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README.md
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# Vulkan-Hpp: C++ Bindings for Vulkan
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# Vulkan-Hpp: C++ Bindings for Vulkan
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## CI Build Status
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The goal of the Vulkan-Hpp is to provide header only C++ bindings for the Vulkan C API to improve the developers Vulkan experience without introducing CPU runtime cost. It adds features like type safety for enums and bitfields, STL container support, exceptions and simple enumerations.
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| Platform | Build Status |
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| Platform | Build Status |
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|:--------:|:------------:|
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|:--------:|:------------:|
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| Linux | [![Build Status](https://travis-ci.org/KhronosGroup/Vulkan-Hpp.svg?branch=master)](https://travis-ci.org/KhronosGroup/Vulkan-Hpp) |
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| Linux | [![Build Status](https://travis-ci.org/KhronosGroup/Vulkan-Hpp.svg?branch=master)](https://travis-ci.org/KhronosGroup/Vulkan-Hpp) |
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The goal of the Vulkan-Hpp is to provide header only C++ bindings for the Vulkan C API to improve the developers Vulkan experience without introducing CPU runtime cost. It adds features like type safety for enums and bitfields, STL container support, exceptions and simple enumerations.
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## Getting Started
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# Getting Started
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Vulkan-Hpp is part of the LunarG Vulkan SDK since version 1.0.24. Just `#include <vulkan/vulkan.hpp>` and you're ready to use the C++ bindings. If you're using a Vulkan version not yet supported by the Vulkan SDK you can find the latest version of the header [here](https://github.com/KhronosGroup/Vulkan-Hpp/blob/master/vulkan/vulkan.hpp).
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Vulkan-Hpp is part of the LunarG Vulkan SDK since version 1.0.24. Just include ```<vulkan.hpp>``` and you're ready to use the C++ bindings. If you're using a Vulkan version not yet supported by the Vulkan SDK you can find the latest version of the header [here](https://github.com/KhronosGroup/Vulkan-Hpp/blob/master/vulkan/vulkan.hpp).
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### Minimum Requirements
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# Minimum Requirements
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Vulkan-Hpp requires a C++11 capable compiler to compile. The following compilers are known to work:
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Vulkan-Hpp requires a C++11 capable compiler to compile. The following compilers are known to work:
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* Visual Studio >=2015
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* Visual Studio >=2015
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* GCC >= 4.8.2 (earlier version might work, but are untested)
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* GCC >= 4.8.2 (earlier version might work, but are untested)
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* Clang >= 3.3
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* Clang >= 3.3
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# namespace vk
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## Usage
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### namespace vk
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To avoid name collisions with the Vulkan C API the C++ bindings reside in the vk namespace. The following rules apply to the new naming
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To avoid name collisions with the Vulkan C API the C++ bindings reside in the vk namespace. The following rules apply to the new naming
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* All functions, enums, handles, and structs have the Vk prefix removed. In addition to this the first leter of functions is lower case.
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* All functions, enums, handles, and structs have the Vk prefix removed. In addition to this the first leter of functions is lower case.
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* ```vkCreateImage``` can be accessed as ```vk::createImage```
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* `vkCreateImage` can be accessed as `vk::createImage`
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* ```VkImageTiling``` can be accessed as ```vk::ImageTiling```
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* `VkImageTiling` can be accessed as `vk::ImageTiling`
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* ```VkImageCreateInfo``` can be accessed as ```vk::ImageCreateInfo```
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* `VkImageCreateInfo` can be accessed as `vk::ImageCreateInfo`
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* Enums are mapped to scoped enums to provide compile time type safety. The names have been changed to 'e' + CamelCase with the VK_ prefix and type infix removed. In case the enum type is an extension the extension suffix has been removed from the enum values.
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* Enums are mapped to scoped enums to provide compile time type safety. The names have been changed to 'e' + CamelCase with the VK_ prefix and type infix removed. In case the enum type is an extension the extension suffix has been removed from the enum values.
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In all other cases the extension suffix has not been removed.
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In all other cases the extension suffix has not been removed.
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* ```VK_IMAGETYPE_2D``` is now ```vk::ImageType::e2D```.
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* `VK_IMAGETYPE_2D` is now `vk::ImageType::e2D`.
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* ```VK_COLOR_SPACE_SRGB_NONLINEAR_KHR``` is now ```vk::ColorSpaceKHR::eSrgbNonlinear```.
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* `VK_COLOR_SPACE_SRGB_NONLINEAR_KHR` is now `vk::ColorSpaceKHR::eSrgbNonlinear`.
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* ```VK_STRUCTURE_TYPE_PRESENT_INFO_KHR``` is now ```vk::StructureType::ePresentInfoKHR```.
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* `VK_STRUCTURE_TYPE_PRESENT_INFO_KHR` is now `vk::StructureType::ePresentInfoKHR`.
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* Flag bits are handled like scoped enums with the addition that the _BIT suffix has also been removed.
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* Flag bits are handled like scoped enums with the addition that the `_BIT` suffix has also been removed.
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In some cases it might be necessary to move Vulkan-Hpp to a custom namespace. This can be achieved by defining VULKAN_HPP_NAMESPACE before including Vulkan-Hpp.
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In some cases it might be necessary to move Vulkan-Hpp to a custom namespace. This can be achieved by defining VULKAN_HPP_NAMESPACE before including Vulkan-Hpp.
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# Handles
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### Handles
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Vulkan-Hpp declares a class for all handles to ensure full type safety and to add support for member functions on handles. A member function has been added to a handle class for each
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function which accepts the corresponding handle as first parameter. Instead of ```vkBindBufferMemory(device, ...)``` one can write ```device.bindBufferMemory(...)``` or ```vk::bindBufferMemory(device, ...)```.
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# C/C++ Interop for Handles
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Vulkan-Hpp declares a class for all handles to ensure full type safety and to add support for member functions on handles. A member function has been added to a handle class for each function which accepts the corresponding handle as first parameter. Instead of `vkBindBufferMemory(device, ...)` one can write `device.bindBufferMemory(...)` or `vk::bindBufferMemory(device, ...)`.
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On 64-bit platforms Vulkan-Hpp supports implicit conversions between C++ Vulkan handles and C Vulkan handles. On 32-bit platforms all non-dispatchable handles are defined as ```uint64_t```,
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thus preventing type-conversion checks at compile time which would catch assignments between incompatible handle types..
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### C/C++ Interop for Handles
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Due to that Vulkan-Hpp does not enable implicit conversion for 32-bit platforms by default and it is recommended to use a static_cast for the conversion like this: ```VkDevice = static_cast<VkDevice>(cppDevice)```
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to prevent converting some arbitrary int to a handle or vice versa by accident. If you're developing your code on a 64-bit platform, but want compile your code for a 32-bit platform without adding the explicit casts
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On 64-bit platforms Vulkan-Hpp supports implicit conversions between C++ Vulkan handles and C Vulkan handles. On 32-bit platforms all non-dispatchable handles are defined as `uint64_t`, thus preventing type-conversion checks at compile time which would catch assignments between incompatible handle types.. Due to that Vulkan-Hpp does not enable implicit conversion for 32-bit platforms by default and it is recommended to use a `static_cast` for the conversion like this: `VkDevice = static_cast<VkDevice>(cppDevice)` to prevent converting some arbitrary int to a handle or vice versa by accident. If you're developing your code on a 64-bit platform, but want compile your code for a 32-bit platform without adding the explicit casts you can define `VULKAN_HPP_TYPESAFE_CONVERSION` to 1 in your build system or before including `vulkan.hpp`. On 64-bit platforms this define is set to 1 by default and can be set to 0 to disable implicit conversions.
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you can define ```VULKAN_HPP_TYPESAFE_CONVERSION``` to 1 in your build system or before including ```vulkan.hpp```. On 64-bit platforms this define is set to 1 by default and can be set to 0 to disable implicit conversions.
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### Flags
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# Flags
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The scoped enum feature adds type safety to the flags, but also prevents using the flag bits as input for bitwise operations like & and |.
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The scoped enum feature adds type safety to the flags, but also prevents using the flag bits as input for bitwise operations like & and |.
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As solution Vulkan-Hpp provides a template class ```vk::Flags``` which brings the standard operations like &=, |=, & and | to our scoped enums. Except for the initialization with 0 this class behaves exactly like a normal bitmask
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with the improvement that it is impossible to set bits not specified by the corresponding enum by accident. Here are a few examples for the bitmask handling:
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As solution Vulkan-Hpp provides a template class `vk::Flags` which brings the standard operations like `&=`, `|=`, `&` and `|` to our scoped enums. Except for the initialization with 0 this class behaves exactly like a normal bitmask with the improvement that it is impossible to set bits not specified by the corresponding enum by accident. Here are a few examples for the bitmask handling:
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```c++
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```c++
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vk::ImageUsage iu1; // initialize a bitmask with no bit set
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vk::ImageUsage iu1; // initialize a bitmask with no bit set
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vk::ImageUsage iu2 = {}; // initialize a bitmask with no bit set
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vk::ImageUsage iu2 = {}; // initialize a bitmask with no bit set
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vk::ImageUsage iu3 = vk::ImageUsage::eColorAttachment; // initialize with a single value
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vk::ImageUsage iu3 = vk::ImageUsage::eColorAttachment; // initialize with a single value
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vk::ImageUsage iu4 = vk::ImageUsage::eColorAttachment | vk::ImageUsage::eStorage; // or two bits to get a bitmask
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vk::ImageUsage iu4 = vk::ImageUsage::eColorAttachment | vk::ImageUsage::eStorage; // or two bits to get a bitmask
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PipelineShaderStageCreateInfo ci( {} /* pass a flag without any bits set, ...);
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PipelineShaderStageCreateInfo ci( {} /* pass a flag without any bits set */, ...);
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```
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```
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# CreateInfo structs
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### CreateInfo structs
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When constructing a handle in Vulkan one usually has to create some ```CreateInfo``` struct which describes the new handle. This can result in quite lengthy code as can be seen in the following Vulkan C example:
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When constructing a handle in Vulkan one usually has to create some `CreateInfo` struct which describes the new handle. This can result in quite lengthy code as can be seen in the following Vulkan C example:
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```c++
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```c++
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VkImageCreateInfo ci;
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VkImageCreateInfo ci;
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@ -80,12 +85,11 @@ When constructing a handle in Vulkan one usually has to create some ```CreateInf
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There are two typical issues Vulkan developers encounter when filling out a CreateInfo struct field by field
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There are two typical issues Vulkan developers encounter when filling out a CreateInfo struct field by field
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* One or more fields are left uninitialized.
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* One or more fields are left uninitialized.
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* sType is incorrect.
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* `sType` is incorrect.
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Especially the first one is hard to detect.
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Especially the first one is hard to detect.
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Vulkan-Hpp provides constructors for all CreateInfo objects which accept one parameter for each member variable. This way the compiler throws a compiler error if a value has been forgotten. In addition to this sType is automatically
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Vulkan-Hpp provides constructors for all CreateInfo objects which accept one parameter for each member variable. This way the compiler throws a compiler error if a value has been forgotten. In addition to this `sType` is automatically filled with the correct value and `pNext` set to a `nullptr` by default. Here's how the same code looks with a constructor:
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filled with the correct value and pNext set to a nullptr by default. Here's how the same code looks with a constructor:
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```c++
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```c++
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vk::ImageCreateInfo ci({}, vk::ImageType::e2D, vk::format::eR8G8B8A8Unorm,
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vk::ImageCreateInfo ci({}, vk::ImageType::e2D, vk::format::eR8G8B8A8Unorm,
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@ -96,6 +100,7 @@ Vulkan-Hpp provides constructors for all CreateInfo objects which accept one par
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```
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```
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With constructors for CreateInfo structures one can also pass temporaries to Vulkan functions like this:
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With constructors for CreateInfo structures one can also pass temporaries to Vulkan functions like this:
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```c++
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```c++
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vk::Image image = device.createImage({{}, vk::ImageType::e2D, vk::format::eR8G8B8A8Unorm,
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vk::Image image = device.createImage({{}, vk::ImageType::e2D, vk::format::eR8G8B8A8Unorm,
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{ width, height, 1 },
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{ width, height, 1 },
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vk::SharingMode::eExclusive, 0, 0, vk::Imagelayout::eUndefined});
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vk::SharingMode::eExclusive, 0, 0, vk::Imagelayout::eUndefined});
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```
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```
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# Passing Arrays to Functions: The ArrayProxy
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### Passing Arrays to Functions using ArrayProxy
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The Vulkan API has several places where which require (count,pointer) as two function arguments and C++ has a few containers which map perfectly to this pair. To simplify development the Vulkan-Hpp bindings have replaced those argument pairs
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with the ArrayProxy template class which accepts empty arrays and a single value as well as STL containers std::initializer_list, std::array and std::vector as argument for construction. This way a single generated Vulkan version can accept
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The Vulkan API has several places where which require (count,pointer) as two function arguments and C++ has a few containers which map perfectly to this pair. To simplify development the Vulkan-Hpp bindings have replaced those argument pairs with the `ArrayProxy` template class which accepts empty arrays and a single value as well as STL containers `std::initializer_list`, `std::array` and `std::vector` as argument for construction. This way a single generated Vulkan version can accept a variety of inputs without having the combinatoric explosion which would occur when creating a function for each container type.
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a variety of inputs without having the combinatoric explosion which would occur when creating a function for each container type.
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Here are some code samples on how to use the ArrayProxy:
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Here are some code samples on how to use the ArrayProxy:
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c.setScissor(0, vec);
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c.setScissor(0, vec);
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```
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```
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# Passing Structs to Functions
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### Passing Structs to Functions
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Vulkan-Hpp generates references for pointers to structs. This conversion allows passing temporary structs to functions which can result in shorter code. In case the input is optional and thus accepting a null pointer the parameter type will be
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a ```vk::Optional<T> const&``` type. This type accepts either a reference to ```T``` or nullptr as input and thus allows optional temporary structs.
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Vulkan-Hpp generates references for pointers to structs. This conversion allows passing temporary structs to functions which can result in shorter code. In case the input is optional and thus accepting a null pointer the parameter type will be a `vk::Optional<T> const&` type. This type accepts either a reference to `T` or nullptr as input and thus allows optional temporary structs.
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```c++
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```c++
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// C
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// C
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auto layout = device.getImageSubResourceLayout(image, { {} /* flags*/, 0 /* miplevel */, 0 /* layout */ });
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auto layout = device.getImageSubResourceLayout(image, { {} /* flags*/, 0 /* miplevel */, 0 /* layout */ });
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```
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```
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# Structure Pointer Chains
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### Structure Pointer Chains
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Vulkan allows chaining of structures through the pNext pointer. Vulkan-Hpp has a variadic template class which allows constructing of such structure chains with minimal efforts.
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In addition to this it checks at compile time if the spec allows the construction of such a pNext chain.
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Vulkan allows chaining of structures through the pNext pointer. Vulkan-Hpp has a variadic template class which allows constructing of such structure chains with minimal efforts. In addition to this it checks at compile time if the spec allows the construction of such a `pNext` chain.
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```
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```
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// This will compile successfully.
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// This will compile successfully.
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@ -187,20 +191,19 @@ vk::MemoryRequirements2KHR &memReqs = result.get<vk::MemoryRequirements2KHR>();
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vk::MemoryDedicatedRequirementsKHR &dedMemReqs = result.get<vk::MemoryDedicatedRequirementsKHR>();
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vk::MemoryDedicatedRequirementsKHR &dedMemReqs = result.get<vk::MemoryDedicatedRequirementsKHR>();
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```
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```
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### Return values, Error Codes & Exceptions
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By default Vulkan-Hpp has exceptions enabled. This means that Vulkan-Hpp checks the return code of each function call which returns a Vk::Result. If Vk::Result is a failure a std::runtime_error will be thrown. Since there is no need to return the error code anymore the C++ bindings can now return the actual desired return value, i.e. a vulkan handle. In those cases ResultValue <SomeType>::type is defined as the returned type.
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# Return values, Error Codes & Exceptions
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By default Vulkan-Hpp has exceptions enabled. This means that Vulkan-Hpp checks the return code of each function call which returns a Vk::Result. If Vk::Result is a failure a std::runtime_error will be thrown.
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Since there is no need to return the error code anymore the C++ bindings can now return the actual desired return value, i.e. a vulkan handle. In those cases ResultValue <SomeType>::type is defined as the returned type.
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To create a device you can now just write:
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To create a device you can now just write:
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```C++
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```C++
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vk::Device device = physicalDevice.createDevice(createInfo);
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vk::Device device = physicalDevice.createDevice(createInfo);
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```
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```
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If exception handling is disabled by defining ```VULKAN_HPP_NO_EXCEPTIONS``` the type of ```ResultValue<SomeType>::type``` is a struct holding a ```vk::Result``` and a ```SomeType```.
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If exception handling is disabled by defining `VULKAN_HPP_NO_EXCEPTIONS` the type of `ResultValue<SomeType>::type` is a struct holding a `vk::Result` and a `SomeType`. This struct supports unpacking the return values by using `std::tie`.
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This struct supports unpacking the return values by using ```std::tie```.
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In case you don’t want to use the ```vk::ArrayProxy``` and return value transformation you can still call the plain C-style function. Below are three examples showing the 3 ways to use the API:
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In case you don’t want to use the `vk::ArrayProxy` and return value transformation you can still call the plain C-style function. Below are three examples showing the 3 ways to use the API:
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The first snippet shows how to use the API without exceptions and the return value transformation:
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The first snippet shows how to use the API without exceptions and the return value transformation:
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@ -267,9 +270,11 @@ Finally, the last code example is using exceptions and return value transformati
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// handle error and free resources
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// handle error and free resources
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}
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}
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```
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```
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Keep in mind that Vulkan-Hpp does not support RAII style handles and that you have to cleanup your resources in the error handler!
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Keep in mind that Vulkan-Hpp does not support RAII style handles and that you have to cleanup your resources in the error handler!
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# Enumerations
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### Enumerations
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For the return value transformation, there's one special class of return values which require special handling: Enumerations. For enumerations you usually have to write code like this:
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For the return value transformation, there's one special class of return values which require special handling: Enumerations. For enumerations you usually have to write code like this:
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```c++
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```c++
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@ -291,24 +296,48 @@ do
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// it's possible that the count has changed, start again if properties was not big enough
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// it's possible that the count has changed, start again if properties was not big enough
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properties.resize(propertyCount);
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properties.resize(propertyCount);
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```
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```
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Since writing this loop over and over again is tedious and error prone the C++ binding takes care of the enumeration so that you can just write:
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Since writing this loop over and over again is tedious and error prone the C++ binding takes care of the enumeration so that you can just write:
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```
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```c++
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std::vector<LayerProperties> properties = physicalDevice.enumerateDeviceLayerProperties();
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std::vector<LayerProperties> properties = physicalDevice.enumerateDeviceLayerProperties();
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```
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```
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# UniqueHandle
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### UniqueHandle for automatic resource management
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Vulkan-Hpp provides a ```vk::UniqueHandle<Type, Deleter>``` interface. For each Vulkan handle type ```vk::Type``` there is a unqiue handle ```vk::UniqueType``` which will delete the underlying Vulkan resource upon destruction, e.g.
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```vk::UniqueBuffer ``` is the unique handle for ```vk::Buffer```.
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For each function which constructs a Vulkan handle of type ```vk::Type``` Vulkan-Hpp provides a second version which returns a ```vk::UnqiueType```. E.g. for ```vk::Device::createBuffer``` there is ```vk::Device::createBufferUnique``` and for ```vk::allocateCommandBuffers```
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Vulkan-Hpp provides a `vk::UniqueHandle<Type, Deleter>` interface. For each Vulkan handle type `vk::Type` there is a unqiue handle `vk::UniqueType` which will delete the underlying Vulkan resource upon destruction, e.g. `vk::UniqueBuffer ` is the unique handle for `vk::Buffer`.
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there is ```vk::allocateCommandBuffersUnique```.
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Note that using ```vk::UniqueHandle``` comes at a cost since most deleters have to store the ```vk::AllocationCallbacks``` and parent handle used for construction because they are required for automatic destruction.
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For each function which constructs a Vulkan handle of type `vk::Type` Vulkan-Hpp provides a second version which returns a `vk::UnqiueType`. E.g. for `vk::Device::createBuffer` there is `vk::Device::createBufferUnique` and for `vk::allocateCommandBuffers` there is `vk::allocateCommandBuffersUnique`.
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# Custom allocators
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Note that using `vk::UniqueHandle` comes at a cost since most deleters have to store the `vk::AllocationCallbacks` and parent handle used for construction because they are required for automatic destruction.
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Sometimes it is required to use ```std::vector``` with custom allocators. Vulkan-Hpp supports vectors with custom allocators as input for ```vk::ArrayProx``` and for functions which do return a vector. For the latter case, add your favorite custom allocator as template argument to the function call like this:
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### Custom allocators
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Sometimes it is required to use `std::vector` with custom allocators. Vulkan-Hpp supports vectors with custom allocators as input for `vk::ArrayProxy` and for functions which do return a vector. For the latter case, add your favorite custom allocator as template argument to the function call like this:
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||||||
|
|
||||||
```c++
|
```c++
|
||||||
std::vector<LayerProperties, MyCustomAllocator> properties = physicalDevice.enumerateDeviceLayerProperties<MyCustomAllocator>();
|
std::vector<LayerProperties, MyCustomAllocator> properties = physicalDevice.enumerateDeviceLayerProperties<MyCustomAllocator>();
|
||||||
```
|
```
|
||||||
|
|
||||||
|
## See Also
|
||||||
|
|
||||||
|
Feel free to submit a PR to add to this list.
|
||||||
|
|
||||||
|
- [Vookoo](https://github.com/andy-thomason/Vookoo/) Stateful helper classes for Vulkan-Hpp, [Introduction Article](https://accu.org/index.php/journals/2380).
|
||||||
|
|
||||||
|
## License
|
||||||
|
|
||||||
|
Copyright 2015-2017 The Khronos Group Inc.
|
||||||
|
|
||||||
|
Licensed under the Apache License, Version 2.0 (the "License");
|
||||||
|
you may not use this file except in compliance with the License.
|
||||||
|
You may obtain a copy of the License at
|
||||||
|
|
||||||
|
http://www.apache.org/licenses/LICENSE-2.0
|
||||||
|
|
||||||
|
Unless required by applicable law or agreed to in writing, software
|
||||||
|
distributed under the License is distributed on an "AS IS" BASIS,
|
||||||
|
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
|
||||||
|
See the License for the specific language governing permissions and
|
||||||
|
limitations under the License.
|
||||||
|
|
||||||
|
Loading…
Reference in New Issue
Block a user