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// Copyright (c) 2016 The vulkano developers // Licensed under the Apache License, Version 2.0 // <LICENSE-APACHE or // http://www.apache.org/licenses/LICENSE-2.0> or the MIT // license <LICENSE-MIT or http://opensource.org/licenses/MIT>, // at your option. All files in the project carrying such // notice may not be copied, modified, or distributed except // according to those terms. //! Cache the pipeline objects to disk for faster reloads. //! //! A pipeline cache is an opaque type that allow you to cache your graphics and compute //! pipelines on the disk. //! //! You can create either an empty cache or a cache from some initial data. Whenever you create a //! graphics or compute pipeline, you have the possibility to pass a reference to that cache. //! TODO: ^ that's not the case yet //! The Vulkan implementation will then look in the cache for an existing entry, or add one if it //! doesn't exist. //! //! Once that is done, you can extract the data from the cache and store it. See the documentation //! of [`get_data`](struct.PipelineCache.html#method.get_data) for example of how to store the data //! on the disk, and [`with_data`](struct.PipelineCache.html#method.with_data) for how to reload it. //! use std::mem::MaybeUninit; use std::ptr; use std::sync::Arc; use device::Device; use OomError; use VulkanObject; use check_errors; use vk; /// Opaque cache that contains pipeline objects. /// /// See [the documentation of the module](index.html) for more info. pub struct PipelineCache { device: Arc<Device>, cache: vk::PipelineCache, } impl PipelineCache { /// Builds a new pipeline cache from existing data. The data must have been previously obtained /// with [`get_data`](#method.get_data). /// /// The data passed to this function will most likely be blindly trusted by the Vulkan /// implementation. Therefore you can easily crash your application or the system by passing /// wrong data. Hence why this function is unsafe. /// /// # Example /// /// This example loads a cache from a file, if it exists. /// See [`get_data`](#method.get_data) for how to store the data in a file. /// TODO: there's a header in the cached data that must be checked ; talk about this /// /// ``` /// # use std::sync::Arc; /// # use vulkano::device::Device; /// use std::fs::File; /// use std::io::Read; /// use vulkano::pipeline::cache::PipelineCache; /// # let device: Arc<Device> = return; /// /// let data = { /// let file = File::open("pipeline_cache.bin"); /// if let Ok(mut file) = file { /// let mut data = Vec::new(); /// if let Ok(_) = file.read_to_end(&mut data) { /// Some(data) /// } else { None } /// } else { None } /// }; /// /// let cache = if let Some(data) = data { /// // This is unsafe because there is no way to be sure that the file contains valid data. /// unsafe { PipelineCache::with_data(device.clone(), &data).unwrap() } /// } else { /// PipelineCache::empty(device.clone()).unwrap() /// }; /// ``` #[inline] pub unsafe fn with_data(device: Arc<Device>, initial_data: &[u8]) -> Result<Arc<PipelineCache>, OomError> { PipelineCache::new_impl(device, Some(initial_data)) } /// Builds a new empty pipeline cache. /// /// # Example /// /// ``` /// # use std::sync::Arc; /// # use vulkano::device::Device; /// use vulkano::pipeline::cache::PipelineCache; /// # let device: Arc<Device> = return; /// let cache = PipelineCache::empty(device.clone()).unwrap(); /// ``` #[inline] pub fn empty(device: Arc<Device>) -> Result<Arc<PipelineCache>, OomError> { unsafe { PipelineCache::new_impl(device, None) } } // Actual implementation of the constructor. unsafe fn new_impl(device: Arc<Device>, initial_data: Option<&[u8]>) -> Result<Arc<PipelineCache>, OomError> { let vk = device.pointers(); let cache = { let infos = vk::PipelineCacheCreateInfo { sType: vk::STRUCTURE_TYPE_PIPELINE_CACHE_CREATE_INFO, pNext: ptr::null(), flags: 0, // reserved initialDataSize: initial_data.map(|d| d.len()).unwrap_or(0), pInitialData: initial_data .map(|d| d.as_ptr() as *const _) .unwrap_or(ptr::null()), }; let mut output = MaybeUninit::uninit(); check_errors(vk.CreatePipelineCache(device.internal_object(), &infos, ptr::null(), output.as_mut_ptr()))?; output.assume_init() }; Ok(Arc::new(PipelineCache { device: device.clone(), cache: cache, })) } /// Merges other pipeline caches into this one. /// /// It is `self` that is modified here. The pipeline caches passed as parameter are untouched. /// /// # Panic /// /// - Panics if `self` is included in the list of other pipelines. /// // FIXME: vkMergePipelineCaches is not thread safe for the destination cache // TODO: write example pub fn merge<'a, I>(&self, pipelines: I) -> Result<(), OomError> where I: IntoIterator<Item = &'a &'a Arc<PipelineCache>> { unsafe { let vk = self.device.pointers(); let pipelines = pipelines .into_iter() .map(|pipeline| { assert!(&***pipeline as *const _ != &*self as *const _); pipeline.cache }) .collect::<Vec<_>>(); check_errors(vk.MergePipelineCaches(self.device.internal_object(), self.cache, pipelines.len() as u32, pipelines.as_ptr()))?; Ok(()) } } /// Obtains the data from the cache. /// /// This data can be stored and then reloaded and passed to `PipelineCache::with_data`. /// /// # Example /// /// This example stores the data of a pipeline cache on the disk. /// See [`with_data`](#method.with_data) for how to reload it. /// /// ``` /// use std::fs; /// use std::fs::File; /// use std::io::Write; /// # use std::sync::Arc; /// # use vulkano::pipeline::cache::PipelineCache; /// /// # let cache: Arc<PipelineCache> = return; /// // If an error happens (eg. no permission for the file) we simply skip storing the cache. /// if let Ok(data) = cache.get_data() { /// if let Ok(mut file) = File::create("pipeline_cache.bin.tmp") { /// if let Ok(_) = file.write_all(&data) { /// let _ = fs::rename("pipeline_cache.bin.tmp", "pipeline_cache.bin"); /// } else { /// let _ = fs::remove_file("pipeline_cache.bin.tmp"); /// } /// } /// } /// ``` pub fn get_data(&self) -> Result<Vec<u8>, OomError> { unsafe { let vk = self.device.pointers(); let mut num = 0; check_errors(vk.GetPipelineCacheData(self.device.internal_object(), self.cache, &mut num, ptr::null_mut()))?; let mut data: Vec<u8> = Vec::with_capacity(num as usize); check_errors(vk.GetPipelineCacheData(self.device.internal_object(), self.cache, &mut num, data.as_mut_ptr() as *mut _))?; data.set_len(num as usize); Ok(data) } } } unsafe impl VulkanObject for PipelineCache { type Object = vk::PipelineCache; const TYPE: vk::ObjectType = vk::OBJECT_TYPE_PIPELINE_CACHE; #[inline] fn internal_object(&self) -> vk::PipelineCache { self.cache } } impl Drop for PipelineCache { #[inline] fn drop(&mut self) { unsafe { let vk = self.device.pointers(); vk.DestroyPipelineCache(self.device.internal_object(), self.cache, ptr::null()); } } } #[cfg(test)] mod tests { use pipeline::cache::PipelineCache; #[test] fn merge_self_forbidden() { let (device, queue) = gfx_dev_and_queue!(); let pipeline = PipelineCache::empty(device).unwrap(); assert_should_panic!({ pipeline.merge(&[&pipeline]).unwrap(); }); } }