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mirror of https://github.com/Yours3lf/rpi-vk-driver.git synced 2024-12-01 13:24:20 +01:00

added all basic stuff, now on to getting something onto the screen

This commit is contained in:
Unknown 2018-05-09 21:02:32 +01:00
parent 1e73f44f50
commit ba5fb7e761
3 changed files with 488 additions and 119 deletions

View File

@ -69,6 +69,11 @@ typedef struct VkQueue_T
int familyIndex;
} _queue;
typedef struct VkCommandBuffer_T
{
int dummy;
} _commandBuffer;
VkQueueFamilyProperties _queueFamilyProperties[] =
{
{
@ -349,101 +354,297 @@ VKAPI_ATTR VkResult VKAPI_CALL vkCreateSemaphore(
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkGetPhysicalDeviceSurfaceCapabilitiesKHR
* The capabilities of a swapchain targetting a surface are the intersection of the capabilities of the WSI platform,
* the native window or display, and the physical device. The resulting capabilities can be obtained with the queries listed
* below in this section. Capabilities that correspond to image creation parameters are not independent of each other:
* combinations of parameters that are not supported as reported by vkGetPhysicalDeviceImageFormatProperties are not supported
* by the surface on that physical device, even if the capabilities taken individually are supported as part of some other parameter combinations.
*
* capabilities the specified device supports for a swapchain created for the surface
*/
VKAPI_ATTR VkResult VKAPI_CALL vkGetPhysicalDeviceSurfaceCapabilitiesKHR(
VkPhysicalDevice physicalDevice,
VkSurfaceKHR surface,
VkSurfaceCapabilitiesKHR* pSurfaceCapabilities)
{
assert(physicalDevice);
assert(surface);
assert(pSurfaceCapabilities);
pSurfaceCapabilities->minImageCount = 1; //min 1
pSurfaceCapabilities->maxImageCount = 2; //TODO max 2 for double buffering for now...
pSurfaceCapabilities->currentExtent.width = ((modeset_dev*)surface)->bufs[0].width;
pSurfaceCapabilities->currentExtent.height = ((modeset_dev*)surface)->bufs[0].height;
pSurfaceCapabilities->minImageExtent.width = ((modeset_dev*)surface)->bufs[0].width; //TODO
pSurfaceCapabilities->minImageExtent.height = ((modeset_dev*)surface)->bufs[0].height; //TODO
pSurfaceCapabilities->maxImageExtent.width = ((modeset_dev*)surface)->bufs[0].width; //TODO
pSurfaceCapabilities->maxImageExtent.height = ((modeset_dev*)surface)->bufs[0].height; //TODO
pSurfaceCapabilities->maxImageArrayLayers = 1; //TODO maybe more layers for cursor etc.
pSurfaceCapabilities->supportedTransforms = VK_SURFACE_TRANSFORM_IDENTITY_BIT_KHR; //TODO no rotation for now
pSurfaceCapabilities->currentTransform = VK_SURFACE_TRANSFORM_IDENTITY_BIT_KHR; //TODO get this from dev
pSurfaceCapabilities->supportedCompositeAlpha = VK_COMPOSITE_ALPHA_OPAQUE_BIT_KHR; //TODO no alpha compositing for now
pSurfaceCapabilities->supportedUsageFlags = VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT; //well we want to draw on the screen right
return VK_SUCCESS;
}
VKAPI_ATTR VkResult VKAPI_CALL vkDeviceWaitIdle(
VkDevice device)
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkGetPhysicalDeviceSurfaceFormatsKHR
* If pSurfaceFormats is NULL, then the number of format pairs supported for the given surface is returned in pSurfaceFormatCount.
* The number of format pairs supported will be greater than or equal to 1. Otherwise, pSurfaceFormatCount must point to a variable
* set by the user to the number of elements in the pSurfaceFormats array, and on return the variable is overwritten with the number
* of structures actually written to pSurfaceFormats. If the value of pSurfaceFormatCount is less than the number of format pairs supported,
* at most pSurfaceFormatCount structures will be written. If pSurfaceFormatCount is smaller than the number of format pairs supported for the given surface,
* VK_INCOMPLETE will be returned instead of VK_SUCCESS to indicate that not all the available values were returned.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkGetPhysicalDeviceSurfaceFormatsKHR(
VkPhysicalDevice physicalDevice,
VkSurfaceKHR surface,
uint32_t* pSurfaceFormatCount,
VkSurfaceFormatKHR* pSurfaceFormats)
{
assert(physicalDevice);
assert(surface);
assert(pSurfaceFormatCount);
const int numFormats = 1;
if(!pSurfaceFormats)
{
*pSurfaceFormatCount = numFormats;
return VK_SUCCESS;
}
VKAPI_ATTR void VKAPI_CALL vkFreeCommandBuffers(
VkDevice device,
VkCommandPool commandPool,
uint32_t commandBufferCount,
const VkCommandBuffer* pCommandBuffers)
{
int arraySize = *pSurfaceFormatCount;
int elementsWritten = min(numFormats, arraySize);
for(int c = 0; c < elementsWritten; ++c)
{
//TODO
pSurfaceFormats[c].colorSpace = VK_COLOR_SPACE_SRGB_NONLINEAR_KHR;
pSurfaceFormats[c].format = VK_FORMAT_R8G8B8A8_UNORM;
}
VKAPI_ATTR void VKAPI_CALL vkDestroyCommandPool(
VkDevice device,
VkCommandPool commandPool,
const VkAllocationCallbacks* pAllocator)
{
*pSurfaceFormatCount = elementsWritten;
if(elementsWritten < numFormats)
{
return VK_INCOMPLETE;
}
VKAPI_ATTR void VKAPI_CALL vkDestroySemaphore(
VkDevice device,
VkSemaphore semaphore,
const VkAllocationCallbacks* pAllocator)
{
return VK_SUCCESS;
}
VKAPI_ATTR void VKAPI_CALL vkDestroySwapchainKHR(
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkGetPhysicalDeviceSurfacePresentModesKHR
* If pPresentModes is NULL, then the number of presentation modes supported for the given surface is returned in pPresentModeCount.
* Otherwise, pPresentModeCount must point to a variable set by the user to the number of elements in the pPresentModes array,
* and on return the variable is overwritten with the number of values actually written to pPresentModes.
* If the value of pPresentModeCount is less than the number of presentation modes supported, at most pPresentModeCount values will be written.
* If pPresentModeCount is smaller than the number of presentation modes supported for the given surface, VK_INCOMPLETE will be returned instead of
* VK_SUCCESS to indicate that not all the available values were returned.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkGetPhysicalDeviceSurfacePresentModesKHR(
VkPhysicalDevice physicalDevice,
VkSurfaceKHR surface,
uint32_t* pPresentModeCount,
VkPresentModeKHR* pPresentModes)
{
assert(physicalDevice);
assert(surface);
assert(pPresentModeCount);
const int numModes = 1;
if(!pPresentModes)
{
*pPresentModeCount = numModes;
return VK_SUCCESS;
}
int arraySize = *pPresentModeCount;
int elementsWritten = min(numModes, arraySize);
for(int c = 0; c < elementsWritten; ++c)
{
//TODO
pPresentModes[c] = VK_PRESENT_MODE_FIFO_KHR;
}
*pPresentModeCount = elementsWritten;
if(elementsWritten < numModes)
{
return VK_INCOMPLETE;
}
return VK_SUCCESS;
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkCreateSwapchainKHR
*/
VKAPI_ATTR VkResult VKAPI_CALL vkCreateSwapchainKHR(
VkDevice device,
const VkSwapchainCreateInfoKHR* pCreateInfo,
const VkAllocationCallbacks* pAllocator,
VkSwapchainKHR* pSwapchain)
{
assert(device);
assert(pCreateInfo);
//TODO: allocator is ignored for now
assert(pAllocator == 0);
*pSwapchain = pCreateInfo->surface; //TODO
return VK_SUCCESS;
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkGetSwapchainImagesKHR
* If pSwapchainImages is NULL, then the number of presentable images for swapchain is returned in pSwapchainImageCount.
* Otherwise, pSwapchainImageCount must point to a variable set by the user to the number of elements in the pSwapchainImages array,
* and on return the variable is overwritten with the number of structures actually written to pSwapchainImages.
* If the value of pSwapchainImageCount is less than the number of presentable images for swapchain, at most pSwapchainImageCount structures will be written.
* If pSwapchainImageCount is smaller than the number of presentable images for swapchain, VK_INCOMPLETE will be returned instead of VK_SUCCESS to
* indicate that not all the available values were returned.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkGetSwapchainImagesKHR(
VkDevice device,
VkSwapchainKHR swapchain,
const VkAllocationCallbacks* pAllocator)
uint32_t* pSwapchainImageCount,
VkImage* pSwapchainImages)
{
assert(device);
assert(swapchain);
const int numImages = 2;
if(!pSwapchainImages)
{
*pSwapchainImageCount = numImages;
return VK_SUCCESS;
}
VKAPI_ATTR void VKAPI_CALL vkDestroyDevice(
int arraySize = *pSwapchainImageCount;
int elementsWritten = min(numImages, arraySize);
for(int c = 0; c < elementsWritten; ++c)
{
//TODO
pSwapchainImages[c] = c;
}
*pSwapchainImageCount = elementsWritten;
if(elementsWritten < numImages)
{
return VK_INCOMPLETE;
}
return VK_SUCCESS;
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#commandbuffers-pools
* Command pools are opaque objects that command buffer memory is allocated from, and which allow the implementation to amortize the
* cost of resource creation across multiple command buffers. Command pools are externally synchronized, meaning that a command pool must
* not be used concurrently in multiple threads. That includes use via recording commands on any command buffers allocated from the pool,
* as well as operations that allocate, free, and reset command buffers or the pool itself.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkCreateCommandPool(
VkDevice device,
const VkAllocationCallbacks* pAllocator)
const VkCommandPoolCreateInfo* pCreateInfo,
const VkAllocationCallbacks* pAllocator,
VkCommandPool* pCommandPool)
{
assert(device);
assert(pCreateInfo);
}
//TODO: allocator is ignored for now
assert(pAllocator == 0);
VKAPI_ATTR void VKAPI_CALL vkDestroyInstance(
VkInstance instance,
const VkAllocationCallbacks* pAllocator)
{
*pCommandPool = 0; //TODO implement pool memory allocator
}
VKAPI_ATTR VkResult VKAPI_CALL vkQueuePresentKHR(
VkQueue queue,
const VkPresentInfoKHR* pPresentInfo)
{
return VK_SUCCESS;
}
VKAPI_ATTR VkResult VKAPI_CALL vkQueueSubmit(
VkQueue queue,
uint32_t submitCount,
const VkSubmitInfo* pSubmits,
VkFence fence)
{
return VK_SUCCESS;
}
VKAPI_ATTR VkResult VKAPI_CALL vkAcquireNextImageKHR(
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#commandbuffer-allocation
* vkAllocateCommandBuffers can be used to create multiple command buffers. If the creation of any of those command buffers fails,
* the implementation must destroy all successfully created command buffer objects from this command, set all entries of the pCommandBuffers array to NULL and return the error.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkAllocateCommandBuffers(
VkDevice device,
VkSwapchainKHR swapchain,
uint64_t timeout,
VkSemaphore semaphore,
VkFence fence,
uint32_t* pImageIndex)
{
return VK_SUCCESS;
}
VKAPI_ATTR VkResult VKAPI_CALL vkEndCommandBuffer(
VkCommandBuffer commandBuffer)
const VkCommandBufferAllocateInfo* pAllocateInfo,
VkCommandBuffer* pCommandBuffers)
{
assert(device);
assert(pAllocateInfo);
assert(pCommandBuffers);
VkResult res = VK_SUCCESS;
for(int c = 0; c < pAllocateInfo->commandBufferCount; ++c)
{
pCommandBuffers[c] = malloc(sizeof(_commandBuffer));
if(!pCommandBuffers[c])
{
res = VK_ERROR_OUT_OF_HOST_MEMORY; //TODO or VK_ERROR_OUT_OF_DEVICE_MEMORY?
}
}
if(res != VK_SUCCESS)
{
for(int c = 0; c < pAllocateInfo->commandBufferCount; ++c)
{
free(pCommandBuffers[c]);
pCommandBuffers[c] = 0;
}
}
return res;
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkBeginCommandBuffer
*/
VKAPI_ATTR VkResult VKAPI_CALL vkBeginCommandBuffer(
VkCommandBuffer commandBuffer,
const VkCommandBufferBeginInfo* pBeginInfo)
{
assert(commandBuffer);
assert(pBeginInfo);
//TODO
return VK_SUCCESS;
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkCmdPipelineBarrier
* vkCmdPipelineBarrier is a synchronization command that inserts a dependency between commands submitted to the same queue, or between commands in the same subpass.
* When vkCmdPipelineBarrier is submitted to a queue, it defines a memory dependency between commands that were submitted before it, and those submitted after it.
* If vkCmdPipelineBarrier was recorded outside a render pass instance, the first synchronization scope includes all commands that occur earlier in submission order.
* If vkCmdPipelineBarrier was recorded inside a render pass instance, the first synchronization scope includes only commands that occur earlier in submission order within the same subpass.
* In either case, the first synchronization scope is limited to operations on the pipeline stages determined by the source stage mask specified by srcStageMask.
*
* If vkCmdPipelineBarrier was recorded outside a render pass instance, the second synchronization scope includes all commands that occur later in submission order.
* If vkCmdPipelineBarrier was recorded inside a render pass instance, the second synchronization scope includes only commands that occur later in submission order within the same subpass.
* In either case, the second synchronization scope is limited to operations on the pipeline stages determined by the destination stage mask specified by dstStageMask.
*
* The first access scope is limited to access in the pipeline stages determined by the source stage mask specified by srcStageMask.
* Within that, the first access scope only includes the first access scopes defined by elements of the pMemoryBarriers,
* pBufferMemoryBarriers and pImageMemoryBarriers arrays, which each define a set of memory barriers. If no memory barriers are specified,
* then the first access scope includes no accesses.
*
* The second access scope is limited to access in the pipeline stages determined by the destination stage mask specified by dstStageMask.
* Within that, the second access scope only includes the second access scopes defined by elements of the pMemoryBarriers, pBufferMemoryBarriers and pImageMemoryBarriers arrays,
* which each define a set of memory barriers. If no memory barriers are specified, then the second access scope includes no accesses.
*
* If dependencyFlags includes VK_DEPENDENCY_BY_REGION_BIT, then any dependency between framebuffer-space pipeline stages is framebuffer-local - otherwise it is framebuffer-global.
*/
VKAPI_ATTR void VKAPI_CALL vkCmdPipelineBarrier(
VkCommandBuffer commandBuffer,
VkPipelineStageFlags srcStageMask,
@ -456,9 +657,16 @@ VKAPI_ATTR void VKAPI_CALL vkCmdPipelineBarrier(
uint32_t imageMemoryBarrierCount,
const VkImageMemoryBarrier* pImageMemoryBarriers)
{
assert(commandBuffer);
//TODO
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkCmdClearColorImage
* Color and depth/stencil images can be cleared outside a render pass instance using vkCmdClearColorImage or vkCmdClearDepthStencilImage, respectively.
* These commands are only allowed outside of a render pass instance.
*/
VKAPI_ATTR void VKAPI_CALL vkCmdClearColorImage(
VkCommandBuffer commandBuffer,
VkImage image,
@ -467,65 +675,226 @@ VKAPI_ATTR void VKAPI_CALL vkCmdClearColorImage(
uint32_t rangeCount,
const VkImageSubresourceRange* pRanges)
{
assert(commandBuffer);
//TODO
}
VKAPI_ATTR VkResult VKAPI_CALL vkBeginCommandBuffer(
VkCommandBuffer commandBuffer,
const VkCommandBufferBeginInfo* pBeginInfo)
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkEndCommandBuffer
* If there was an error during recording, the application will be notified by an unsuccessful return code returned by vkEndCommandBuffer.
* If the application wishes to further use the command buffer, the command buffer must be reset. The command buffer must have been in the recording state,
* and is moved to the executable state.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkEndCommandBuffer(
VkCommandBuffer commandBuffer)
{
assert(commandBuffer);
//TODO
return VK_SUCCESS;
}
VKAPI_ATTR VkResult VKAPI_CALL vkAllocateCommandBuffers(
VkDevice device,
const VkCommandBufferAllocateInfo* pAllocateInfo,
VkCommandBuffer* pCommandBuffers)
{
return VK_SUCCESS;
}
VKAPI_ATTR VkResult VKAPI_CALL vkCreateCommandPool(
VkDevice device,
const VkCommandPoolCreateInfo* pCreateInfo,
const VkAllocationCallbacks* pAllocator,
VkCommandPool* pCommandPool)
{
return VK_SUCCESS;
}
VKAPI_ATTR VkResult VKAPI_CALL vkGetSwapchainImagesKHR(
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkAcquireNextImageKHR
*/
VKAPI_ATTR VkResult VKAPI_CALL vkAcquireNextImageKHR(
VkDevice device,
VkSwapchainKHR swapchain,
uint32_t* pSwapchainImageCount,
VkImage* pSwapchainImages)
uint64_t timeout,
VkSemaphore semaphore,
VkFence fence,
uint32_t* pImageIndex)
{
assert(device);
assert(swapchain);
//TODO
return VK_SUCCESS;
}
VKAPI_ATTR VkResult VKAPI_CALL vkCreateSwapchainKHR(
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkQueueSubmit
* vkQueueSubmit is a queue submission command, with each batch defined by an element of pSubmits as an instance of the VkSubmitInfo structure.
* Batches begin execution in the order they appear in pSubmits, but may complete out of order.
* Fence and semaphore operations submitted with vkQueueSubmit have additional ordering constraints compared to other submission commands,
* with dependencies involving previous and subsequent queue operations. Information about these additional constraints can be found in the semaphore and
* fence sections of the synchronization chapter.
* Details on the interaction of pWaitDstStageMask with synchronization are described in the semaphore wait operation section of the synchronization chapter.
* The order that batches appear in pSubmits is used to determine submission order, and thus all the implicit ordering guarantees that respect it.
* Other than these implicit ordering guarantees and any explicit synchronization primitives, these batches may overlap or otherwise execute out of order.
* If any command buffer submitted to this queue is in the executable state, it is moved to the pending state. Once execution of all submissions of a command buffer complete,
* it moves from the pending state, back to the executable state. If a command buffer was recorded with the VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT flag,
* it instead moves back to the invalid state.
* If vkQueueSubmit fails, it may return VK_ERROR_OUT_OF_HOST_MEMORY or VK_ERROR_OUT_OF_DEVICE_MEMORY.
* If it does, the implementation must ensure that the state and contents of any resources or synchronization primitives referenced by the submitted command buffers and any semaphores
* referenced by pSubmits is unaffected by the call or its failure. If vkQueueSubmit fails in such a way that the implementation is unable to make that guarantee,
* the implementation must return VK_ERROR_DEVICE_LOST. See Lost Device.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkQueueSubmit(
VkQueue queue,
uint32_t submitCount,
const VkSubmitInfo* pSubmits,
VkFence fence)
{
assert(queue);
//TODO
return VK_SUCCESS;
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkQueuePresentKHR
* Any writes to memory backing the images referenced by the pImageIndices and pSwapchains members of pPresentInfo,
* that are available before vkQueuePresentKHR is executed, are automatically made visible to the read access performed by the presentation engine.
* This automatic visibility operation for an image happens-after the semaphore signal operation, and happens-before the presentation engine accesses the image.
* Queueing an image for presentation defines a set of queue operations, including waiting on the semaphores and submitting a presentation request to the presentation engine.
* However, the scope of this set of queue operations does not include the actual processing of the image by the presentation engine.
* If vkQueuePresentKHR fails to enqueue the corresponding set of queue operations, it may return VK_ERROR_OUT_OF_HOST_MEMORY or VK_ERROR_OUT_OF_DEVICE_MEMORY.
* If it does, the implementation must ensure that the state and contents of any resources or synchronization primitives referenced is unaffected by the call or its failure.
* If vkQueuePresentKHR fails in such a way that the implementation is unable to make that guarantee, the implementation must return VK_ERROR_DEVICE_LOST.
* However, if the presentation request is rejected by the presentation engine with an error VK_ERROR_OUT_OF_DATE_KHR or VK_ERROR_SURFACE_LOST_KHR,
* the set of queue operations are still considered to be enqueued and thus any semaphore to be waited on gets unsignaled when the corresponding queue operation is complete.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkQueuePresentKHR(
VkQueue queue,
const VkPresentInfoKHR* pPresentInfo)
{
assert(queue);
assert(pPresentInfo);
for(int c = 0; c < pPresentInfo->swapchainCount; ++c)
{
//TODO
modeset_swapbuffer((modeset_dev*)pPresentInfo->pSwapchains[c], pPresentInfo->pImageIndices[c]);
}
return VK_SUCCESS;
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkDeviceWaitIdle
* vkDeviceWaitIdle is equivalent to calling vkQueueWaitIdle for all queues owned by device.
*/
VKAPI_ATTR VkResult VKAPI_CALL vkDeviceWaitIdle(
VkDevice device)
{
assert(device);
//TODO
//possibly wait on ioctl
return VK_SUCCESS;
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkFreeCommandBuffers
* Any primary command buffer that is in the recording or executable state and has any element of pCommandBuffers recorded into it, becomes invalid.
*/
VKAPI_ATTR void VKAPI_CALL vkFreeCommandBuffers(
VkDevice device,
const VkSwapchainCreateInfoKHR* pCreateInfo,
const VkAllocationCallbacks* pAllocator,
VkSwapchainKHR* pSwapchain)
VkCommandPool commandPool,
uint32_t commandBufferCount,
const VkCommandBuffer* pCommandBuffers)
{
return VK_SUCCESS;
assert(device);
//assert(commandPool); //TODO
assert(pCommandBuffers);
for(int c = 0; c < commandBufferCount; ++c)
{
free(pCommandBuffers[c]); //TODO
}
}
VKAPI_ATTR VkResult VKAPI_CALL vkGetPhysicalDeviceSurfacePresentModesKHR(
VkPhysicalDevice physicalDevice,
VkSurfaceKHR surface,
uint32_t* pPresentModeCount,
VkPresentModeKHR* pPresentModes)
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkDestroyCommandPool
* When a pool is destroyed, all command buffers allocated from the pool are freed.
* Any primary command buffer allocated from another VkCommandPool that is in the recording or executable state and has a secondary command buffer
* allocated from commandPool recorded into it, becomes invalid.
*/
VKAPI_ATTR void VKAPI_CALL vkDestroyCommandPool(
VkDevice device,
VkCommandPool commandPool,
const VkAllocationCallbacks* pAllocator)
{
return VK_SUCCESS;
assert(device);
//assert(commandPool); //TODO
//TODO: allocator is ignored for now
assert(pAllocator == 0);
//TODO
}
VKAPI_ATTR VkResult VKAPI_CALL vkGetPhysicalDeviceSurfaceFormatsKHR(
VkPhysicalDevice physicalDevice,
VkSurfaceKHR surface,
uint32_t* pSurfaceFormatCount,
VkSurfaceFormatKHR* pSurfaceFormats)
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkDestroySemaphore
*/
VKAPI_ATTR void VKAPI_CALL vkDestroySemaphore(
VkDevice device,
VkSemaphore semaphore,
const VkAllocationCallbacks* pAllocator)
{
return VK_SUCCESS;
assert(device);
assert(semaphore);
//TODO: allocator is ignored for now
assert(pAllocator == 0);
//TODO
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkDestroySwapchainKHR
*/
VKAPI_ATTR void VKAPI_CALL vkDestroySwapchainKHR(
VkDevice device,
VkSwapchainKHR swapchain,
const VkAllocationCallbacks* pAllocator)
{
assert(device);
assert(swapchain);
//TODO: allocator is ignored for now
assert(pAllocator == 0);
//TODO
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkDestroyDevice
* To ensure that no work is active on the device, vkDeviceWaitIdle can be used to gate the destruction of the device.
* Prior to destroying a device, an application is responsible for destroying/freeing any Vulkan objects that were created using that device as the
* first parameter of the corresponding vkCreate* or vkAllocate* command
*/
VKAPI_ATTR void VKAPI_CALL vkDestroyDevice(
VkDevice device,
const VkAllocationCallbacks* pAllocator)
{
assert(device);
//TODO: allocator is ignored for now
assert(pAllocator == 0);
//TODO
}
/*
* https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkDestroyInstance
*
*/
VKAPI_ATTR void VKAPI_CALL vkDestroyInstance(
VkInstance instance,
const VkAllocationCallbacks* pAllocator)
{
assert(instance);
//TODO: allocator is ignored for now
assert(pAllocator == 0);
//TODO
}

View File

@ -47,28 +47,6 @@
* Everything else stays the same.
*/
struct modeset_buf {
uint32_t width;
uint32_t height;
uint32_t stride;
uint32_t size;
uint32_t handle;
uint8_t *map;
uint32_t fb;
};
struct modeset_dev {
struct modeset_dev *next;
unsigned int front_buf;
struct modeset_buf bufs[2];
drmModeModeInfo mode;
uint32_t conn;
uint32_t crtc;
drmModeCrtc *saved_crtc;
};
//static struct modeset_dev *modeset_list = NULL;
static int fd = -1;
@ -473,8 +451,10 @@ static void modeset_destroy_fb(struct modeset_buf *buf)
* vertical-sync.
*/
void modeset_swapbuffer(modeset_dev* dev)
void modeset_swapbuffer(modeset_dev* dev, unsigned index)
{
//TODO use index!!
struct modeset_dev *iter;
struct modeset_buf *buf;
int ret;

View File

@ -17,11 +17,31 @@ extern "C" {
#include <xf86drm.h>
#include <xf86drmMode.h>
typedef struct modeset_dev modeset_dev;
typedef struct modeset_buf {
uint32_t width;
uint32_t height;
uint32_t stride;
uint32_t size;
uint32_t handle;
uint8_t *map;
uint32_t fb;
} modeset_buf;
typedef struct modeset_dev {
struct modeset_dev *next;
unsigned int front_buf;
struct modeset_buf bufs[2];
drmModeModeInfo mode;
uint32_t conn;
uint32_t crtc;
drmModeCrtc *saved_crtc;
} modeset_dev;
int modeset_open(const char* node);
modeset_dev* modeset_create();
void modeset_swapbuffer(modeset_dev* dev);
void modeset_swapbuffer(modeset_dev* dev, unsigned index);
void modeset_destroy(modeset_dev* dev);
void modeset_close();