5, -1.0 ] },
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tVertex { position: [-0.5, -1.0 ] },
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].iter().cloned()).unwrap()
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].iter().cloned()).unwrap()
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};
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};
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@ -405,32 +361,15 @@ impl<'a> VkProcessor<'a> {
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self.vertex_buffer = Some(vertex_buffer);
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self.vertex_buffer = Some(vertex_buffer);
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self.vertex_buffer2 = Some(vertex_buffer2);
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self.vertex_buffer2 = Some(vertex_buffer2);
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let compute_transfer_image = {
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let mut usage = ImageUsage::none();
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usage.transfer_destination = true;
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usage.storage = true;
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AttachmentImage::with_usage(
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self.device.clone(),
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[self.xy.0, self.xy.1],
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Format::R8G8B8A8Uint,
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usage)
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};
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self.graphics_image_swap_buffer = Some(compute_transfer_image.clone().unwrap());
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let texture = VkProcessor::get_texture_from_file(image_filename.clone(), self.queue.clone());
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let texture = VkProcessor::get_texture_from_file(image_filename.clone(), self.queue.clone());
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self.textures.push(texture);
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self.textures.push(texture);
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let texture1 = VkProcessor::get_texture_from_file(String::from("button.png"), self.queue.clone());
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self.textures.push(texture1);
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}
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}
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// The image set is the containing object for all texture and image hooks.
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// The image set is the containing object for all texture and image hooks.
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// todo, make this pull from the image_buffer_store
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fn get_image_set(&mut self) -> Box<DescriptorSet + Send + Sync> {
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fn get_image_set(&mut self) -> Box<DescriptorSet + Send + Sync> {
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let sampler = Sampler::new(self.device.clone(), Filter::Linear, Filter::Linear,
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let sampler = Sampler::new(self.device.clone(), Filter::Linear, Filter::Linear,
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@ -447,6 +386,27 @@ impl<'a> VkProcessor<'a> {
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o
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o
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}
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}
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// The image set is the containing object for all texture and image hooks.
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fn get_gui_image_set(&mut self) -> Box<DescriptorSet + Send + Sync> {
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let sampler = Sampler::new(self.device.clone(), Filter::Linear, Filter::Linear,
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MipmapMode::Nearest, SamplerAddressMode::Repeat, SamplerAddressMode::Repeat,
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SamplerAddressMode::Repeat, 0.0, 1.0, 0.0, 0.0).unwrap();
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let o : Box<DescriptorSet + Send + Sync> = Box::new(
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PersistentDescriptorSet::start(
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self.shader_kernels.clone().unwrap().graphics_pipeline.clone().unwrap().clone(), 0
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)
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.add_sampled_image(self.textures.get(1).unwrap().clone(), sampler.clone()).unwrap()
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.add_image(self.compute_image.clone().unwrap().clone().get_swap_buffer().clone()).unwrap()
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.build().unwrap());
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o
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}
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pub fn save_edges_image(&mut self){
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self.compute_image.clone().unwrap().clone().save_image();
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}
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pub fn run(&mut self, surface: &'a Arc<Surface<Window>>, mut frame_future: Box<dyn GpuFuture>) -> Box<dyn GpuFuture> {
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pub fn run(&mut self, surface: &'a Arc<Surface<Window>>, mut frame_future: Box<dyn GpuFuture>) -> Box<dyn GpuFuture> {
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let mut framebuffers = window_size_dependent_setup(&self.shader_kernels.clone().unwrap().swapchain_images.clone(),
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let mut framebuffers = window_size_dependent_setup(&self.shader_kernels.clone().unwrap().swapchain_images.clone(),
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@ -468,7 +428,6 @@ impl<'a> VkProcessor<'a> {
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recreate_swapchain = false;
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recreate_swapchain = false;
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}
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}
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// This function can block if no image is available. The parameter is an optional timeout
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// This function can block if no image is available. The parameter is an optional timeout
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// after which the function call will return an error.
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// after which the function call will return an error.
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let (image_num, acquire_future) = match vulkano::swapchain::acquire_next_image(self.shader_kernels.clone().unwrap().swapchain.clone(), None) {
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let (image_num, acquire_future) = match vulkano::swapchain::acquire_next_image(self.shader_kernels.clone().unwrap().swapchain.clone(), None) {
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@ -484,24 +443,12 @@ impl<'a> VkProcessor<'a> {
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// Specify the color to clear the framebuffer with i.e. blue
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// Specify the color to clear the framebuffer with i.e. blue
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let clear_values = vec!([0.0, 0.0, 1.0, 1.0].into());
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let clear_values = vec!([0.0, 0.0, 1.0, 1.0].into());
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{
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// In order to draw, we have to build a *command buffer*. The command buffer object holds
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// the list of commands that are going to be executed.
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//
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// Building a command buffer is an expensive operation (usually a few hundred
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// microseconds), but it is known to be a hot path in the driver and is expected to be
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// optimized.
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//
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// Note that we have to pass a queue family when we create the command buffer. The command
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// buffer will only be executable on that given queue family.
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let mut v = Vec::new();
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let mut v = Vec::new();
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v.push(self.vertex_buffer.clone().unwrap().clone());
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v.push(self.vertex_buffer.clone().unwrap().clone());
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let mut v2 = Vec::new();
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let mut v2 = Vec::new();
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v2.push(self.vertex_buffer2.clone().unwrap().clone());
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v2.push(self.vertex_buffer2.clone().unwrap().clone());
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let command_buffer =
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let command_buffer =
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AutoCommandBufferBuilder::primary_one_time_submit(self.device.clone(), self.queue.family())
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AutoCommandBufferBuilder::primary_one_time_submit(self.device.clone(), self.queue.family())
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.unwrap()
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.unwrap()
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@ -522,10 +469,10 @@ impl<'a> VkProcessor<'a> {
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vec![self.get_image_set()], ())
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vec![self.get_image_set()], ())
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.unwrap()
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.unwrap()
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// .draw(self.shader_kernels.clone().unwrap().graphics_pipeline.clone().unwrap().clone(),
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.draw(self.shader_kernels.clone().unwrap().graphics_pipeline.clone().unwrap().clone(),
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// &self.dynamic_state.clone(), v2,
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&self.dynamic_state.clone(), v2,
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// vec![self.get_image_set()], ())
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vec![self.get_gui_image_set()], ())
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// .unwrap()
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.unwrap()
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.end_render_pass()
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.end_render_pass()
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.unwrap()
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.unwrap()
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@ -554,52 +501,6 @@ impl<'a> VkProcessor<'a> {
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}
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}
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}
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}
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// pub fn read_image(&self) -> Vec<u8> {
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//
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// // The buffer is sync'd so we can just read straight from the handle
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// let mut data_buffer_content = self.img_buffers.get(0).unwrap().read().unwrap();
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//
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// println!("Reading output");
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//
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// let mut image_buffer = Vec::new();
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//
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// for y in 0..self.xy.1 {
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// for x in 0..self.xy.0 {
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//
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// let r = data_buffer_content[((self.xy.0 * y + x) * 4 + 0) as usize] as u8;
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// let g = data_buffer_content[((self.xy.0 * y + x) * 4 + 1) as usize] as u8;
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// let b = data_buffer_content[((self.xy.0 * y + x) * 4 + 2) as usize] as u8;
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// let a = data_buffer_content[((self.xy.0 * y + x) * 4 + 3) as usize] as u8;
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//
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// image_buffer.push(r);
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// image_buffer.push(g);
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// image_buffer.push(b);
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// image_buffer.push(a);
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// }
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// }
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//
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// image_buffer
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// }
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// pub fn save_image(&self) {
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// println!("Saving output");
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//
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// let img_data = self.read_image();
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//
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// let img = ImageBuffer::from_fn(self.xy.0, self.xy.1, |x, y| {
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//
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// let r = img_data[((self.xy.0 * y + x) * 4 + 0) as usize] as u8;
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// let g = img_data[((self.xy.0 * y + x) * 4 + 1) as usize] as u8;
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// let b = img_data[((self.xy.0 * y + x) * 4 + 2) as usize] as u8;
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// let a = img_data[((self.xy.0 * y + x) * 4 + 3) as usize] as u8;
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//
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// image::Rgba([r, g, b, a])
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// });
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//
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// img.save(format!("output/{}.png", SystemTime::now().duration_since(SystemTime::UNIX_EPOCH).unwrap().as_secs()));
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// }
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}
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