vkr: validate array sizes and string lengths

For a (fooCount, pFoo) array, we encode fooCount twice.  Previously, we
used one for allocation and the other for initialization.  When the two
differed, we could allocate an array of N elements but initialize only
the first M elements.  We only validated that M <= N.

After this commit, vn_decode_array_size validates that M == N.

The other main change is that this commit adds vn_decode_char_array to
make sure strings are null-terminated.

Signed-off-by: Chia-I Wu <olvaffe@gmail.com>
Reviewed-by: Yiwei Zhang <zzyiwei@chromium.org>
Reviewed-by: Ryan Neph <ryanneph@google.com>
macos/master
Chia-I Wu 3 years ago
parent 4c646dc68f
commit 92b083bb29
  1. 2
      src/venus/venus-protocol/vn_protocol_renderer.h
  2. 6
      src/venus/venus-protocol/vn_protocol_renderer_buffer.h
  3. 188
      src/venus/venus-protocol/vn_protocol_renderer_command_buffer.h
  4. 6
      src/venus/venus-protocol/vn_protocol_renderer_descriptor_pool.h
  5. 48
      src/venus/venus-protocol/vn_protocol_renderer_descriptor_set.h
  6. 18
      src/venus/venus-protocol/vn_protocol_renderer_descriptor_set_layout.h
  7. 6
      src/venus/venus-protocol/vn_protocol_renderer_descriptor_update_template.h
  8. 112
      src/venus/venus-protocol/vn_protocol_renderer_device.h
  9. 12
      src/venus/venus-protocol/vn_protocol_renderer_device_memory.h
  10. 12
      src/venus/venus-protocol/vn_protocol_renderer_fence.h
  11. 12
      src/venus/venus-protocol/vn_protocol_renderer_framebuffer.h
  12. 30
      src/venus/venus-protocol/vn_protocol_renderer_image.h
  13. 44
      src/venus/venus-protocol/vn_protocol_renderer_instance.h
  14. 70
      src/venus/venus-protocol/vn_protocol_renderer_pipeline.h
  15. 6
      src/venus/venus-protocol/vn_protocol_renderer_pipeline_cache.h
  16. 12
      src/venus/venus-protocol/vn_protocol_renderer_pipeline_layout.h
  17. 84
      src/venus/venus-protocol/vn_protocol_renderer_queue.h
  18. 78
      src/venus/venus-protocol/vn_protocol_renderer_render_pass.h
  19. 6
      src/venus/venus-protocol/vn_protocol_renderer_semaphore.h
  20. 8
      src/venus/venus-protocol/vn_protocol_renderer_structs.h
  21. 12
      src/venus/venus-protocol/vn_protocol_renderer_transport.h
  22. 33
      src/venus/venus-protocol/vn_protocol_renderer_types.h

@ -1,4 +1,4 @@
/* This file is generated by venus-protocol git-2c162241. */
/* This file is generated by venus-protocol git-712f11f6. */
/*
* Copyright 2020 Google LLC

@ -732,10 +732,10 @@ static inline void vn_decode_vkBindBufferMemory2_args_temp(struct vn_cs_decoder
vn_decode_VkDevice_lookup(dec, &args->device);
vn_decode_uint32_t(dec, &args->bindInfoCount);
if (vn_peek_array_size(dec)) {
args->pBindInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBindInfos) * args->bindInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->bindInfoCount);
args->pBindInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBindInfos) * iter_count);
if (!args->pBindInfos) return;
vn_decode_array_size(dec, args->bindInfoCount);
for (uint32_t i = 0; i < args->bindInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBindBufferMemoryInfo_temp(dec, &((VkBindBufferMemoryInfo *)args->pBindInfos)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -447,14 +447,14 @@ vn_decode_VkImageBlit_temp(struct vn_cs_decoder *dec, VkImageBlit *val)
{
vn_decode_VkImageSubresourceLayers_temp(dec, &val->srcSubresource);
{
vn_decode_array_size(dec, 2);
for (uint32_t i = 0; i < 2; i++)
const uint32_t iter_count = vn_decode_array_size(dec, 2);
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkOffset3D_temp(dec, &val->srcOffsets[i]);
}
vn_decode_VkImageSubresourceLayers_temp(dec, &val->dstSubresource);
{
vn_decode_array_size(dec, 2);
for (uint32_t i = 0; i < 2; i++)
const uint32_t iter_count = vn_decode_array_size(dec, 2);
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkOffset3D_temp(dec, &val->dstOffsets[i]);
}
}
@ -837,10 +837,10 @@ vn_decode_VkDeviceGroupRenderPassBeginInfo_self_temp(struct vn_cs_decoder *dec,
vn_decode_uint32_t(dec, &val->deviceMask);
vn_decode_uint32_t(dec, &val->deviceRenderAreaCount);
if (vn_peek_array_size(dec)) {
val->pDeviceRenderAreas = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDeviceRenderAreas) * val->deviceRenderAreaCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->deviceRenderAreaCount);
val->pDeviceRenderAreas = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDeviceRenderAreas) * iter_count);
if (!val->pDeviceRenderAreas) return;
vn_decode_array_size(dec, val->deviceRenderAreaCount);
for (uint32_t i = 0; i < val->deviceRenderAreaCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkRect2D_temp(dec, &((VkRect2D *)val->pDeviceRenderAreas)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -909,10 +909,10 @@ vn_decode_VkRenderPassAttachmentBeginInfo_self_temp(struct vn_cs_decoder *dec, V
/* skip val->{sType,pNext} */
vn_decode_uint32_t(dec, &val->attachmentCount);
if (vn_peek_array_size(dec)) {
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * val->attachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->attachmentCount);
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * iter_count);
if (!val->pAttachments) return;
vn_decode_array_size(dec, val->attachmentCount);
for (uint32_t i = 0; i < val->attachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageView_lookup(dec, &((VkImageView *)val->pAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1011,10 +1011,10 @@ vn_decode_VkRenderPassBeginInfo_self_temp(struct vn_cs_decoder *dec, VkRenderPas
vn_decode_VkRect2D_temp(dec, &val->renderArea);
vn_decode_uint32_t(dec, &val->clearValueCount);
if (vn_peek_array_size(dec)) {
val->pClearValues = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pClearValues) * val->clearValueCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->clearValueCount);
val->pClearValues = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pClearValues) * iter_count);
if (!val->pClearValues) return;
vn_decode_array_size(dec, val->clearValueCount);
for (uint32_t i = 0; i < val->clearValueCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkClearValue_temp(dec, &((VkClearValue *)val->pClearValues)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1195,10 +1195,10 @@ static inline void vn_decode_vkAllocateCommandBuffers_args_temp(struct vn_cs_dec
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pCommandBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCommandBuffers) * (args->pAllocateInfo ? args->pAllocateInfo->commandBufferCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pAllocateInfo ? args->pAllocateInfo->commandBufferCount : 0));
args->pCommandBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCommandBuffers) * iter_count);
if (!args->pCommandBuffers) return;
vn_decode_array_size(dec, (args->pAllocateInfo ? args->pAllocateInfo->commandBufferCount : 0));
for (uint32_t i = 0; i < (args->pAllocateInfo ? args->pAllocateInfo->commandBufferCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkCommandBuffer_temp(dec, &args->pCommandBuffers[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1236,10 +1236,10 @@ static inline void vn_decode_vkFreeCommandBuffers_args_temp(struct vn_cs_decoder
vn_decode_VkCommandPool_lookup(dec, &args->commandPool);
vn_decode_uint32_t(dec, &args->commandBufferCount);
if (vn_peek_array_size(dec)) {
args->pCommandBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCommandBuffers) * args->commandBufferCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->commandBufferCount);
args->pCommandBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCommandBuffers) * iter_count);
if (!args->pCommandBuffers) return;
vn_decode_array_size(dec, args->commandBufferCount);
for (uint32_t i = 0; i < args->commandBufferCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkCommandBuffer_lookup(dec, &((VkCommandBuffer *)args->pCommandBuffers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1365,10 +1365,10 @@ static inline void vn_decode_vkCmdSetViewport_args_temp(struct vn_cs_decoder *de
vn_decode_uint32_t(dec, &args->firstViewport);
vn_decode_uint32_t(dec, &args->viewportCount);
if (vn_peek_array_size(dec)) {
args->pViewports = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pViewports) * args->viewportCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->viewportCount);
args->pViewports = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pViewports) * iter_count);
if (!args->pViewports) return;
vn_decode_array_size(dec, args->viewportCount);
for (uint32_t i = 0; i < args->viewportCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkViewport_temp(dec, &((VkViewport *)args->pViewports)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1403,10 +1403,10 @@ static inline void vn_decode_vkCmdSetScissor_args_temp(struct vn_cs_decoder *dec
vn_decode_uint32_t(dec, &args->firstScissor);
vn_decode_uint32_t(dec, &args->scissorCount);
if (vn_peek_array_size(dec)) {
args->pScissors = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pScissors) * args->scissorCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->scissorCount);
args->pScissors = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pScissors) * iter_count);
if (!args->pScissors) return;
vn_decode_array_size(dec, args->scissorCount);
for (uint32_t i = 0; i < args->scissorCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkRect2D_temp(dec, &((VkRect2D *)args->pScissors)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1604,10 +1604,10 @@ static inline void vn_decode_vkCmdBindDescriptorSets_args_temp(struct vn_cs_deco
vn_decode_uint32_t(dec, &args->firstSet);
vn_decode_uint32_t(dec, &args->descriptorSetCount);
if (vn_peek_array_size(dec)) {
args->pDescriptorSets = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorSets) * args->descriptorSetCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->descriptorSetCount);
args->pDescriptorSets = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorSets) * iter_count);
if (!args->pDescriptorSets) return;
vn_decode_array_size(dec, args->descriptorSetCount);
for (uint32_t i = 0; i < args->descriptorSetCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorSet_lookup(dec, &((VkDescriptorSet *)args->pDescriptorSets)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1686,10 +1686,10 @@ static inline void vn_decode_vkCmdBindVertexBuffers_args_temp(struct vn_cs_decod
vn_decode_uint32_t(dec, &args->firstBinding);
vn_decode_uint32_t(dec, &args->bindingCount);
if (vn_peek_array_size(dec)) {
args->pBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBuffers) * args->bindingCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->bindingCount);
args->pBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBuffers) * iter_count);
if (!args->pBuffers) return;
vn_decode_array_size(dec, args->bindingCount);
for (uint32_t i = 0; i < args->bindingCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBuffer_lookup(dec, &((VkBuffer *)args->pBuffers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1904,10 +1904,10 @@ static inline void vn_decode_vkCmdCopyBuffer_args_temp(struct vn_cs_decoder *dec
vn_decode_VkBuffer_lookup(dec, &args->dstBuffer);
vn_decode_uint32_t(dec, &args->regionCount);
if (vn_peek_array_size(dec)) {
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * args->regionCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->regionCount);
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * iter_count);
if (!args->pRegions) return;
vn_decode_array_size(dec, args->regionCount);
for (uint32_t i = 0; i < args->regionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBufferCopy_temp(dec, &((VkBufferCopy *)args->pRegions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1947,10 +1947,10 @@ static inline void vn_decode_vkCmdCopyImage_args_temp(struct vn_cs_decoder *dec,
vn_decode_VkImageLayout(dec, &args->dstImageLayout);
vn_decode_uint32_t(dec, &args->regionCount);
if (vn_peek_array_size(dec)) {
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * args->regionCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->regionCount);
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * iter_count);
if (!args->pRegions) return;
vn_decode_array_size(dec, args->regionCount);
for (uint32_t i = 0; i < args->regionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageCopy_temp(dec, &((VkImageCopy *)args->pRegions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1994,10 +1994,10 @@ static inline void vn_decode_vkCmdBlitImage_args_temp(struct vn_cs_decoder *dec,
vn_decode_VkImageLayout(dec, &args->dstImageLayout);
vn_decode_uint32_t(dec, &args->regionCount);
if (vn_peek_array_size(dec)) {
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * args->regionCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->regionCount);
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * iter_count);
if (!args->pRegions) return;
vn_decode_array_size(dec, args->regionCount);
for (uint32_t i = 0; i < args->regionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageBlit_temp(dec, &((VkImageBlit *)args->pRegions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2043,10 +2043,10 @@ static inline void vn_decode_vkCmdCopyBufferToImage_args_temp(struct vn_cs_decod
vn_decode_VkImageLayout(dec, &args->dstImageLayout);
vn_decode_uint32_t(dec, &args->regionCount);
if (vn_peek_array_size(dec)) {
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * args->regionCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->regionCount);
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * iter_count);
if (!args->pRegions) return;
vn_decode_array_size(dec, args->regionCount);
for (uint32_t i = 0; i < args->regionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBufferImageCopy_temp(dec, &((VkBufferImageCopy *)args->pRegions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2087,10 +2087,10 @@ static inline void vn_decode_vkCmdCopyImageToBuffer_args_temp(struct vn_cs_decod
vn_decode_VkBuffer_lookup(dec, &args->dstBuffer);
vn_decode_uint32_t(dec, &args->regionCount);
if (vn_peek_array_size(dec)) {
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * args->regionCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->regionCount);
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * iter_count);
if (!args->pRegions) return;
vn_decode_array_size(dec, args->regionCount);
for (uint32_t i = 0; i < args->regionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBufferImageCopy_temp(dec, &((VkBufferImageCopy *)args->pRegions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2203,10 +2203,10 @@ static inline void vn_decode_vkCmdClearColorImage_args_temp(struct vn_cs_decoder
}
vn_decode_uint32_t(dec, &args->rangeCount);
if (vn_peek_array_size(dec)) {
args->pRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRanges) * args->rangeCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->rangeCount);
args->pRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRanges) * iter_count);
if (!args->pRanges) return;
vn_decode_array_size(dec, args->rangeCount);
for (uint32_t i = 0; i < args->rangeCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageSubresourceRange_temp(dec, &((VkImageSubresourceRange *)args->pRanges)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2254,10 +2254,10 @@ static inline void vn_decode_vkCmdClearDepthStencilImage_args_temp(struct vn_cs_
}
vn_decode_uint32_t(dec, &args->rangeCount);
if (vn_peek_array_size(dec)) {
args->pRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRanges) * args->rangeCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->rangeCount);
args->pRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRanges) * iter_count);
if (!args->pRanges) return;
vn_decode_array_size(dec, args->rangeCount);
for (uint32_t i = 0; i < args->rangeCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageSubresourceRange_temp(dec, &((VkImageSubresourceRange *)args->pRanges)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2296,10 +2296,10 @@ static inline void vn_decode_vkCmdClearAttachments_args_temp(struct vn_cs_decode
vn_decode_VkCommandBuffer_lookup(dec, &args->commandBuffer);
vn_decode_uint32_t(dec, &args->attachmentCount);
if (vn_peek_array_size(dec)) {
args->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pAttachments) * args->attachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->attachmentCount);
args->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pAttachments) * iter_count);
if (!args->pAttachments) return;
vn_decode_array_size(dec, args->attachmentCount);
for (uint32_t i = 0; i < args->attachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkClearAttachment_temp(dec, &((VkClearAttachment *)args->pAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2307,10 +2307,10 @@ static inline void vn_decode_vkCmdClearAttachments_args_temp(struct vn_cs_decode
}
vn_decode_uint32_t(dec, &args->rectCount);
if (vn_peek_array_size(dec)) {
args->pRects = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRects) * args->rectCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->rectCount);
args->pRects = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRects) * iter_count);
if (!args->pRects) return;
vn_decode_array_size(dec, args->rectCount);
for (uint32_t i = 0; i < args->rectCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkClearRect_temp(dec, &((VkClearRect *)args->pRects)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2353,10 +2353,10 @@ static inline void vn_decode_vkCmdResolveImage_args_temp(struct vn_cs_decoder *d
vn_decode_VkImageLayout(dec, &args->dstImageLayout);
vn_decode_uint32_t(dec, &args->regionCount);
if (vn_peek_array_size(dec)) {
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * args->regionCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->regionCount);
args->pRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pRegions) * iter_count);
if (!args->pRegions) return;
vn_decode_array_size(dec, args->regionCount);
for (uint32_t i = 0; i < args->regionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageResolve_temp(dec, &((VkImageResolve *)args->pRegions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2442,10 +2442,10 @@ static inline void vn_decode_vkCmdWaitEvents_args_temp(struct vn_cs_decoder *dec
vn_decode_VkCommandBuffer_lookup(dec, &args->commandBuffer);
vn_decode_uint32_t(dec, &args->eventCount);
if (vn_peek_array_size(dec)) {
args->pEvents = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pEvents) * args->eventCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->eventCount);
args->pEvents = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pEvents) * iter_count);
if (!args->pEvents) return;
vn_decode_array_size(dec, args->eventCount);
for (uint32_t i = 0; i < args->eventCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkEvent_lookup(dec, &((VkEvent *)args->pEvents)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2455,10 +2455,10 @@ static inline void vn_decode_vkCmdWaitEvents_args_temp(struct vn_cs_decoder *dec
vn_decode_VkFlags(dec, &args->dstStageMask);
vn_decode_uint32_t(dec, &args->memoryBarrierCount);
if (vn_peek_array_size(dec)) {
args->pMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pMemoryBarriers) * args->memoryBarrierCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->memoryBarrierCount);
args->pMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pMemoryBarriers) * iter_count);
if (!args->pMemoryBarriers) return;
vn_decode_array_size(dec, args->memoryBarrierCount);
for (uint32_t i = 0; i < args->memoryBarrierCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkMemoryBarrier_temp(dec, &((VkMemoryBarrier *)args->pMemoryBarriers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2466,10 +2466,10 @@ static inline void vn_decode_vkCmdWaitEvents_args_temp(struct vn_cs_decoder *dec
}
vn_decode_uint32_t(dec, &args->bufferMemoryBarrierCount);
if (vn_peek_array_size(dec)) {
args->pBufferMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBufferMemoryBarriers) * args->bufferMemoryBarrierCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->bufferMemoryBarrierCount);
args->pBufferMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBufferMemoryBarriers) * iter_count);
if (!args->pBufferMemoryBarriers) return;
vn_decode_array_size(dec, args->bufferMemoryBarrierCount);
for (uint32_t i = 0; i < args->bufferMemoryBarrierCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBufferMemoryBarrier_temp(dec, &((VkBufferMemoryBarrier *)args->pBufferMemoryBarriers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2477,10 +2477,10 @@ static inline void vn_decode_vkCmdWaitEvents_args_temp(struct vn_cs_decoder *dec
}
vn_decode_uint32_t(dec, &args->imageMemoryBarrierCount);
if (vn_peek_array_size(dec)) {
args->pImageMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pImageMemoryBarriers) * args->imageMemoryBarrierCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->imageMemoryBarrierCount);
args->pImageMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pImageMemoryBarriers) * iter_count);
if (!args->pImageMemoryBarriers) return;
vn_decode_array_size(dec, args->imageMemoryBarrierCount);
for (uint32_t i = 0; i < args->imageMemoryBarrierCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageMemoryBarrier_temp(dec, &((VkImageMemoryBarrier *)args->pImageMemoryBarriers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2540,10 +2540,10 @@ static inline void vn_decode_vkCmdPipelineBarrier_args_temp(struct vn_cs_decoder
vn_decode_VkFlags(dec, &args->dependencyFlags);
vn_decode_uint32_t(dec, &args->memoryBarrierCount);
if (vn_peek_array_size(dec)) {
args->pMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pMemoryBarriers) * args->memoryBarrierCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->memoryBarrierCount);
args->pMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pMemoryBarriers) * iter_count);
if (!args->pMemoryBarriers) return;
vn_decode_array_size(dec, args->memoryBarrierCount);
for (uint32_t i = 0; i < args->memoryBarrierCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkMemoryBarrier_temp(dec, &((VkMemoryBarrier *)args->pMemoryBarriers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2551,10 +2551,10 @@ static inline void vn_decode_vkCmdPipelineBarrier_args_temp(struct vn_cs_decoder
}
vn_decode_uint32_t(dec, &args->bufferMemoryBarrierCount);
if (vn_peek_array_size(dec)) {
args->pBufferMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBufferMemoryBarriers) * args->bufferMemoryBarrierCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->bufferMemoryBarrierCount);
args->pBufferMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBufferMemoryBarriers) * iter_count);
if (!args->pBufferMemoryBarriers) return;
vn_decode_array_size(dec, args->bufferMemoryBarrierCount);
for (uint32_t i = 0; i < args->bufferMemoryBarrierCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBufferMemoryBarrier_temp(dec, &((VkBufferMemoryBarrier *)args->pBufferMemoryBarriers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2562,10 +2562,10 @@ static inline void vn_decode_vkCmdPipelineBarrier_args_temp(struct vn_cs_decoder
}
vn_decode_uint32_t(dec, &args->imageMemoryBarrierCount);
if (vn_peek_array_size(dec)) {
args->pImageMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pImageMemoryBarriers) * args->imageMemoryBarrierCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->imageMemoryBarrierCount);
args->pImageMemoryBarriers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pImageMemoryBarriers) * iter_count);
if (!args->pImageMemoryBarriers) return;
vn_decode_array_size(dec, args->imageMemoryBarrierCount);
for (uint32_t i = 0; i < args->imageMemoryBarrierCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageMemoryBarrier_temp(dec, &((VkImageMemoryBarrier *)args->pImageMemoryBarriers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -2864,10 +2864,10 @@ static inline void vn_decode_vkCmdExecuteCommands_args_temp(struct vn_cs_decoder
vn_decode_VkCommandBuffer_lookup(dec, &args->commandBuffer);
vn_decode_uint32_t(dec, &args->commandBufferCount);
if (vn_peek_array_size(dec)) {
args->pCommandBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCommandBuffers) * args->commandBufferCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->commandBufferCount);
args->pCommandBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCommandBuffers) * iter_count);
if (!args->pCommandBuffers) return;
vn_decode_array_size(dec, args->commandBufferCount);
for (uint32_t i = 0; i < args->commandBufferCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkCommandBuffer_lookup(dec, &((VkCommandBuffer *)args->pCommandBuffers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -3131,10 +3131,10 @@ static inline void vn_decode_vkCmdBindTransformFeedbackBuffersEXT_args_temp(stru
vn_decode_uint32_t(dec, &args->firstBinding);
vn_decode_uint32_t(dec, &args->bindingCount);
if (vn_peek_array_size(dec)) {
args->pBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBuffers) * args->bindingCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->bindingCount);
args->pBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBuffers) * iter_count);
if (!args->pBuffers) return;
vn_decode_array_size(dec, args->bindingCount);
for (uint32_t i = 0; i < args->bindingCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBuffer_lookup(dec, &((VkBuffer *)args->pBuffers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -3191,10 +3191,10 @@ static inline void vn_decode_vkCmdBeginTransformFeedbackEXT_args_temp(struct vn_
vn_decode_uint32_t(dec, &args->firstCounterBuffer);
vn_decode_uint32_t(dec, &args->counterBufferCount);
if (vn_peek_array_size(dec)) {
args->pCounterBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCounterBuffers) * args->counterBufferCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->counterBufferCount);
args->pCounterBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCounterBuffers) * iter_count);
if (!args->pCounterBuffers) return;
vn_decode_array_size(dec, args->counterBufferCount);
for (uint32_t i = 0; i < args->counterBufferCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBuffer_lookup(dec, &((VkBuffer *)args->pCounterBuffers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -3240,10 +3240,10 @@ static inline void vn_decode_vkCmdEndTransformFeedbackEXT_args_temp(struct vn_cs
vn_decode_uint32_t(dec, &args->firstCounterBuffer);
vn_decode_uint32_t(dec, &args->counterBufferCount);
if (vn_peek_array_size(dec)) {
args->pCounterBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCounterBuffers) * args->counterBufferCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->counterBufferCount);
args->pCounterBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCounterBuffers) * iter_count);
if (!args->pCounterBuffers) return;
vn_decode_array_size(dec, args->counterBufferCount);
for (uint32_t i = 0; i < args->counterBufferCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBuffer_lookup(dec, &((VkBuffer *)args->pCounterBuffers)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -49,10 +49,10 @@ vn_decode_VkDescriptorPoolCreateInfo_self_temp(struct vn_cs_decoder *dec, VkDesc
vn_decode_uint32_t(dec, &val->maxSets);
vn_decode_uint32_t(dec, &val->poolSizeCount);
if (vn_peek_array_size(dec)) {
val->pPoolSizes = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pPoolSizes) * val->poolSizeCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->poolSizeCount);
val->pPoolSizes = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pPoolSizes) * iter_count);
if (!val->pPoolSizes) return;
vn_decode_array_size(dec, val->poolSizeCount);
for (uint32_t i = 0; i < val->poolSizeCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorPoolSize_temp(dec, &((VkDescriptorPoolSize *)val->pPoolSizes)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -125,10 +125,10 @@ vn_decode_VkDescriptorSetAllocateInfo_self_temp(struct vn_cs_decoder *dec, VkDes
vn_decode_VkDescriptorPool_lookup(dec, &val->descriptorPool);
vn_decode_uint32_t(dec, &val->descriptorSetCount);
if (vn_peek_array_size(dec)) {
val->pSetLayouts = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSetLayouts) * val->descriptorSetCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->descriptorSetCount);
val->pSetLayouts = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSetLayouts) * iter_count);
if (!val->pSetLayouts) return;
vn_decode_array_size(dec, val->descriptorSetCount);
for (uint32_t i = 0; i < val->descriptorSetCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorSetLayout_lookup(dec, &((VkDescriptorSetLayout *)val->pSetLayouts)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -240,30 +240,30 @@ vn_decode_VkWriteDescriptorSet_self_temp(struct vn_cs_decoder *dec, VkWriteDescr
vn_decode_uint32_t(dec, &val->descriptorCount);
vn_decode_VkDescriptorType(dec, &val->descriptorType);
if (vn_peek_array_size(dec)) {
val->pImageInfo = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pImageInfo) * val->descriptorCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->descriptorCount);
val->pImageInfo = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pImageInfo) * iter_count);
if (!val->pImageInfo) return;
vn_decode_array_size(dec, val->descriptorCount);
for (uint32_t i = 0; i < val->descriptorCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorImageInfo_temp(dec, &((VkDescriptorImageInfo *)val->pImageInfo)[i]);
} else {
vn_decode_array_size(dec, 0);
val->pImageInfo = NULL;
}
if (vn_peek_array_size(dec)) {
val->pBufferInfo = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBufferInfo) * val->descriptorCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->descriptorCount);
val->pBufferInfo = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBufferInfo) * iter_count);
if (!val->pBufferInfo) return;
vn_decode_array_size(dec, val->descriptorCount);
for (uint32_t i = 0; i < val->descriptorCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorBufferInfo_temp(dec, &((VkDescriptorBufferInfo *)val->pBufferInfo)[i]);
} else {
vn_decode_array_size(dec, 0);
val->pBufferInfo = NULL;
}
if (vn_peek_array_size(dec)) {
val->pTexelBufferView = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pTexelBufferView) * val->descriptorCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->descriptorCount);
val->pTexelBufferView = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pTexelBufferView) * iter_count);
if (!val->pTexelBufferView) return;
vn_decode_array_size(dec, val->descriptorCount);
for (uint32_t i = 0; i < val->descriptorCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBufferView_lookup(dec, &((VkBufferView *)val->pTexelBufferView)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -407,10 +407,10 @@ static inline void vn_decode_vkAllocateDescriptorSets_args_temp(struct vn_cs_dec
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pDescriptorSets = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorSets) * (args->pAllocateInfo ? args->pAllocateInfo->descriptorSetCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pAllocateInfo ? args->pAllocateInfo->descriptorSetCount : 0));
args->pDescriptorSets = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorSets) * iter_count);
if (!args->pDescriptorSets) return;
vn_decode_array_size(dec, (args->pAllocateInfo ? args->pAllocateInfo->descriptorSetCount : 0));
for (uint32_t i = 0; i < (args->pAllocateInfo ? args->pAllocateInfo->descriptorSetCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorSet(dec, &args->pDescriptorSets[i]);
} else {
vn_decode_array_size(dec, 0);
@ -448,10 +448,10 @@ static inline void vn_decode_vkFreeDescriptorSets_args_temp(struct vn_cs_decoder
vn_decode_VkDescriptorPool_lookup(dec, &args->descriptorPool);
vn_decode_uint32_t(dec, &args->descriptorSetCount);
if (vn_peek_array_size(dec)) {
args->pDescriptorSets = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorSets) * args->descriptorSetCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->descriptorSetCount);
args->pDescriptorSets = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorSets) * iter_count);
if (!args->pDescriptorSets) return;
vn_decode_array_size(dec, args->descriptorSetCount);
for (uint32_t i = 0; i < args->descriptorSetCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorSet_lookup(dec, &((VkDescriptorSet *)args->pDescriptorSets)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -486,10 +486,10 @@ static inline void vn_decode_vkUpdateDescriptorSets_args_temp(struct vn_cs_decod
vn_decode_VkDevice_lookup(dec, &args->device);
vn_decode_uint32_t(dec, &args->descriptorWriteCount);
if (vn_peek_array_size(dec)) {
args->pDescriptorWrites = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorWrites) * args->descriptorWriteCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->descriptorWriteCount);
args->pDescriptorWrites = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorWrites) * iter_count);
if (!args->pDescriptorWrites) return;
vn_decode_array_size(dec, args->descriptorWriteCount);
for (uint32_t i = 0; i < args->descriptorWriteCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkWriteDescriptorSet_temp(dec, &((VkWriteDescriptorSet *)args->pDescriptorWrites)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -497,10 +497,10 @@ static inline void vn_decode_vkUpdateDescriptorSets_args_temp(struct vn_cs_decod
}
vn_decode_uint32_t(dec, &args->descriptorCopyCount);
if (vn_peek_array_size(dec)) {
args->pDescriptorCopies = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorCopies) * args->descriptorCopyCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->descriptorCopyCount);
args->pDescriptorCopies = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDescriptorCopies) * iter_count);
if (!args->pDescriptorCopies) return;
vn_decode_array_size(dec, args->descriptorCopyCount);
for (uint32_t i = 0; i < args->descriptorCopyCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkCopyDescriptorSet_temp(dec, &((VkCopyDescriptorSet *)args->pDescriptorCopies)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -24,10 +24,10 @@ vn_decode_VkDescriptorSetLayoutBinding_temp(struct vn_cs_decoder *dec, VkDescrip
vn_decode_uint32_t(dec, &val->descriptorCount);
vn_decode_VkFlags(dec, &val->stageFlags);
if (vn_peek_array_size(dec)) {
val->pImmutableSamplers = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pImmutableSamplers) * val->descriptorCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->descriptorCount);
val->pImmutableSamplers = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pImmutableSamplers) * iter_count);
if (!val->pImmutableSamplers) return;
vn_decode_array_size(dec, val->descriptorCount);
for (uint32_t i = 0; i < val->descriptorCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSampler_lookup(dec, &((VkSampler *)val->pImmutableSamplers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -65,10 +65,10 @@ vn_decode_VkDescriptorSetLayoutBindingFlagsCreateInfo_self_temp(struct vn_cs_dec
/* skip val->{sType,pNext} */
vn_decode_uint32_t(dec, &val->bindingCount);
if (vn_peek_array_size(dec)) {
val->pBindingFlags = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBindingFlags) * val->bindingCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->bindingCount);
val->pBindingFlags = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBindingFlags) * iter_count);
if (!val->pBindingFlags) return;
vn_decode_array_size(dec, val->bindingCount);
for (uint32_t i = 0; i < val->bindingCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkFlags(dec, &((VkDescriptorBindingFlags *)val->pBindingFlags)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -154,10 +154,10 @@ vn_decode_VkDescriptorSetLayoutCreateInfo_self_temp(struct vn_cs_decoder *dec, V
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->bindingCount);
if (vn_peek_array_size(dec)) {
val->pBindings = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBindings) * val->bindingCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->bindingCount);
val->pBindings = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBindings) * iter_count);
if (!val->pBindings) return;
vn_decode_array_size(dec, val->bindingCount);
for (uint32_t i = 0; i < val->bindingCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorSetLayoutBinding_temp(dec, &((VkDescriptorSetLayoutBinding *)val->pBindings)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -56,10 +56,10 @@ vn_decode_VkDescriptorUpdateTemplateCreateInfo_self_temp(struct vn_cs_decoder *d
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->descriptorUpdateEntryCount);
if (vn_peek_array_size(dec)) {
val->pDescriptorUpdateEntries = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDescriptorUpdateEntries) * val->descriptorUpdateEntryCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->descriptorUpdateEntryCount);
val->pDescriptorUpdateEntries = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDescriptorUpdateEntries) * iter_count);
if (!val->pDescriptorUpdateEntries) return;
vn_decode_array_size(dec, val->descriptorUpdateEntryCount);
for (uint32_t i = 0; i < val->descriptorUpdateEntryCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorUpdateTemplateEntry_temp(dec, &((VkDescriptorUpdateTemplateEntry *)val->pDescriptorUpdateEntries)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -283,7 +283,7 @@ vn_encode_VkPhysicalDeviceProperties(struct vn_cs_encoder *enc, const VkPhysical
vn_encode_uint32_t(enc, &val->deviceID);
vn_encode_VkPhysicalDeviceType(enc, &val->deviceType);
vn_encode_array_size(enc, VK_MAX_PHYSICAL_DEVICE_NAME_SIZE);
vn_encode_blob_array(enc, val->deviceName, VK_MAX_PHYSICAL_DEVICE_NAME_SIZE);
vn_encode_char_array(enc, val->deviceName, VK_MAX_PHYSICAL_DEVICE_NAME_SIZE);
vn_encode_array_size(enc, VK_UUID_SIZE);
vn_encode_uint8_t_array(enc, val->pipelineCacheUUID, VK_UUID_SIZE);
vn_encode_VkPhysicalDeviceLimits(enc, &val->limits);
@ -376,14 +376,14 @@ vn_decode_VkPhysicalDeviceMemoryProperties_partial_temp(struct vn_cs_decoder *de
{
/* skip val->memoryTypeCount */
{
vn_decode_array_size(dec, VK_MAX_MEMORY_TYPES);
for (uint32_t i = 0; i < VK_MAX_MEMORY_TYPES; i++)
const uint32_t iter_count = vn_decode_array_size(dec, VK_MAX_MEMORY_TYPES);
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkMemoryType_partial_temp(dec, &val->memoryTypes[i]);
}
/* skip val->memoryHeapCount */
{
vn_decode_array_size(dec, VK_MAX_MEMORY_HEAPS);
for (uint32_t i = 0; i < VK_MAX_MEMORY_HEAPS; i++)
const uint32_t iter_count = vn_decode_array_size(dec, VK_MAX_MEMORY_HEAPS);
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkMemoryHeap_partial_temp(dec, &val->memoryHeaps[i]);
}
}
@ -4213,10 +4213,10 @@ vn_decode_VkDeviceGroupDeviceCreateInfo_self_temp(struct vn_cs_decoder *dec, VkD
/* skip val->{sType,pNext} */
vn_decode_uint32_t(dec, &val->physicalDeviceCount);
if (vn_peek_array_size(dec)) {
val->pPhysicalDevices = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pPhysicalDevices) * val->physicalDeviceCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->physicalDeviceCount);
val->pPhysicalDevices = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pPhysicalDevices) * iter_count);
if (!val->pPhysicalDevices) return;
vn_decode_array_size(dec, val->physicalDeviceCount);
for (uint32_t i = 0; i < val->physicalDeviceCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPhysicalDevice_lookup(dec, &((VkPhysicalDevice *)val->pPhysicalDevices)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -4489,10 +4489,10 @@ vn_decode_VkDeviceCreateInfo_self_temp(struct vn_cs_decoder *dec, VkDeviceCreate
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->queueCreateInfoCount);
if (vn_peek_array_size(dec)) {
val->pQueueCreateInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pQueueCreateInfos) * val->queueCreateInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->queueCreateInfoCount);
val->pQueueCreateInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pQueueCreateInfos) * iter_count);
if (!val->pQueueCreateInfos) return;
vn_decode_array_size(dec, val->queueCreateInfoCount);
for (uint32_t i = 0; i < val->queueCreateInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDeviceQueueCreateInfo_temp(dec, &((VkDeviceQueueCreateInfo *)val->pQueueCreateInfos)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -4500,14 +4500,14 @@ vn_decode_VkDeviceCreateInfo_self_temp(struct vn_cs_decoder *dec, VkDeviceCreate
}
vn_decode_uint32_t(dec, &val->enabledLayerCount);
if (vn_peek_array_size(dec)) {
val->ppEnabledLayerNames = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledLayerNames) * val->enabledLayerCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->enabledLayerCount);
val->ppEnabledLayerNames = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledLayerNames) * iter_count);
if (!val->ppEnabledLayerNames) return;
vn_decode_array_size(dec, val->enabledLayerCount);
for (uint32_t i = 0; i < val->enabledLayerCount; i++) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
for (uint32_t i = 0; i < iter_count; i++) {
const size_t string_size = vn_decode_array_size_unchecked(dec);
((char **)val->ppEnabledLayerNames)[i] = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledLayerNames[i]) * string_size);
if (!val->ppEnabledLayerNames[i]) return;
vn_decode_blob_array(dec, ((char **)val->ppEnabledLayerNames)[i], string_size);
vn_decode_char_array(dec, ((char **)val->ppEnabledLayerNames)[i], string_size);
}
} else {
vn_decode_array_size(dec, 0);
@ -4515,14 +4515,14 @@ vn_decode_VkDeviceCreateInfo_self_temp(struct vn_cs_decoder *dec, VkDeviceCreate
}
vn_decode_uint32_t(dec, &val->enabledExtensionCount);
if (vn_peek_array_size(dec)) {
val->ppEnabledExtensionNames = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledExtensionNames) * val->enabledExtensionCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->enabledExtensionCount);
val->ppEnabledExtensionNames = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledExtensionNames) * iter_count);
if (!val->ppEnabledExtensionNames) return;
vn_decode_array_size(dec, val->enabledExtensionCount);
for (uint32_t i = 0; i < val->enabledExtensionCount; i++) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
for (uint32_t i = 0; i < iter_count; i++) {
const size_t string_size = vn_decode_array_size_unchecked(dec);
((char **)val->ppEnabledExtensionNames)[i] = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledExtensionNames[i]) * string_size);
if (!val->ppEnabledExtensionNames[i]) return;
vn_decode_blob_array(dec, ((char **)val->ppEnabledExtensionNames)[i], string_size);
vn_decode_char_array(dec, ((char **)val->ppEnabledExtensionNames)[i], string_size);
}
} else {
vn_decode_array_size(dec, 0);
@ -4694,9 +4694,9 @@ vn_encode_VkPhysicalDeviceDriverProperties_self(struct vn_cs_encoder *enc, const
/* skip val->{sType,pNext} */
vn_encode_VkDriverId(enc, &val->driverID);
vn_encode_array_size(enc, VK_MAX_DRIVER_NAME_SIZE);
vn_encode_blob_array(enc, val->driverName, VK_MAX_DRIVER_NAME_SIZE);
vn_encode_char_array(enc, val->driverName, VK_MAX_DRIVER_NAME_SIZE);
vn_encode_array_size(enc, VK_MAX_DRIVER_INFO_SIZE);
vn_encode_blob_array(enc, val->driverInfo, VK_MAX_DRIVER_INFO_SIZE);
vn_encode_char_array(enc, val->driverInfo, VK_MAX_DRIVER_INFO_SIZE);
vn_encode_VkConformanceVersion(enc, &val->conformanceVersion);
}
@ -5612,9 +5612,9 @@ vn_encode_VkPhysicalDeviceVulkan12Properties_self(struct vn_cs_encoder *enc, con
/* skip val->{sType,pNext} */
vn_encode_VkDriverId(enc, &val->driverID);
vn_encode_array_size(enc, VK_MAX_DRIVER_NAME_SIZE);
vn_encode_blob_array(enc, val->driverName, VK_MAX_DRIVER_NAME_SIZE);
vn_encode_char_array(enc, val->driverName, VK_MAX_DRIVER_NAME_SIZE);
vn_encode_array_size(enc, VK_MAX_DRIVER_INFO_SIZE);
vn_encode_blob_array(enc, val->driverInfo, VK_MAX_DRIVER_INFO_SIZE);
vn_encode_char_array(enc, val->driverInfo, VK_MAX_DRIVER_INFO_SIZE);
vn_encode_VkConformanceVersion(enc, &val->conformanceVersion);
vn_encode_VkShaderFloatControlsIndependence(enc, &val->denormBehaviorIndependence);
vn_encode_VkShaderFloatControlsIndependence(enc, &val->roundingModeIndependence);
@ -6106,10 +6106,10 @@ vn_decode_VkDrmFormatModifierPropertiesListEXT_self_partial_temp(struct vn_cs_de
/* skip val->{sType,pNext} */
/* skip val->drmFormatModifierCount */
if (vn_peek_array_size(dec)) {
val->pDrmFormatModifierProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDrmFormatModifierProperties) * val->drmFormatModifierCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->drmFormatModifierCount);
val->pDrmFormatModifierProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDrmFormatModifierProperties) * iter_count);
if (!val->pDrmFormatModifierProperties) return;
vn_decode_array_size(dec, val->drmFormatModifierCount);
for (uint32_t i = 0; i < val->drmFormatModifierCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDrmFormatModifierPropertiesEXT_partial_temp(dec, &val->pDrmFormatModifierProperties[i]);
} else {
vn_decode_array_size(dec, 0);
@ -7338,8 +7338,8 @@ vn_decode_VkPhysicalDeviceGroupProperties_self_partial_temp(struct vn_cs_decoder
/* skip val->{sType,pNext} */
/* skip val->physicalDeviceCount */
{
vn_decode_array_size(dec, VK_MAX_DEVICE_GROUP_SIZE);
for (uint32_t i = 0; i < VK_MAX_DEVICE_GROUP_SIZE; i++)
const uint32_t iter_count = vn_decode_array_size(dec, VK_MAX_DEVICE_GROUP_SIZE);
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPhysicalDevice_temp(dec, &val->physicalDevices[i]);
}
/* skip val->subsetAllocation */
@ -7431,10 +7431,10 @@ static inline void vn_decode_vkEnumeratePhysicalDevices_args_temp(struct vn_cs_d
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pPhysicalDevices = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pPhysicalDevices) * (args->pPhysicalDeviceCount ? *args->pPhysicalDeviceCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pPhysicalDeviceCount ? *args->pPhysicalDeviceCount : 0));
args->pPhysicalDevices = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pPhysicalDevices) * iter_count);
if (!args->pPhysicalDevices) return;
vn_decode_array_size(dec, (args->pPhysicalDeviceCount ? *args->pPhysicalDeviceCount : 0));
for (uint32_t i = 0; i < (args->pPhysicalDeviceCount ? *args->pPhysicalDeviceCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPhysicalDevice_temp(dec, &args->pPhysicalDevices[i]);
} else {
vn_decode_array_size(dec, 0);
@ -7506,10 +7506,10 @@ static inline void vn_decode_vkGetPhysicalDeviceQueueFamilyProperties_args_temp(
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pQueueFamilyProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pQueueFamilyProperties) * (args->pQueueFamilyPropertyCount ? *args->pQueueFamilyPropertyCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pQueueFamilyPropertyCount ? *args->pQueueFamilyPropertyCount : 0));
args->pQueueFamilyProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pQueueFamilyProperties) * iter_count);
if (!args->pQueueFamilyProperties) return;
vn_decode_array_size(dec, (args->pQueueFamilyPropertyCount ? *args->pQueueFamilyPropertyCount : 0));
for (uint32_t i = 0; i < (args->pQueueFamilyPropertyCount ? *args->pQueueFamilyPropertyCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkQueueFamilyProperties_partial_temp(dec, &args->pQueueFamilyProperties[i]);
} else {
vn_decode_array_size(dec, 0);
@ -7754,10 +7754,10 @@ static inline void vn_decode_vkEnumerateDeviceLayerProperties_args_temp(struct v
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * (args->pPropertyCount ? *args->pPropertyCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * iter_count);
if (!args->pProperties) return;
vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
for (uint32_t i = 0; i < (args->pPropertyCount ? *args->pPropertyCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkLayerProperties_partial_temp(dec, &args->pProperties[i]);
} else {
vn_decode_array_size(dec, 0);
@ -7793,10 +7793,10 @@ static inline void vn_decode_vkEnumerateDeviceExtensionProperties_args_temp(stru
{
vn_decode_VkPhysicalDevice_lookup(dec, &args->physicalDevice);
if (vn_peek_array_size(dec)) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
const size_t string_size = vn_decode_array_size_unchecked(dec);
args->pLayerName = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pLayerName) * string_size);
if (!args->pLayerName) return;
vn_decode_blob_array(dec, (char *)args->pLayerName, string_size);
vn_decode_char_array(dec, (char *)args->pLayerName, string_size);
} else {
vn_decode_array_size(dec, 0);
args->pLayerName = NULL;
@ -7810,10 +7810,10 @@ static inline void vn_decode_vkEnumerateDeviceExtensionProperties_args_temp(stru
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * (args->pPropertyCount ? *args->pPropertyCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * iter_count);
if (!args->pProperties) return;
vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
for (uint32_t i = 0; i < (args->pPropertyCount ? *args->pPropertyCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkExtensionProperties_partial_temp(dec, &args->pProperties[i]);
} else {
vn_decode_array_size(dec, 0);
@ -7916,10 +7916,10 @@ static inline void vn_decode_vkGetPhysicalDeviceSparseImageFormatProperties_args
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * (args->pPropertyCount ? *args->pPropertyCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * iter_count);
if (!args->pProperties) return;
vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
for (uint32_t i = 0; i < (args->pPropertyCount ? *args->pPropertyCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseImageFormatProperties_partial_temp(dec, &args->pProperties[i]);
} else {
vn_decode_array_size(dec, 0);
@ -8099,10 +8099,10 @@ static inline void vn_decode_vkGetPhysicalDeviceQueueFamilyProperties2_args_temp
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pQueueFamilyProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pQueueFamilyProperties) * (args->pQueueFamilyPropertyCount ? *args->pQueueFamilyPropertyCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pQueueFamilyPropertyCount ? *args->pQueueFamilyPropertyCount : 0));
args->pQueueFamilyProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pQueueFamilyProperties) * iter_count);
if (!args->pQueueFamilyProperties) return;
vn_decode_array_size(dec, (args->pQueueFamilyPropertyCount ? *args->pQueueFamilyPropertyCount : 0));
for (uint32_t i = 0; i < (args->pQueueFamilyPropertyCount ? *args->pQueueFamilyPropertyCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkQueueFamilyProperties2_partial_temp(dec, &args->pQueueFamilyProperties[i]);
} else {
vn_decode_array_size(dec, 0);
@ -8181,10 +8181,10 @@ static inline void vn_decode_vkGetPhysicalDeviceSparseImageFormatProperties2_arg
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * (args->pPropertyCount ? *args->pPropertyCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * iter_count);
if (!args->pProperties) return;
vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
for (uint32_t i = 0; i < (args->pPropertyCount ? *args->pPropertyCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseImageFormatProperties2_partial_temp(dec, &args->pProperties[i]);
} else {
vn_decode_array_size(dec, 0);
@ -8347,10 +8347,10 @@ static inline void vn_decode_vkEnumeratePhysicalDeviceGroups_args_temp(struct vn
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pPhysicalDeviceGroupProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pPhysicalDeviceGroupProperties) * (args->pPhysicalDeviceGroupCount ? *args->pPhysicalDeviceGroupCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pPhysicalDeviceGroupCount ? *args->pPhysicalDeviceGroupCount : 0));
args->pPhysicalDeviceGroupProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pPhysicalDeviceGroupProperties) * iter_count);
if (!args->pPhysicalDeviceGroupProperties) return;
vn_decode_array_size(dec, (args->pPhysicalDeviceGroupCount ? *args->pPhysicalDeviceGroupCount : 0));
for (uint32_t i = 0; i < (args->pPhysicalDeviceGroupCount ? *args->pPhysicalDeviceGroupCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPhysicalDeviceGroupProperties_partial_temp(dec, &args->pPhysicalDeviceGroupProperties[i]);
} else {
vn_decode_array_size(dec, 0);

@ -703,10 +703,10 @@ static inline void vn_decode_vkFlushMappedMemoryRanges_args_temp(struct vn_cs_de
vn_decode_VkDevice_lookup(dec, &args->device);
vn_decode_uint32_t(dec, &args->memoryRangeCount);
if (vn_peek_array_size(dec)) {
args->pMemoryRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pMemoryRanges) * args->memoryRangeCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->memoryRangeCount);
args->pMemoryRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pMemoryRanges) * iter_count);
if (!args->pMemoryRanges) return;
vn_decode_array_size(dec, args->memoryRangeCount);
for (uint32_t i = 0; i < args->memoryRangeCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkMappedMemoryRange_temp(dec, &((VkMappedMemoryRange *)args->pMemoryRanges)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -739,10 +739,10 @@ static inline void vn_decode_vkInvalidateMappedMemoryRanges_args_temp(struct vn_
vn_decode_VkDevice_lookup(dec, &args->device);
vn_decode_uint32_t(dec, &args->memoryRangeCount);
if (vn_peek_array_size(dec)) {
args->pMemoryRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pMemoryRanges) * args->memoryRangeCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->memoryRangeCount);
args->pMemoryRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pMemoryRanges) * iter_count);
if (!args->pMemoryRanges) return;
vn_decode_array_size(dec, args->memoryRangeCount);
for (uint32_t i = 0; i < args->memoryRangeCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkMappedMemoryRange_temp(dec, &((VkMappedMemoryRange *)args->pMemoryRanges)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -230,10 +230,10 @@ static inline void vn_decode_vkResetFences_args_temp(struct vn_cs_decoder *dec,
vn_decode_VkDevice_lookup(dec, &args->device);
vn_decode_uint32_t(dec, &args->fenceCount);
if (vn_peek_array_size(dec)) {
args->pFences = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pFences) * args->fenceCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->fenceCount);
args->pFences = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pFences) * iter_count);
if (!args->pFences) return;
vn_decode_array_size(dec, args->fenceCount);
for (uint32_t i = 0; i < args->fenceCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkFence_lookup(dec, &((VkFence *)args->pFences)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -287,10 +287,10 @@ static inline void vn_decode_vkWaitForFences_args_temp(struct vn_cs_decoder *dec
vn_decode_VkDevice_lookup(dec, &args->device);
vn_decode_uint32_t(dec, &args->fenceCount);
if (vn_peek_array_size(dec)) {
args->pFences = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pFences) * args->fenceCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->fenceCount);
args->pFences = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pFences) * iter_count);
if (!args->pFences) return;
vn_decode_array_size(dec, args->fenceCount);
for (uint32_t i = 0; i < args->fenceCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkFence_lookup(dec, &((VkFence *)args->pFences)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -108,10 +108,10 @@ vn_decode_VkFramebufferAttachmentsCreateInfo_self_temp(struct vn_cs_decoder *dec
/* skip val->{sType,pNext} */
vn_decode_uint32_t(dec, &val->attachmentImageInfoCount);
if (vn_peek_array_size(dec)) {
val->pAttachmentImageInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachmentImageInfos) * val->attachmentImageInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->attachmentImageInfoCount);
val->pAttachmentImageInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachmentImageInfos) * iter_count);
if (!val->pAttachmentImageInfos) return;
vn_decode_array_size(dec, val->attachmentImageInfoCount);
for (uint32_t i = 0; i < val->attachmentImageInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkFramebufferAttachmentImageInfo_temp(dec, &((VkFramebufferAttachmentImageInfo *)val->pAttachmentImageInfos)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -201,10 +201,10 @@ vn_decode_VkFramebufferCreateInfo_self_temp(struct vn_cs_decoder *dec, VkFramebu
vn_decode_VkRenderPass_lookup(dec, &val->renderPass);
vn_decode_uint32_t(dec, &val->attachmentCount);
if (vn_peek_array_size(dec)) {
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * val->attachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->attachmentCount);
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * iter_count);
if (!val->pAttachments) return;
vn_decode_array_size(dec, val->attachmentCount);
for (uint32_t i = 0; i < val->attachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkImageView_lookup(dec, &((VkImageView *)val->pAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -220,10 +220,10 @@ vn_decode_VkImageDrmFormatModifierExplicitCreateInfoEXT_self_temp(struct vn_cs_d
vn_decode_uint64_t(dec, &val->drmFormatModifier);
vn_decode_uint32_t(dec, &val->drmFormatModifierPlaneCount);
if (vn_peek_array_size(dec)) {
val->pPlaneLayouts = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pPlaneLayouts) * val->drmFormatModifierPlaneCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->drmFormatModifierPlaneCount);
val->pPlaneLayouts = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pPlaneLayouts) * iter_count);
if (!val->pPlaneLayouts) return;
vn_decode_array_size(dec, val->drmFormatModifierPlaneCount);
for (uint32_t i = 0; i < val->drmFormatModifierPlaneCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSubresourceLayout_temp(dec, &((VkSubresourceLayout *)val->pPlaneLayouts)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -495,10 +495,10 @@ vn_decode_VkBindImageMemoryDeviceGroupInfo_self_temp(struct vn_cs_decoder *dec,
}
vn_decode_uint32_t(dec, &val->splitInstanceBindRegionCount);
if (vn_peek_array_size(dec)) {
val->pSplitInstanceBindRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSplitInstanceBindRegions) * val->splitInstanceBindRegionCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->splitInstanceBindRegionCount);
val->pSplitInstanceBindRegions = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSplitInstanceBindRegions) * iter_count);
if (!val->pSplitInstanceBindRegions) return;
vn_decode_array_size(dec, val->splitInstanceBindRegionCount);
for (uint32_t i = 0; i < val->splitInstanceBindRegionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkRect2D_temp(dec, &((VkRect2D *)val->pSplitInstanceBindRegions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1146,10 +1146,10 @@ static inline void vn_decode_vkGetImageSparseMemoryRequirements_args_temp(struct
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pSparseMemoryRequirements = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pSparseMemoryRequirements) * (args->pSparseMemoryRequirementCount ? *args->pSparseMemoryRequirementCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pSparseMemoryRequirementCount ? *args->pSparseMemoryRequirementCount : 0));
args->pSparseMemoryRequirements = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pSparseMemoryRequirements) * iter_count);
if (!args->pSparseMemoryRequirements) return;
vn_decode_array_size(dec, (args->pSparseMemoryRequirementCount ? *args->pSparseMemoryRequirementCount : 0));
for (uint32_t i = 0; i < (args->pSparseMemoryRequirementCount ? *args->pSparseMemoryRequirementCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseImageMemoryRequirements_partial_temp(dec, &args->pSparseMemoryRequirements[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1303,10 +1303,10 @@ static inline void vn_decode_vkBindImageMemory2_args_temp(struct vn_cs_decoder *
vn_decode_VkDevice_lookup(dec, &args->device);
vn_decode_uint32_t(dec, &args->bindInfoCount);
if (vn_peek_array_size(dec)) {
args->pBindInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBindInfos) * args->bindInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->bindInfoCount);
args->pBindInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBindInfos) * iter_count);
if (!args->pBindInfos) return;
vn_decode_array_size(dec, args->bindInfoCount);
for (uint32_t i = 0; i < args->bindInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBindImageMemoryInfo_temp(dec, &((VkBindImageMemoryInfo *)args->pBindInfos)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1393,10 +1393,10 @@ static inline void vn_decode_vkGetImageSparseMemoryRequirements2_args_temp(struc
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pSparseMemoryRequirements = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pSparseMemoryRequirements) * (args->pSparseMemoryRequirementCount ? *args->pSparseMemoryRequirementCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pSparseMemoryRequirementCount ? *args->pSparseMemoryRequirementCount : 0));
args->pSparseMemoryRequirements = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pSparseMemoryRequirements) * iter_count);
if (!args->pSparseMemoryRequirements) return;
vn_decode_array_size(dec, (args->pSparseMemoryRequirementCount ? *args->pSparseMemoryRequirementCount : 0));
for (uint32_t i = 0; i < (args->pSparseMemoryRequirementCount ? *args->pSparseMemoryRequirementCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseImageMemoryRequirements2_partial_temp(dec, &args->pSparseMemoryRequirements[i]);
} else {
vn_decode_array_size(dec, 0);

@ -36,20 +36,20 @@ vn_decode_VkApplicationInfo_self_temp(struct vn_cs_decoder *dec, VkApplicationIn
{
/* skip val->{sType,pNext} */
if (vn_peek_array_size(dec)) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
const size_t string_size = vn_decode_array_size_unchecked(dec);
val->pApplicationName = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pApplicationName) * string_size);
if (!val->pApplicationName) return;
vn_decode_blob_array(dec, (char *)val->pApplicationName, string_size);
vn_decode_char_array(dec, (char *)val->pApplicationName, string_size);
} else {
vn_decode_array_size(dec, 0);
val->pApplicationName = NULL;
}
vn_decode_uint32_t(dec, &val->applicationVersion);
if (vn_peek_array_size(dec)) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
const size_t string_size = vn_decode_array_size_unchecked(dec);
val->pEngineName = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pEngineName) * string_size);
if (!val->pEngineName) return;
vn_decode_blob_array(dec, (char *)val->pEngineName, string_size);
vn_decode_char_array(dec, (char *)val->pEngineName, string_size);
} else {
vn_decode_array_size(dec, 0);
val->pEngineName = NULL;
@ -126,14 +126,14 @@ vn_decode_VkInstanceCreateInfo_self_temp(struct vn_cs_decoder *dec, VkInstanceCr
}
vn_decode_uint32_t(dec, &val->enabledLayerCount);
if (vn_peek_array_size(dec)) {
val->ppEnabledLayerNames = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledLayerNames) * val->enabledLayerCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->enabledLayerCount);
val->ppEnabledLayerNames = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledLayerNames) * iter_count);
if (!val->ppEnabledLayerNames) return;
vn_decode_array_size(dec, val->enabledLayerCount);
for (uint32_t i = 0; i < val->enabledLayerCount; i++) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
for (uint32_t i = 0; i < iter_count; i++) {
const size_t string_size = vn_decode_array_size_unchecked(dec);
((char **)val->ppEnabledLayerNames)[i] = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledLayerNames[i]) * string_size);
if (!val->ppEnabledLayerNames[i]) return;
vn_decode_blob_array(dec, ((char **)val->ppEnabledLayerNames)[i], string_size);
vn_decode_char_array(dec, ((char **)val->ppEnabledLayerNames)[i], string_size);
}
} else {
vn_decode_array_size(dec, 0);
@ -141,14 +141,14 @@ vn_decode_VkInstanceCreateInfo_self_temp(struct vn_cs_decoder *dec, VkInstanceCr
}
vn_decode_uint32_t(dec, &val->enabledExtensionCount);
if (vn_peek_array_size(dec)) {
val->ppEnabledExtensionNames = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledExtensionNames) * val->enabledExtensionCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->enabledExtensionCount);
val->ppEnabledExtensionNames = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledExtensionNames) * iter_count);
if (!val->ppEnabledExtensionNames) return;
vn_decode_array_size(dec, val->enabledExtensionCount);
for (uint32_t i = 0; i < val->enabledExtensionCount; i++) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
for (uint32_t i = 0; i < iter_count; i++) {
const size_t string_size = vn_decode_array_size_unchecked(dec);
((char **)val->ppEnabledExtensionNames)[i] = vn_cs_decoder_alloc_temp(dec, sizeof(*val->ppEnabledExtensionNames[i]) * string_size);
if (!val->ppEnabledExtensionNames[i]) return;
vn_decode_blob_array(dec, ((char **)val->ppEnabledExtensionNames)[i], string_size);
vn_decode_char_array(dec, ((char **)val->ppEnabledExtensionNames)[i], string_size);
}
} else {
vn_decode_array_size(dec, 0);
@ -305,10 +305,10 @@ static inline void vn_decode_vkEnumerateInstanceLayerProperties_args_temp(struct
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * (args->pPropertyCount ? *args->pPropertyCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * iter_count);
if (!args->pProperties) return;
vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
for (uint32_t i = 0; i < (args->pPropertyCount ? *args->pPropertyCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkLayerProperties_partial_temp(dec, &args->pProperties[i]);
} else {
vn_decode_array_size(dec, 0);
@ -341,10 +341,10 @@ static inline void vn_encode_vkEnumerateInstanceLayerProperties_reply(struct vn_
static inline void vn_decode_vkEnumerateInstanceExtensionProperties_args_temp(struct vn_cs_decoder *dec, struct vn_command_vkEnumerateInstanceExtensionProperties *args)
{
if (vn_peek_array_size(dec)) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
const size_t string_size = vn_decode_array_size_unchecked(dec);
args->pLayerName = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pLayerName) * string_size);
if (!args->pLayerName) return;
vn_decode_blob_array(dec, (char *)args->pLayerName, string_size);
vn_decode_char_array(dec, (char *)args->pLayerName, string_size);
} else {
vn_decode_array_size(dec, 0);
args->pLayerName = NULL;
@ -358,10 +358,10 @@ static inline void vn_decode_vkEnumerateInstanceExtensionProperties_args_temp(st
vn_cs_decoder_set_fatal(dec);
}
if (vn_peek_array_size(dec)) {
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * (args->pPropertyCount ? *args->pPropertyCount : 0));
const uint32_t iter_count = vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
args->pProperties = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pProperties) * iter_count);
if (!args->pProperties) return;
vn_decode_array_size(dec, (args->pPropertyCount ? *args->pPropertyCount : 0));
for (uint32_t i = 0; i < (args->pPropertyCount ? *args->pPropertyCount : 0); i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkExtensionProperties_partial_temp(dec, &args->pProperties[i]);
} else {
vn_decode_array_size(dec, 0);

@ -39,10 +39,10 @@ vn_decode_VkSpecializationInfo_temp(struct vn_cs_decoder *dec, VkSpecializationI
{
vn_decode_uint32_t(dec, &val->mapEntryCount);
if (vn_peek_array_size(dec)) {
val->pMapEntries = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pMapEntries) * val->mapEntryCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->mapEntryCount);
val->pMapEntries = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pMapEntries) * iter_count);
if (!val->pMapEntries) return;
vn_decode_array_size(dec, val->mapEntryCount);
for (uint32_t i = 0; i < val->mapEntryCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSpecializationMapEntry_temp(dec, &((VkSpecializationMapEntry *)val->pMapEntries)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -91,10 +91,10 @@ vn_decode_VkPipelineShaderStageCreateInfo_self_temp(struct vn_cs_decoder *dec, V
vn_decode_VkShaderStageFlagBits(dec, &val->stage);
vn_decode_VkShaderModule_lookup(dec, &val->module);
if (vn_peek_array_size(dec)) {
const size_t string_size = vn_decode_array_size(dec, UINT64_MAX);
const size_t string_size = vn_decode_array_size_unchecked(dec);
val->pName = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pName) * string_size);
if (!val->pName) return;
vn_decode_blob_array(dec, (char *)val->pName, string_size);
vn_decode_char_array(dec, (char *)val->pName, string_size);
} else {
vn_decode_array_size(dec, 0);
val->pName = NULL;
@ -208,10 +208,10 @@ vn_decode_VkPipelineVertexInputStateCreateInfo_self_temp(struct vn_cs_decoder *d
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->vertexBindingDescriptionCount);
if (vn_peek_array_size(dec)) {
val->pVertexBindingDescriptions = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pVertexBindingDescriptions) * val->vertexBindingDescriptionCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->vertexBindingDescriptionCount);
val->pVertexBindingDescriptions = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pVertexBindingDescriptions) * iter_count);
if (!val->pVertexBindingDescriptions) return;
vn_decode_array_size(dec, val->vertexBindingDescriptionCount);
for (uint32_t i = 0; i < val->vertexBindingDescriptionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkVertexInputBindingDescription_temp(dec, &((VkVertexInputBindingDescription *)val->pVertexBindingDescriptions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -219,10 +219,10 @@ vn_decode_VkPipelineVertexInputStateCreateInfo_self_temp(struct vn_cs_decoder *d
}
vn_decode_uint32_t(dec, &val->vertexAttributeDescriptionCount);
if (vn_peek_array_size(dec)) {
val->pVertexAttributeDescriptions = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pVertexAttributeDescriptions) * val->vertexAttributeDescriptionCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->vertexAttributeDescriptionCount);
val->pVertexAttributeDescriptions = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pVertexAttributeDescriptions) * iter_count);
if (!val->pVertexAttributeDescriptions) return;
vn_decode_array_size(dec, val->vertexAttributeDescriptionCount);
for (uint32_t i = 0; i < val->vertexAttributeDescriptionCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkVertexInputAttributeDescription_temp(dec, &((VkVertexInputAttributeDescription *)val->pVertexAttributeDescriptions)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -497,10 +497,10 @@ vn_decode_VkPipelineViewportStateCreateInfo_self_temp(struct vn_cs_decoder *dec,
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->viewportCount);
if (vn_peek_array_size(dec)) {
val->pViewports = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pViewports) * val->viewportCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->viewportCount);
val->pViewports = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pViewports) * iter_count);
if (!val->pViewports) return;
vn_decode_array_size(dec, val->viewportCount);
for (uint32_t i = 0; i < val->viewportCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkViewport_temp(dec, &((VkViewport *)val->pViewports)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -508,10 +508,10 @@ vn_decode_VkPipelineViewportStateCreateInfo_self_temp(struct vn_cs_decoder *dec,
}
vn_decode_uint32_t(dec, &val->scissorCount);
if (vn_peek_array_size(dec)) {
val->pScissors = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pScissors) * val->scissorCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->scissorCount);
val->pScissors = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pScissors) * iter_count);
if (!val->pScissors) return;
vn_decode_array_size(dec, val->scissorCount);
for (uint32_t i = 0; i < val->scissorCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkRect2D_temp(dec, &((VkRect2D *)val->pScissors)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -953,10 +953,10 @@ vn_decode_VkPipelineColorBlendStateCreateInfo_self_temp(struct vn_cs_decoder *de
vn_decode_VkLogicOp(dec, &val->logicOp);
vn_decode_uint32_t(dec, &val->attachmentCount);
if (vn_peek_array_size(dec)) {
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * val->attachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->attachmentCount);
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * iter_count);
if (!val->pAttachments) return;
vn_decode_array_size(dec, val->attachmentCount);
for (uint32_t i = 0; i < val->attachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPipelineColorBlendAttachmentState_temp(dec, &((VkPipelineColorBlendAttachmentState *)val->pAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1102,10 +1102,10 @@ vn_decode_VkGraphicsPipelineCreateInfo_self_temp(struct vn_cs_decoder *dec, VkGr
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->stageCount);
if (vn_peek_array_size(dec)) {
val->pStages = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pStages) * val->stageCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->stageCount);
val->pStages = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pStages) * iter_count);
if (!val->pStages) return;
vn_decode_array_size(dec, val->stageCount);
for (uint32_t i = 0; i < val->stageCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPipelineShaderStageCreateInfo_temp(dec, &((VkPipelineShaderStageCreateInfo *)val->pStages)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1320,10 +1320,10 @@ static inline void vn_decode_vkCreateGraphicsPipelines_args_temp(struct vn_cs_de
vn_decode_VkPipelineCache_lookup(dec, &args->pipelineCache);
vn_decode_uint32_t(dec, &args->createInfoCount);
if (vn_peek_array_size(dec)) {
args->pCreateInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCreateInfos) * args->createInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->createInfoCount);
args->pCreateInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCreateInfos) * iter_count);
if (!args->pCreateInfos) return;
vn_decode_array_size(dec, args->createInfoCount);
for (uint32_t i = 0; i < args->createInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkGraphicsPipelineCreateInfo_temp(dec, &((VkGraphicsPipelineCreateInfo *)args->pCreateInfos)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1335,10 +1335,10 @@ static inline void vn_decode_vkCreateGraphicsPipelines_args_temp(struct vn_cs_de
args->pAllocator = NULL;
}
if (vn_peek_array_size(dec)) {
args->pPipelines = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pPipelines) * args->createInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->createInfoCount);
args->pPipelines = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pPipelines) * iter_count);
if (!args->pPipelines) return;
vn_decode_array_size(dec, args->createInfoCount);
for (uint32_t i = 0; i < args->createInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPipeline(dec, &args->pPipelines[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1384,10 +1384,10 @@ static inline void vn_decode_vkCreateComputePipelines_args_temp(struct vn_cs_dec
vn_decode_VkPipelineCache_lookup(dec, &args->pipelineCache);
vn_decode_uint32_t(dec, &args->createInfoCount);
if (vn_peek_array_size(dec)) {
args->pCreateInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCreateInfos) * args->createInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->createInfoCount);
args->pCreateInfos = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pCreateInfos) * iter_count);
if (!args->pCreateInfos) return;
vn_decode_array_size(dec, args->createInfoCount);
for (uint32_t i = 0; i < args->createInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkComputePipelineCreateInfo_temp(dec, &((VkComputePipelineCreateInfo *)args->pCreateInfos)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1399,10 +1399,10 @@ static inline void vn_decode_vkCreateComputePipelines_args_temp(struct vn_cs_dec
args->pAllocator = NULL;
}
if (vn_peek_array_size(dec)) {
args->pPipelines = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pPipelines) * args->createInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->createInfoCount);
args->pPipelines = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pPipelines) * iter_count);
if (!args->pPipelines) return;
vn_decode_array_size(dec, args->createInfoCount);
for (uint32_t i = 0; i < args->createInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPipeline(dec, &args->pPipelines[i]);
} else {
vn_decode_array_size(dec, 0);

@ -210,10 +210,10 @@ static inline void vn_decode_vkMergePipelineCaches_args_temp(struct vn_cs_decode
vn_decode_VkPipelineCache_lookup(dec, &args->dstCache);
vn_decode_uint32_t(dec, &args->srcCacheCount);
if (vn_peek_array_size(dec)) {
args->pSrcCaches = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pSrcCaches) * args->srcCacheCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->srcCacheCount);
args->pSrcCaches = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pSrcCaches) * iter_count);
if (!args->pSrcCaches) return;
vn_decode_array_size(dec, args->srcCacheCount);
for (uint32_t i = 0; i < args->srcCacheCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPipelineCache_lookup(dec, &((VkPipelineCache *)args->pSrcCaches)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -50,10 +50,10 @@ vn_decode_VkPipelineLayoutCreateInfo_self_temp(struct vn_cs_decoder *dec, VkPipe
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->setLayoutCount);
if (vn_peek_array_size(dec)) {
val->pSetLayouts = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSetLayouts) * val->setLayoutCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->setLayoutCount);
val->pSetLayouts = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSetLayouts) * iter_count);
if (!val->pSetLayouts) return;
vn_decode_array_size(dec, val->setLayoutCount);
for (uint32_t i = 0; i < val->setLayoutCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkDescriptorSetLayout_lookup(dec, &((VkDescriptorSetLayout *)val->pSetLayouts)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -61,10 +61,10 @@ vn_decode_VkPipelineLayoutCreateInfo_self_temp(struct vn_cs_decoder *dec, VkPipe
}
vn_decode_uint32_t(dec, &val->pushConstantRangeCount);
if (vn_peek_array_size(dec)) {
val->pPushConstantRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pPushConstantRanges) * val->pushConstantRangeCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->pushConstantRangeCount);
val->pPushConstantRanges = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pPushConstantRanges) * iter_count);
if (!val->pPushConstantRanges) return;
vn_decode_array_size(dec, val->pushConstantRangeCount);
for (uint32_t i = 0; i < val->pushConstantRangeCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkPushConstantRange_temp(dec, &((VkPushConstantRange *)val->pPushConstantRanges)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -294,20 +294,20 @@ vn_decode_VkSubmitInfo_self_temp(struct vn_cs_decoder *dec, VkSubmitInfo *val)
/* skip val->{sType,pNext} */
vn_decode_uint32_t(dec, &val->waitSemaphoreCount);
if (vn_peek_array_size(dec)) {
val->pWaitSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pWaitSemaphores) * val->waitSemaphoreCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->waitSemaphoreCount);
val->pWaitSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pWaitSemaphores) * iter_count);
if (!val->pWaitSemaphores) return;
vn_decode_array_size(dec, val->waitSemaphoreCount);
for (uint32_t i = 0; i < val->waitSemaphoreCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSemaphore_lookup(dec, &((VkSemaphore *)val->pWaitSemaphores)[i]);
} else {
vn_decode_array_size(dec, 0);
val->pWaitSemaphores = NULL;
}
if (vn_peek_array_size(dec)) {
val->pWaitDstStageMask = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pWaitDstStageMask) * val->waitSemaphoreCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->waitSemaphoreCount);
val->pWaitDstStageMask = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pWaitDstStageMask) * iter_count);
if (!val->pWaitDstStageMask) return;
vn_decode_array_size(dec, val->waitSemaphoreCount);
for (uint32_t i = 0; i < val->waitSemaphoreCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkFlags(dec, &((VkPipelineStageFlags *)val->pWaitDstStageMask)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -315,10 +315,10 @@ vn_decode_VkSubmitInfo_self_temp(struct vn_cs_decoder *dec, VkSubmitInfo *val)
}
vn_decode_uint32_t(dec, &val->commandBufferCount);
if (vn_peek_array_size(dec)) {
val->pCommandBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pCommandBuffers) * val->commandBufferCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->commandBufferCount);
val->pCommandBuffers = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pCommandBuffers) * iter_count);
if (!val->pCommandBuffers) return;
vn_decode_array_size(dec, val->commandBufferCount);
for (uint32_t i = 0; i < val->commandBufferCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkCommandBuffer_lookup(dec, &((VkCommandBuffer *)val->pCommandBuffers)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -326,10 +326,10 @@ vn_decode_VkSubmitInfo_self_temp(struct vn_cs_decoder *dec, VkSubmitInfo *val)
}
vn_decode_uint32_t(dec, &val->signalSemaphoreCount);
if (vn_peek_array_size(dec)) {
val->pSignalSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSignalSemaphores) * val->signalSemaphoreCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->signalSemaphoreCount);
val->pSignalSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSignalSemaphores) * iter_count);
if (!val->pSignalSemaphores) return;
vn_decode_array_size(dec, val->signalSemaphoreCount);
for (uint32_t i = 0; i < val->signalSemaphoreCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSemaphore_lookup(dec, &((VkSemaphore *)val->pSignalSemaphores)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -430,10 +430,10 @@ vn_decode_VkSparseBufferMemoryBindInfo_temp(struct vn_cs_decoder *dec, VkSparseB
vn_decode_VkBuffer_lookup(dec, &val->buffer);
vn_decode_uint32_t(dec, &val->bindCount);
if (vn_peek_array_size(dec)) {
val->pBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBinds) * val->bindCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->bindCount);
val->pBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBinds) * iter_count);
if (!val->pBinds) return;
vn_decode_array_size(dec, val->bindCount);
for (uint32_t i = 0; i < val->bindCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseMemoryBind_temp(dec, &((VkSparseMemoryBind *)val->pBinds)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -460,10 +460,10 @@ vn_decode_VkSparseImageOpaqueMemoryBindInfo_temp(struct vn_cs_decoder *dec, VkSp
vn_decode_VkImage_lookup(dec, &val->image);
vn_decode_uint32_t(dec, &val->bindCount);
if (vn_peek_array_size(dec)) {
val->pBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBinds) * val->bindCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->bindCount);
val->pBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBinds) * iter_count);
if (!val->pBinds) return;
vn_decode_array_size(dec, val->bindCount);
for (uint32_t i = 0; i < val->bindCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseMemoryBind_temp(dec, &((VkSparseMemoryBind *)val->pBinds)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -514,10 +514,10 @@ vn_decode_VkSparseImageMemoryBindInfo_temp(struct vn_cs_decoder *dec, VkSparseIm
vn_decode_VkImage_lookup(dec, &val->image);
vn_decode_uint32_t(dec, &val->bindCount);
if (vn_peek_array_size(dec)) {
val->pBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBinds) * val->bindCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->bindCount);
val->pBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBinds) * iter_count);
if (!val->pBinds) return;
vn_decode_array_size(dec, val->bindCount);
for (uint32_t i = 0; i < val->bindCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseImageMemoryBind_temp(dec, &((VkSparseImageMemoryBind *)val->pBinds)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -640,10 +640,10 @@ vn_decode_VkBindSparseInfo_self_temp(struct vn_cs_decoder *dec, VkBindSparseInfo
/* skip val->{sType,pNext} */
vn_decode_uint32_t(dec, &val->waitSemaphoreCount);
if (vn_peek_array_size(dec)) {
val->pWaitSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pWaitSemaphores) * val->waitSemaphoreCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->waitSemaphoreCount);
val->pWaitSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pWaitSemaphores) * iter_count);
if (!val->pWaitSemaphores) return;
vn_decode_array_size(dec, val->waitSemaphoreCount);
for (uint32_t i = 0; i < val->waitSemaphoreCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSemaphore_lookup(dec, &((VkSemaphore *)val->pWaitSemaphores)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -651,10 +651,10 @@ vn_decode_VkBindSparseInfo_self_temp(struct vn_cs_decoder *dec, VkBindSparseInfo
}
vn_decode_uint32_t(dec, &val->bufferBindCount);
if (vn_peek_array_size(dec)) {
val->pBufferBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBufferBinds) * val->bufferBindCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->bufferBindCount);
val->pBufferBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pBufferBinds) * iter_count);
if (!val->pBufferBinds) return;
vn_decode_array_size(dec, val->bufferBindCount);
for (uint32_t i = 0; i < val->bufferBindCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseBufferMemoryBindInfo_temp(dec, &((VkSparseBufferMemoryBindInfo *)val->pBufferBinds)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -662,10 +662,10 @@ vn_decode_VkBindSparseInfo_self_temp(struct vn_cs_decoder *dec, VkBindSparseInfo
}
vn_decode_uint32_t(dec, &val->imageOpaqueBindCount);
if (vn_peek_array_size(dec)) {
val->pImageOpaqueBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pImageOpaqueBinds) * val->imageOpaqueBindCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->imageOpaqueBindCount);
val->pImageOpaqueBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pImageOpaqueBinds) * iter_count);
if (!val->pImageOpaqueBinds) return;
vn_decode_array_size(dec, val->imageOpaqueBindCount);
for (uint32_t i = 0; i < val->imageOpaqueBindCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseImageOpaqueMemoryBindInfo_temp(dec, &((VkSparseImageOpaqueMemoryBindInfo *)val->pImageOpaqueBinds)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -673,10 +673,10 @@ vn_decode_VkBindSparseInfo_self_temp(struct vn_cs_decoder *dec, VkBindSparseInfo
}
vn_decode_uint32_t(dec, &val->imageBindCount);
if (vn_peek_array_size(dec)) {
val->pImageBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pImageBinds) * val->imageBindCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->imageBindCount);
val->pImageBinds = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pImageBinds) * iter_count);
if (!val->pImageBinds) return;
vn_decode_array_size(dec, val->imageBindCount);
for (uint32_t i = 0; i < val->imageBindCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSparseImageMemoryBindInfo_temp(dec, &((VkSparseImageMemoryBindInfo *)val->pImageBinds)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -684,10 +684,10 @@ vn_decode_VkBindSparseInfo_self_temp(struct vn_cs_decoder *dec, VkBindSparseInfo
}
vn_decode_uint32_t(dec, &val->signalSemaphoreCount);
if (vn_peek_array_size(dec)) {
val->pSignalSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSignalSemaphores) * val->signalSemaphoreCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->signalSemaphoreCount);
val->pSignalSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSignalSemaphores) * iter_count);
if (!val->pSignalSemaphores) return;
vn_decode_array_size(dec, val->signalSemaphoreCount);
for (uint32_t i = 0; i < val->signalSemaphoreCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSemaphore_lookup(dec, &((VkSemaphore *)val->pSignalSemaphores)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -769,10 +769,10 @@ static inline void vn_decode_vkQueueSubmit_args_temp(struct vn_cs_decoder *dec,
vn_decode_VkQueue_lookup(dec, &args->queue);
vn_decode_uint32_t(dec, &args->submitCount);
if (vn_peek_array_size(dec)) {
args->pSubmits = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pSubmits) * args->submitCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->submitCount);
args->pSubmits = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pSubmits) * iter_count);
if (!args->pSubmits) return;
vn_decode_array_size(dec, args->submitCount);
for (uint32_t i = 0; i < args->submitCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSubmitInfo_temp(dec, &((VkSubmitInfo *)args->pSubmits)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -826,10 +826,10 @@ static inline void vn_decode_vkQueueBindSparse_args_temp(struct vn_cs_decoder *d
vn_decode_VkQueue_lookup(dec, &args->queue);
vn_decode_uint32_t(dec, &args->bindInfoCount);
if (vn_peek_array_size(dec)) {
args->pBindInfo = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBindInfo) * args->bindInfoCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->bindInfoCount);
args->pBindInfo = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pBindInfo) * iter_count);
if (!args->pBindInfo) return;
vn_decode_array_size(dec, args->bindInfoCount);
for (uint32_t i = 0; i < args->bindInfoCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkBindSparseInfo_temp(dec, &((VkBindSparseInfo *)args->pBindInfo)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -69,10 +69,10 @@ vn_decode_VkSubpassDescription_temp(struct vn_cs_decoder *dec, VkSubpassDescript
vn_decode_VkPipelineBindPoint(dec, &val->pipelineBindPoint);
vn_decode_uint32_t(dec, &val->inputAttachmentCount);
if (vn_peek_array_size(dec)) {
val->pInputAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pInputAttachments) * val->inputAttachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->inputAttachmentCount);
val->pInputAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pInputAttachments) * iter_count);
if (!val->pInputAttachments) return;
vn_decode_array_size(dec, val->inputAttachmentCount);
for (uint32_t i = 0; i < val->inputAttachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkAttachmentReference_temp(dec, &((VkAttachmentReference *)val->pInputAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -80,20 +80,20 @@ vn_decode_VkSubpassDescription_temp(struct vn_cs_decoder *dec, VkSubpassDescript
}
vn_decode_uint32_t(dec, &val->colorAttachmentCount);
if (vn_peek_array_size(dec)) {
val->pColorAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pColorAttachments) * val->colorAttachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->colorAttachmentCount);
val->pColorAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pColorAttachments) * iter_count);
if (!val->pColorAttachments) return;
vn_decode_array_size(dec, val->colorAttachmentCount);
for (uint32_t i = 0; i < val->colorAttachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkAttachmentReference_temp(dec, &((VkAttachmentReference *)val->pColorAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
val->pColorAttachments = NULL;
}
if (vn_peek_array_size(dec)) {
val->pResolveAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pResolveAttachments) * val->colorAttachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->colorAttachmentCount);
val->pResolveAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pResolveAttachments) * iter_count);
if (!val->pResolveAttachments) return;
vn_decode_array_size(dec, val->colorAttachmentCount);
for (uint32_t i = 0; i < val->colorAttachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkAttachmentReference_temp(dec, &((VkAttachmentReference *)val->pResolveAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -295,10 +295,10 @@ vn_decode_VkRenderPassInputAttachmentAspectCreateInfo_self_temp(struct vn_cs_dec
/* skip val->{sType,pNext} */
vn_decode_uint32_t(dec, &val->aspectReferenceCount);
if (vn_peek_array_size(dec)) {
val->pAspectReferences = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAspectReferences) * val->aspectReferenceCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->aspectReferenceCount);
val->pAspectReferences = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAspectReferences) * iter_count);
if (!val->pAspectReferences) return;
vn_decode_array_size(dec, val->aspectReferenceCount);
for (uint32_t i = 0; i < val->aspectReferenceCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkInputAttachmentAspectReference_temp(dec, &((VkInputAttachmentAspectReference *)val->pAspectReferences)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -395,10 +395,10 @@ vn_decode_VkRenderPassCreateInfo_self_temp(struct vn_cs_decoder *dec, VkRenderPa
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->attachmentCount);
if (vn_peek_array_size(dec)) {
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * val->attachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->attachmentCount);
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * iter_count);
if (!val->pAttachments) return;
vn_decode_array_size(dec, val->attachmentCount);
for (uint32_t i = 0; i < val->attachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkAttachmentDescription_temp(dec, &((VkAttachmentDescription *)val->pAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -406,10 +406,10 @@ vn_decode_VkRenderPassCreateInfo_self_temp(struct vn_cs_decoder *dec, VkRenderPa
}
vn_decode_uint32_t(dec, &val->subpassCount);
if (vn_peek_array_size(dec)) {
val->pSubpasses = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSubpasses) * val->subpassCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->subpassCount);
val->pSubpasses = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSubpasses) * iter_count);
if (!val->pSubpasses) return;
vn_decode_array_size(dec, val->subpassCount);
for (uint32_t i = 0; i < val->subpassCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSubpassDescription_temp(dec, &((VkSubpassDescription *)val->pSubpasses)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -417,10 +417,10 @@ vn_decode_VkRenderPassCreateInfo_self_temp(struct vn_cs_decoder *dec, VkRenderPa
}
vn_decode_uint32_t(dec, &val->dependencyCount);
if (vn_peek_array_size(dec)) {
val->pDependencies = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDependencies) * val->dependencyCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->dependencyCount);
val->pDependencies = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDependencies) * iter_count);
if (!val->pDependencies) return;
vn_decode_array_size(dec, val->dependencyCount);
for (uint32_t i = 0; i < val->dependencyCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSubpassDependency_temp(dec, &((VkSubpassDependency *)val->pDependencies)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -892,10 +892,10 @@ vn_decode_VkSubpassDescription2_self_temp(struct vn_cs_decoder *dec, VkSubpassDe
vn_decode_uint32_t(dec, &val->viewMask);
vn_decode_uint32_t(dec, &val->inputAttachmentCount);
if (vn_peek_array_size(dec)) {
val->pInputAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pInputAttachments) * val->inputAttachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->inputAttachmentCount);
val->pInputAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pInputAttachments) * iter_count);
if (!val->pInputAttachments) return;
vn_decode_array_size(dec, val->inputAttachmentCount);
for (uint32_t i = 0; i < val->inputAttachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkAttachmentReference2_temp(dec, &((VkAttachmentReference2 *)val->pInputAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -903,20 +903,20 @@ vn_decode_VkSubpassDescription2_self_temp(struct vn_cs_decoder *dec, VkSubpassDe
}
vn_decode_uint32_t(dec, &val->colorAttachmentCount);
if (vn_peek_array_size(dec)) {
val->pColorAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pColorAttachments) * val->colorAttachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->colorAttachmentCount);
val->pColorAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pColorAttachments) * iter_count);
if (!val->pColorAttachments) return;
vn_decode_array_size(dec, val->colorAttachmentCount);
for (uint32_t i = 0; i < val->colorAttachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkAttachmentReference2_temp(dec, &((VkAttachmentReference2 *)val->pColorAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
val->pColorAttachments = NULL;
}
if (vn_peek_array_size(dec)) {
val->pResolveAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pResolveAttachments) * val->colorAttachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->colorAttachmentCount);
val->pResolveAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pResolveAttachments) * iter_count);
if (!val->pResolveAttachments) return;
vn_decode_array_size(dec, val->colorAttachmentCount);
for (uint32_t i = 0; i < val->colorAttachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkAttachmentReference2_temp(dec, &((VkAttachmentReference2 *)val->pResolveAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1092,10 +1092,10 @@ vn_decode_VkRenderPassCreateInfo2_self_temp(struct vn_cs_decoder *dec, VkRenderP
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->attachmentCount);
if (vn_peek_array_size(dec)) {
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * val->attachmentCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->attachmentCount);
val->pAttachments = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pAttachments) * iter_count);
if (!val->pAttachments) return;
vn_decode_array_size(dec, val->attachmentCount);
for (uint32_t i = 0; i < val->attachmentCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkAttachmentDescription2_temp(dec, &((VkAttachmentDescription2 *)val->pAttachments)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1103,10 +1103,10 @@ vn_decode_VkRenderPassCreateInfo2_self_temp(struct vn_cs_decoder *dec, VkRenderP
}
vn_decode_uint32_t(dec, &val->subpassCount);
if (vn_peek_array_size(dec)) {
val->pSubpasses = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSubpasses) * val->subpassCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->subpassCount);
val->pSubpasses = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSubpasses) * iter_count);
if (!val->pSubpasses) return;
vn_decode_array_size(dec, val->subpassCount);
for (uint32_t i = 0; i < val->subpassCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSubpassDescription2_temp(dec, &((VkSubpassDescription2 *)val->pSubpasses)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -1114,10 +1114,10 @@ vn_decode_VkRenderPassCreateInfo2_self_temp(struct vn_cs_decoder *dec, VkRenderP
}
vn_decode_uint32_t(dec, &val->dependencyCount);
if (vn_peek_array_size(dec)) {
val->pDependencies = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDependencies) * val->dependencyCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->dependencyCount);
val->pDependencies = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pDependencies) * iter_count);
if (!val->pDependencies) return;
vn_decode_array_size(dec, val->dependencyCount);
for (uint32_t i = 0; i < val->dependencyCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSubpassDependency2_temp(dec, &((VkSubpassDependency2 *)val->pDependencies)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -180,10 +180,10 @@ vn_decode_VkSemaphoreWaitInfo_self_temp(struct vn_cs_decoder *dec, VkSemaphoreWa
vn_decode_VkFlags(dec, &val->flags);
vn_decode_uint32_t(dec, &val->semaphoreCount);
if (vn_peek_array_size(dec)) {
val->pSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSemaphores) * val->semaphoreCount);
const uint32_t iter_count = vn_decode_array_size(dec, val->semaphoreCount);
val->pSemaphores = vn_cs_decoder_alloc_temp(dec, sizeof(*val->pSemaphores) * iter_count);
if (!val->pSemaphores) return;
vn_decode_array_size(dec, val->semaphoreCount);
for (uint32_t i = 0; i < val->semaphoreCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkSemaphore_lookup(dec, &((VkSemaphore *)val->pSemaphores)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -60,11 +60,11 @@ static inline void
vn_encode_VkLayerProperties(struct vn_cs_encoder *enc, const VkLayerProperties *val)
{
vn_encode_array_size(enc, VK_MAX_EXTENSION_NAME_SIZE);
vn_encode_blob_array(enc, val->layerName, VK_MAX_EXTENSION_NAME_SIZE);
vn_encode_char_array(enc, val->layerName, VK_MAX_EXTENSION_NAME_SIZE);
vn_encode_uint32_t(enc, &val->specVersion);
vn_encode_uint32_t(enc, &val->implementationVersion);
vn_encode_array_size(enc, VK_MAX_DESCRIPTION_SIZE);
vn_encode_blob_array(enc, val->description, VK_MAX_DESCRIPTION_SIZE);
vn_encode_char_array(enc, val->description, VK_MAX_DESCRIPTION_SIZE);
}
static inline void
@ -82,7 +82,7 @@ static inline void
vn_encode_VkExtensionProperties(struct vn_cs_encoder *enc, const VkExtensionProperties *val)
{
vn_encode_array_size(enc, VK_MAX_EXTENSION_NAME_SIZE);
vn_encode_blob_array(enc, val->extensionName, VK_MAX_EXTENSION_NAME_SIZE);
vn_encode_char_array(enc, val->extensionName, VK_MAX_EXTENSION_NAME_SIZE);
vn_encode_uint32_t(enc, &val->specVersion);
}
@ -91,7 +91,7 @@ vn_decode_VkExtensionProperties_temp(struct vn_cs_decoder *dec, VkExtensionPrope
{
{
const size_t array_size = vn_decode_array_size(dec, VK_MAX_EXTENSION_NAME_SIZE);
vn_decode_blob_array(dec, val->extensionName, array_size);
vn_decode_char_array(dec, val->extensionName, array_size);
}
vn_decode_uint32_t(dec, &val->specVersion);
}

@ -324,10 +324,10 @@ static inline void vn_decode_vkExecuteCommandStreamsMESA_args_temp(struct vn_cs_
{
vn_decode_uint32_t(dec, &args->streamCount);
if (vn_peek_array_size(dec)) {
args->pStreams = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pStreams) * args->streamCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->streamCount);
args->pStreams = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pStreams) * iter_count);
if (!args->pStreams) return;
vn_decode_array_size(dec, args->streamCount);
for (uint32_t i = 0; i < args->streamCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkCommandStreamDescriptionMESA_temp(dec, &((VkCommandStreamDescriptionMESA *)args->pStreams)[i]);
} else {
vn_decode_array_size(dec, 0);
@ -344,10 +344,10 @@ static inline void vn_decode_vkExecuteCommandStreamsMESA_args_temp(struct vn_cs_
}
vn_decode_uint32_t(dec, &args->dependencyCount);
if (vn_peek_array_size(dec)) {
args->pDependencies = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDependencies) * args->dependencyCount);
const uint32_t iter_count = vn_decode_array_size(dec, args->dependencyCount);
args->pDependencies = vn_cs_decoder_alloc_temp(dec, sizeof(*args->pDependencies) * iter_count);
if (!args->pDependencies) return;
vn_decode_array_size(dec, args->dependencyCount);
for (uint32_t i = 0; i < args->dependencyCount; i++)
for (uint32_t i = 0; i < iter_count; i++)
vn_decode_VkCommandStreamDependencyMESA_temp(dec, &((VkCommandStreamDependencyMESA *)args->pDependencies)[i]);
} else {
vn_decode_array_size(dec, 0);

@ -137,6 +137,25 @@ vn_decode_blob_array(struct vn_cs_decoder *dec, void *val, size_t size)
vn_decode(dec, (size + 3) & ~3, val, size);
}
/* string */
static inline void
vn_encode_char_array(struct vn_cs_encoder *enc, const char *val, size_t size)
{
assert(size && strlen(val) < size);
vn_encode_blob_array(enc, val, size);
}
static inline void
vn_decode_char_array(struct vn_cs_decoder *dec, char *val, size_t size)
{
vn_decode_blob_array(dec, val, size);
if (size)
val[size - 1] = '\0';
else
vn_cs_decoder_set_fatal(dec);
}
/* array size (uint64_t) */
static inline void
@ -146,17 +165,25 @@ vn_encode_array_size(struct vn_cs_encoder *enc, uint64_t size)
}
static inline uint64_t
vn_decode_array_size(struct vn_cs_decoder *dec, uint64_t max_size)
vn_decode_array_size(struct vn_cs_decoder *dec, uint64_t expected_size)
{
uint64_t size;
vn_decode_uint64_t(dec, &size);
if (size > max_size) {
if (size != expected_size) {
vn_cs_decoder_set_fatal(dec);
size = 0;
}
return size;
}
static inline uint64_t
vn_decode_array_size_unchecked(struct vn_cs_decoder *dec)
{
uint64_t size;
vn_decode_uint64_t(dec, &size);
return size;
}
static inline uint64_t
vn_peek_array_size(struct vn_cs_decoder *dec)
{
@ -177,7 +204,7 @@ vn_encode_simple_pointer(struct vn_cs_encoder *enc, const void *val)
static inline bool
vn_decode_simple_pointer(struct vn_cs_decoder *dec)
{
return vn_decode_array_size(dec, 1);
return vn_decode_array_size_unchecked(dec);
}
/* uint32_t */

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