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gerrit-public.fairphone.software / platform / external / vulkan-validation-layers / c779c7e8b7c586779562de776e8af4ff070b36e4 / . / layers / mem_tracker.cpp
blob: de5ef1974efa6655b37d44a043f871faa909aca1 [file] [log] [blame]
/*
* Vulkan
*
* Copyright (C) 2015 LunarG, Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
*/
#include <inttypes.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <list>
#include <map>
#include <vector>
using namespace std;
#include "loader_platform.h"
#include "vk_dispatch_table_helper.h"
#include "vk_struct_string_helper_cpp.h"
#include "mem_tracker.h"
#include "layers_config.h"
// The following is #included again to catch certain OS-specific functions
// being used:
#include "loader_platform.h"
#include "layers_msg.h"
static VkLayerDispatchTable nextTable;
static VkBaseLayerObject *pCurObj;
static LOADER_PLATFORM_THREAD_ONCE_DECLARATION(g_initOnce);
// TODO : This can be much smarter, using separate locks for separate global data
static int globalLockInitialized = 0;
static loader_platform_thread_mutex globalLock;
#define MAX_BINDING 0xFFFFFFFF
map<VkCmdBuffer, MT_CB_INFO*> cbMap;
map<VkDeviceMemory, MT_MEM_OBJ_INFO*> memObjMap;
map<VkObject, MT_OBJ_INFO*> objectMap;
map<uint64_t, MT_FENCE_INFO*> fenceMap; // Map fenceId to fence info
map<VkQueue, MT_QUEUE_INFO*> queueMap;
map<VkSwapChainWSI, MT_SWAP_CHAIN_INFO*> swapChainMap;
// TODO : Add per-device fence completion
static uint64_t g_currentFenceId = 1;
static VkDevice globalDevice = NULL;
// Add new queue for this device to map container
static void addQueueInfo(const VkQueue queue)
{
MT_QUEUE_INFO* pInfo = new MT_QUEUE_INFO;
pInfo->lastRetiredId = 0;
pInfo->lastSubmittedId = 0;
queueMap[queue] = pInfo;
}
static void deleteQueueInfoList(
void)
{
// Process queue list, cleaning up each entry before deleting
if (queueMap.size() <= 0)
return;
for (map<VkQueue, MT_QUEUE_INFO*>::iterator ii=queueMap.begin(); ii!=queueMap.end(); ++ii) {
(*ii).second->pQueueCmdBuffers.clear();
}
queueMap.clear();
}
static void addSwapChainInfo(
const VkSwapChainWSI swapChain)
{
MT_SWAP_CHAIN_INFO* pInfo = new MT_SWAP_CHAIN_INFO;
swapChainMap[swapChain] = pInfo;
}
// Add new CBInfo for this cb to map container
static void addCBInfo(
const VkCmdBuffer cb)
{
MT_CB_INFO* pInfo = new MT_CB_INFO;
memset(pInfo, 0, (sizeof(MT_CB_INFO) - sizeof(list<VkDeviceMemory>)));
pInfo->cmdBuffer = cb;
cbMap[cb] = pInfo;
}
// Return ptr to Info in CB map, or NULL if not found
static MT_CB_INFO* getCBInfo(
const VkCmdBuffer cb)
{
MT_CB_INFO* pCBInfo = NULL;
if (cbMap.find(cb) != cbMap.end()) {
pCBInfo = cbMap[cb];
}
return pCBInfo;
}
// Return object info for 'object' or return NULL if no info exists
static MT_OBJ_INFO* getObjectInfo(
const VkObject object)
{
MT_OBJ_INFO* pObjInfo = NULL;
if (objectMap.find(object) != objectMap.end()) {
pObjInfo = objectMap[object];
}
return pObjInfo;
}
static MT_OBJ_INFO* addObjectInfo(
VkObject object,
VkStructureType sType,
const void *pCreateInfo,
const int struct_size,
const char *name_prefix)
{
MT_OBJ_INFO* pInfo = new MT_OBJ_INFO;
memset(pInfo, 0, sizeof(MT_OBJ_INFO));
memcpy(&pInfo->create_info, pCreateInfo, struct_size);
sprintf(pInfo->object_name, "%s_%p", name_prefix, object);
pInfo->object = object;
pInfo->ref_count = 1;
pInfo->sType = sType;
objectMap[object] = pInfo;
return pInfo;
}
// Add a fence, creating one if necessary to our list of fences/fenceIds
static uint64_t addFenceInfo(
VkFence fence,
VkQueue queue)
{
// Create fence object
MT_FENCE_INFO* pFenceInfo = new MT_FENCE_INFO;
MT_QUEUE_INFO* pQueueInfo = queueMap[queue];
uint64_t fenceId = g_currentFenceId++;
memset(pFenceInfo, 0, sizeof(MT_FENCE_INFO));
// If no fence, create an internal fence to track the submissions
if (fence == NULL) {
VkFenceCreateInfo fci;
fci.sType = VK_STRUCTURE_TYPE_FENCE_CREATE_INFO;
fci.pNext = NULL;
fci.flags = static_cast<VkFenceCreateFlags>(0);
nextTable.CreateFence(globalDevice, &fci, &pFenceInfo->fence);
addObjectInfo(pFenceInfo->fence, fci.sType, &fci, sizeof(VkFenceCreateInfo), "internalFence");
pFenceInfo->localFence = VK_TRUE;
} else {
// Validate that fence is in UNSIGNALED state
MT_OBJ_INFO* pObjectInfo = getObjectInfo(fence);
if (pObjectInfo != NULL) {
if (pObjectInfo->create_info.fence_create_info.flags & VK_FENCE_CREATE_SIGNALED_BIT) {
char str[1024];
sprintf(str, "Fence %p submitted in SIGNALED state. Fences must be reset before being submitted", fence);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, fence, 0, MEMTRACK_INVALID_FENCE_STATE, "MEM", str);
}
}
pFenceInfo->localFence = VK_FALSE;
pFenceInfo->fence = fence;
}
pFenceInfo->queue = queue;
fenceMap[fenceId] = pFenceInfo;
// Update most recently submitted fenceId for Queue
pQueueInfo->lastSubmittedId = fenceId;
return fenceId;
}
// Remove a fenceInfo from our list of fences/fenceIds
static void deleteFenceInfo(
uint64_t fenceId)
{
if (fenceId != 0) {
if (fenceMap.find(fenceId) != fenceMap.end()) {
map<uint64_t, MT_FENCE_INFO*>::iterator item;
MT_FENCE_INFO* pDelInfo = fenceMap[fenceId];
if (pDelInfo != NULL) {
if (pDelInfo->localFence == VK_TRUE) {
nextTable.DestroyObject(globalDevice, VK_OBJECT_TYPE_FENCE, pDelInfo->fence);
}
delete pDelInfo;
}
item = fenceMap.find(fenceId);
fenceMap.erase(item);
}
}
}
// Search through list for this fence, deleting all items before it (with lower IDs) and updating lastRetiredId
static void updateFenceTracking(
VkFence fence)
{
MT_FENCE_INFO *pCurFenceInfo = NULL;
uint64_t fenceId = 0;
VkQueue queue = NULL;
bool found = false;
if (fenceMap.size() <= 0)
return;
for (map<uint64_t, MT_FENCE_INFO*>::iterator ii=fenceMap.begin(); !found && ii!=fenceMap.end(); ++ii) {
if ((*ii).second != NULL) {
if (fence == ((*ii).second)->fence) {
queue = ((*ii).second)->queue;
MT_QUEUE_INFO *pQueueInfo = queueMap[queue];
pQueueInfo->lastRetiredId = (*ii).first;
found = true;
} else {
deleteFenceInfo((*ii).first);
}
// Update fence state in fenceCreateInfo structure
MT_OBJ_INFO* pObjectInfo = getObjectInfo(fence);
if (pObjectInfo != NULL) {
pObjectInfo->create_info.fence_create_info.flags =
static_cast<VkFenceCreateFlags>(
pObjectInfo->create_info.fence_create_info.flags | VK_FENCE_CREATE_SIGNALED_BIT);
}
}
}
}
// Utility function that determines if a fenceId has been retired yet
static bool32_t fenceRetired(
uint64_t fenceId)
{
bool32_t result = VK_FALSE;
if (fenceMap.find(fenceId) != fenceMap.end()) {
MT_FENCE_INFO* pFenceInfo = fenceMap[fenceId];
MT_QUEUE_INFO* pQueueInfo = queueMap[pFenceInfo->queue];
if (fenceId <= pQueueInfo->lastRetiredId)
{
result = VK_TRUE;
}
} else { // If not in list, fence has been retired and deleted
result = VK_TRUE;
}
return result;
}
// Return the fence associated with a fenceId
static VkFence getFenceFromId(
uint64_t fenceId)
{
VkFence fence = NULL;
if (fenceId != 0) {
// Search for an item with this fenceId
if (fenceMap.find(fenceId) != fenceMap.end()) {
MT_FENCE_INFO* pFenceInfo = fenceMap[fenceId];
if (pFenceInfo != NULL) {
MT_QUEUE_INFO* pQueueInfo = queueMap[pFenceInfo->queue];
if (fenceId > pQueueInfo->lastRetiredId) {
fence = pFenceInfo->fence;
}
}
}
}
return fence;
}
// Helper routine that updates the fence list for a specific queue to all-retired
static void retireQueueFences(
VkQueue queue)
{
MT_QUEUE_INFO *pQueueInfo = queueMap[queue];
pQueueInfo->lastRetiredId = pQueueInfo->lastSubmittedId;
// Set Queue's lastRetired to lastSubmitted, free items in queue's fence list
map<uint64_t, MT_FENCE_INFO*>::iterator it = fenceMap.begin();
map<uint64_t, MT_FENCE_INFO*>::iterator temp;
while (fenceMap.size() > 0 && it != fenceMap.end()) {
if ((((*it).second) != NULL) && ((*it).second)->queue == queue) {
temp = it;
++temp;
deleteFenceInfo((*it).first);
it = temp;
} else {
++it;
}
}
}
// Helper routine that updates fence list for all queues to all-retired
static void retireDeviceFences(
VkDevice device)
{
// Process each queue for device
// TODO: Add multiple device support
if (queueMap.size() <= 0)
return;
for (map<VkQueue, MT_QUEUE_INFO*>::iterator ii=queueMap.begin(); ii!=queueMap.end(); ++ii) {
retireQueueFences((*ii).first);
}
}
// Returns True if a memory reference is present in a Queue's memory reference list
// Queue is validated by caller
static bool32_t checkMemRef(
VkQueue queue,
VkDeviceMemory mem)
{
bool32_t result = VK_FALSE;
list<VkDeviceMemory>::iterator it;
MT_QUEUE_INFO *pQueueInfo = queueMap[queue];
if (pQueueInfo->pMemRefList.size() <= 0)
return result;
for (it = pQueueInfo->pMemRefList.begin(); it != pQueueInfo->pMemRefList.end(); ++it) {
if ((*it) == mem) {
result = VK_TRUE;
break;
}
}
return result;
}
static bool32_t validateQueueMemRefs(
VkQueue queue,
uint32_t cmdBufferCount,
const VkCmdBuffer *pCmdBuffers)
{
bool32_t result = VK_TRUE;
// Verify Queue
MT_QUEUE_INFO *pQueueInfo = queueMap[queue];
if (pQueueInfo == NULL) {
char str[1024];
sprintf(str, "Unknown Queue %p specified in vkQueueSubmit", queue);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, queue, 0, MEMTRACK_INVALID_QUEUE, "MEM", str);
}
else {
// Iterate through all CBs in pCmdBuffers
for (uint32_t i = 0; i < cmdBufferCount; i++) {
MT_CB_INFO* pCBInfo = getCBInfo(pCmdBuffers[i]);
if (!pCBInfo) {
char str[1024];
sprintf(str, "Unable to find info for CB %p in order to check memory references in "
"vkQueueSubmit for queue %p",
(void*)pCmdBuffers[i], queue);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, pCmdBuffers[i], 0, MEMTRACK_INVALID_CB, "MEM", str);
result = VK_FALSE;
} else {
// Validate that all actual references are accounted for in pMemRefs
if (pCBInfo->pMemObjList.size() > 0) {
for (list<VkDeviceMemory>::iterator it = pCBInfo->pMemObjList.begin(); it != pCBInfo->pMemObjList.end(); ++it) {
// Search for each memref in queues memreflist.
if (checkMemRef(queue, *it)) {
char str[1024];
sprintf(str, "Found Mem Obj %p binding to CB %p for queue %p", (*it), pCmdBuffers[i], queue);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, pCmdBuffers[i], 0, MEMTRACK_NONE, "MEM", str);
}
else {
char str[1024];
sprintf(str, "Queue %p Memory reference list for Command Buffer %p is missing ref to mem obj %p",
queue, pCmdBuffers[i], (*it));
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, pCmdBuffers[i], 0, MEMTRACK_INVALID_MEM_REF, "MEM", str);
result = VK_FALSE;
}
}
}
}
}
if (result == VK_TRUE) {
char str[1024];
sprintf(str, "Verified all memory dependencies for Queue %p are included in pMemRefs list", queue);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, queue, 0, MEMTRACK_NONE, "MEM", str);
// TODO : Could report mem refs in pMemRefs that AREN'T in mem list, that would be primarily informational
// Currently just noting that there is a difference
}
}
return result;
}
// Return ptr to info in map container containing mem, or NULL if not found
// Calls to this function should be wrapped in mutex
static MT_MEM_OBJ_INFO* getMemObjInfo(
const VkDeviceMemory mem)
{
MT_MEM_OBJ_INFO* pMemObjInfo = NULL;
if (memObjMap.find(mem) != memObjMap.end()) {
pMemObjInfo = memObjMap[mem];
}
return pMemObjInfo;
}
static void addMemObjInfo(
const VkDeviceMemory mem,
const VkMemoryAllocInfo *pAllocInfo)
{
MT_MEM_OBJ_INFO* pInfo = new MT_MEM_OBJ_INFO;
pInfo->refCount = 0;
memset(&pInfo->allocInfo, 0, sizeof(VkMemoryAllocInfo));
if (pAllocInfo) { // MEM alloc created by vkCreateSwapChainWSI() doesn't have alloc info struct
memcpy(&pInfo->allocInfo, pAllocInfo, sizeof(VkMemoryAllocInfo));
// TODO: Update for real hardware, actually process allocation info structures
pInfo->allocInfo.pNext = NULL;
}
pInfo->mem = mem;
memObjMap[mem] = pInfo;
}
// Find CB Info and add mem binding to list container
// Find Mem Obj Info and add CB binding to list container
static bool32_t updateCBBinding(
const VkCmdBuffer cb,
const VkDeviceMemory mem)
{
bool32_t result = VK_TRUE;
// First update CB binding in MemObj mini CB list
MT_MEM_OBJ_INFO* pMemInfo = getMemObjInfo(mem);
if (!pMemInfo) {
char str[1024];
sprintf(str, "Trying to bind mem obj %p to CB %p but no info for that mem obj.\n "
"Was it correctly allocated? Did it already get freed?", mem, cb);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cb, 0, MEMTRACK_INVALID_MEM_OBJ, "MEM", str);
result = VK_FALSE;
} else {
// Search for cmd buffer object in memory object's binding list
bool32_t found = VK_FALSE;
if (pMemInfo->pCmdBufferBindings.size() > 0) {
for (list<VkCmdBuffer>::iterator it = pMemInfo->pCmdBufferBindings.begin(); it != pMemInfo->pCmdBufferBindings.end(); ++it) {
if ((*it) == cb) {
found = VK_TRUE;
break;
}
}
}
// If not present, add to list
if (found == VK_FALSE) {
pMemInfo->pCmdBufferBindings.push_front(cb);
pMemInfo->refCount++;
}
// Now update CBInfo's Mem binding list
MT_CB_INFO* pCBInfo = getCBInfo(cb);
if (!pCBInfo) {
char str[1024];
sprintf(str, "Trying to bind mem obj %p to CB %p but no info for that CB. Was it CB incorrectly destroyed?", mem, cb);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cb, 0, MEMTRACK_INVALID_MEM_OBJ, "MEM", str);
result = VK_FALSE;
} else {
// Search for memory object in cmd buffer's binding list
bool32_t found = VK_FALSE;
if (pCBInfo->pMemObjList.size() > 0) {
for (list<VkDeviceMemory>::iterator it = pCBInfo->pMemObjList.begin(); it != pCBInfo->pMemObjList.end(); ++it) {
if ((*it) == mem) {
found = VK_TRUE;
break;
}
}
}
// If not present, add to list
if (found == VK_FALSE) {
pCBInfo->pMemObjList.push_front(mem);
}
}
}
return result;
}
// Clear the CB Binding for mem
// Calls to this function should be wrapped in mutex
static void clearCBBinding(
const VkCmdBuffer cb,
const VkDeviceMemory mem)
{
MT_MEM_OBJ_INFO* pInfo = getMemObjInfo(mem);
// TODO : Having this check is not ideal, really if memInfo was deleted,
// its CB bindings should be cleared and then freeCBBindings wouldn't call
// us here with stale mem objs
if (pInfo) {
pInfo->pCmdBufferBindings.remove(cb);
pInfo->refCount--;
}
}
// Free bindings related to CB
static bool32_t freeCBBindings(
const VkCmdBuffer cb)
{
bool32_t result = VK_TRUE;
MT_CB_INFO* pCBInfo = getCBInfo(cb);
if (!pCBInfo) {
char str[1024];
sprintf(str, "Unable to find global CB info %p for deletion", cb);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cb, 0, MEMTRACK_INVALID_CB, "MEM", str);
result = VK_FALSE;
} else {
if (!fenceRetired(pCBInfo->fenceId)) {
deleteFenceInfo(pCBInfo->fenceId);
}
if (pCBInfo->pMemObjList.size() > 0) {
list<VkDeviceMemory> mem_obj_list = pCBInfo->pMemObjList;
for (list<VkDeviceMemory>::iterator it=mem_obj_list.begin(); it!=mem_obj_list.end(); ++it) {
clearCBBinding(cb, (*it));
}
}
pCBInfo->pMemObjList.clear();
}
return result;
}
// Delete CBInfo from list along with all of it's mini MemObjInfo
// and also clear mem references to CB
// TODO : When should this be called? There's no Destroy of CBs that I see
static bool32_t deleteCBInfo(
const VkCmdBuffer cb)
{
bool32_t result = VK_TRUE;
result = freeCBBindings(cb);
// Delete the CBInfo info
if (result == VK_TRUE) {
if (cbMap.find(cb) != cbMap.end()) {
MT_CB_INFO* pDelInfo = cbMap[cb];
delete pDelInfo;
cbMap.erase(cb);
}
}
return result;
}
// Delete the entire CB list
static bool32_t deleteCBInfoList(
void)
{
bool32_t result = VK_TRUE;
if (cbMap.size() <= 0)
return result;
for (map<VkCmdBuffer, MT_CB_INFO*>::iterator ii=cbMap.begin(); ii!=cbMap.end(); ++ii) {
freeCBBindings((*ii).first);
delete (*ii).second;
}
return result;
}
// For given MemObjInfo, report Obj & CB bindings
static void reportMemReferencesAndCleanUp(
MT_MEM_OBJ_INFO* pMemObjInfo)
{
size_t cmdBufRefCount = pMemObjInfo->pCmdBufferBindings.size();
size_t objRefCount = pMemObjInfo->pObjBindings.size();
if ((pMemObjInfo->pCmdBufferBindings.size() + pMemObjInfo->pObjBindings.size()) != 0) {
char str[1024];
sprintf(str, "Attempting to free memory object %p which still contains %lu references",
pMemObjInfo->mem, (cmdBufRefCount + objRefCount));
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, pMemObjInfo->mem, 0, MEMTRACK_INTERNAL_ERROR, "MEM", str);
}
if (cmdBufRefCount > 0 && pMemObjInfo->pCmdBufferBindings.size() > 0) {
for (list<VkCmdBuffer>::const_iterator it = pMemObjInfo->pCmdBufferBindings.begin(); it != pMemObjInfo->pCmdBufferBindings.end(); ++it) {
char str[1024];
sprintf(str, "Command Buffer %p still has a reference to mem obj %p", (*it), pMemObjInfo->mem);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, (*it), 0, MEMTRACK_NONE, "MEM", str);
}
// Clear the list of hanging references
pMemObjInfo->pCmdBufferBindings.clear();
}
if (objRefCount > 0 && pMemObjInfo->pObjBindings.size() > 0) {
for (list<VkObject>::const_iterator it = pMemObjInfo->pObjBindings.begin(); it != pMemObjInfo->pObjBindings.end(); ++it) {
char str[1024];
sprintf(str, "VK Object %p still has a reference to mem obj %p", (*it), pMemObjInfo->mem);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, (*it), 0, MEMTRACK_NONE, "MEM", str);
}
// Clear the list of hanging references
pMemObjInfo->pObjBindings.clear();
}
}
static void deleteMemObjInfo(
VkDeviceMemory mem)
{
if (memObjMap.find(mem) != memObjMap.end()) {
MT_MEM_OBJ_INFO* pDelInfo = memObjMap[mem];
delete pDelInfo;
memObjMap.erase(mem);
}
else {
char str[1024];
sprintf(str, "Request to delete memory object %p not present in memory Object Map", mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, mem, 0, MEMTRACK_INVALID_MEM_OBJ, "MEM", str);
}
}
// Check if fence for given CB is completed
static bool32_t checkCBCompleted(
const VkCmdBuffer cb)
{
bool32_t result = VK_TRUE;
MT_CB_INFO* pCBInfo = getCBInfo(cb);
if (!pCBInfo) {
char str[1024];
sprintf(str, "Unable to find global CB info %p to check for completion", cb);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cb, 0, MEMTRACK_INVALID_CB, "MEM", str);
result = VK_FALSE;
} else {
if (!fenceRetired(pCBInfo->fenceId)) {
char str[1024];
sprintf(str, "FenceId %" PRIx64", fence %p for CB %p has not been checked for completion",
pCBInfo->fenceId, getFenceFromId(pCBInfo->fenceId), cb);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, cb, 0, MEMTRACK_NONE, "MEM", str);
result = VK_FALSE;
}
}
return result;
}
static bool32_t freeMemObjInfo(
VkDeviceMemory mem,
bool internal)
{
bool32_t result = VK_TRUE;
// Parse global list to find info w/ mem
MT_MEM_OBJ_INFO* pInfo = getMemObjInfo(mem);
if (!pInfo) {
char str[1024];
sprintf(str, "Couldn't find mem info object for %p\n Was %p never allocated or previously freed?",
(void*)mem, (void*)mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, mem, 0, MEMTRACK_INVALID_MEM_OBJ, "MEM", str);
result = VK_FALSE;
} else {
if (pInfo->allocInfo.allocationSize == 0 && !internal) {
char str[1024];
sprintf(str, "Attempting to free memory associated with a Persistent Image, %p, "
"this should not be explicitly freed\n", (void*)mem);
layerCbMsg(VK_DBG_MSG_WARNING, VK_VALIDATION_LEVEL_0, mem, 0, MEMTRACK_INVALID_MEM_OBJ, "MEM", str);
result = VK_FALSE;
} else {
// Clear any CB bindings for completed CBs
// TODO : Is there a better place to do this?
list<VkCmdBuffer>::iterator it = pInfo->pCmdBufferBindings.begin();
list<VkCmdBuffer>::iterator temp;
while (pInfo->pCmdBufferBindings.size() > 0 && it != pInfo->pCmdBufferBindings.end()) {
if (VK_TRUE == checkCBCompleted(*it)) {
temp = it;
++temp;
freeCBBindings(*it);
it = temp;
} else {
++it;
}
}
// Now verify that no references to this mem obj remain
if (0 != pInfo->refCount) {
// If references remain, report the error and can search CB list to find references
char str[1024];
sprintf(str, "Freeing mem obj %p while it still has references", (void*)mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, mem, 0, MEMTRACK_FREED_MEM_REF, "MEM", str);
reportMemReferencesAndCleanUp(pInfo);
result = VK_FALSE;
}
// Delete mem obj info
deleteMemObjInfo(mem);
}
}
return result;
}
// Remove object binding performs 3 tasks:
// 1. Remove ObjectInfo from MemObjInfo list container of obj bindings & free it
// 2. Decrement refCount for MemObjInfo
// 3. Clear MemObjInfo ptr from ObjectInfo
static bool32_t clearObjectBinding(
VkObject object)
{
bool32_t result = VK_FALSE;
MT_OBJ_INFO* pObjInfo = getObjectInfo(object);
if (!pObjInfo) {
char str[1024];
sprintf(str, "Attempting to clear mem binding for object %p: devices, queues, command buffers, "
"shaders and memory objects do not have external memory requirements and it is "
"unneccessary to call bind/unbindObjectMemory on them.", object);
layerCbMsg(VK_DBG_MSG_WARNING, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_INVALID_OBJECT, "MEM", str);
} else {
if (!pObjInfo->pMemObjInfo || pObjInfo->pMemObjInfo->pObjBindings.size() <= 0) {
char str[1024];
sprintf(str, "Attempting to clear mem binding on obj %p but it has no binding.", (void*)object);
layerCbMsg(VK_DBG_MSG_WARNING, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_MEM_OBJ_CLEAR_EMPTY_BINDINGS, "MEM", str);
} else {
// This obj is bound to a memory object. Remove the reference to this object in that memory object's list, decrement the memObj's refcount
// and set the objects memory binding pointer to NULL.
for (list<VkObject>::iterator it = pObjInfo->pMemObjInfo->pObjBindings.begin(); it != pObjInfo->pMemObjInfo->pObjBindings.end(); ++it) {
if ((*it) == object) {
pObjInfo->pMemObjInfo->refCount--;
pObjInfo->pMemObjInfo->pObjBindings.erase(it);
pObjInfo->pMemObjInfo = NULL;
result = VK_TRUE;
break;
}
}
if (result == VK_FALSE) {
char str[1024];
sprintf(str, "While trying to clear mem binding for object %p, unable to find that object referenced by mem obj %p",
object, pObjInfo->pMemObjInfo->mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_INTERNAL_ERROR, "MEM", str);
}
}
}
return result;
}
// For NULL mem case, clear any previous binding Else...
// Make sure given object is in global object map
// IF a previous binding existed, clear it
// Add reference from objectInfo to memoryInfo
// Add reference off of objInfo
// Return VK_TRUE if addition is successful, VK_FALSE otherwise
static bool32_t updateObjectBinding(
VkObject object,
VkDeviceMemory mem)
{
bool32_t result = VK_FALSE;
// Handle NULL case separately, just clear previous binding & decrement reference
if (mem == VK_NULL_HANDLE) {
clearObjectBinding(object);
result = VK_TRUE;
} else {
char str[1024];
MT_OBJ_INFO* pObjInfo = getObjectInfo(object);
if (!pObjInfo) {
sprintf(str, "Attempting to update Binding of Obj(%p) that's not in global list()", (void*)object);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_INTERNAL_ERROR, "MEM", str);
return VK_FALSE;
}
// non-null case so should have real mem obj
MT_MEM_OBJ_INFO* pInfo = getMemObjInfo(mem);
if (!pInfo) {
sprintf(str, "While trying to bind mem for obj %p, couldn't find info for mem obj %p", (void*)object, (void*)mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, mem, 0, MEMTRACK_INVALID_MEM_OBJ, "MEM", str);
} else {
// Search for object in memory object's binding list
bool32_t found = VK_FALSE;
if (pInfo->pObjBindings.size() > 0) {
for (list<VkObject>::iterator it = pInfo->pObjBindings.begin(); it != pInfo->pObjBindings.end(); ++it) {
if ((*it) == object) {
found = VK_TRUE;
break;
}
}
}
// If not present, add to list
if (found == VK_FALSE) {
pInfo->pObjBindings.push_front(object);
pInfo->refCount++;
}
if (pObjInfo->pMemObjInfo) {
clearObjectBinding(object); // Need to clear the previous object binding before setting new binding
sprintf(str, "Updating memory binding for object %p from mem obj %p to %p", object, pObjInfo->pMemObjInfo->mem, mem);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_NONE, "MEM", str);
}
// For image objects, make sure default memory state is correctly set
// TODO : What's the best/correct way to handle this?
if (VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO == pObjInfo->sType) {
if (pObjInfo->create_info.image_create_info.usage & (VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT |
VK_IMAGE_USAGE_DEPTH_STENCIL_BIT)) {
// TODO:: More memory state transition stuff.
}
}
pObjInfo->pMemObjInfo = pInfo;
}
}
return VK_TRUE;
}
// Print details of global Obj tracking list
static void printObjList(
void)
{
MT_OBJ_INFO* pInfo = NULL;
char str[1024];
sprintf(str, "Details of Object list of size %lu elements", objectMap.size());
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
if (objectMap.size() <= 0)
return;
for (map<VkObject, MT_OBJ_INFO*>::iterator ii=objectMap.begin(); ii!=objectMap.end(); ++ii) {
pInfo = (*ii).second;
sprintf(str, " ObjInfo %p has object %p, pMemObjInfo %p", pInfo, pInfo->object, pInfo->pMemObjInfo);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, pInfo->object, 0, MEMTRACK_NONE, "MEM", str);
}
}
// For given Object, get 'mem' obj that it's bound to or NULL if no binding
static VkDeviceMemory getMemBindingFromObject(
const VkObject object)
{
VkDeviceMemory mem = NULL;
MT_OBJ_INFO* pObjInfo = getObjectInfo(object);
if (pObjInfo) {
if (pObjInfo->pMemObjInfo) {
mem = pObjInfo->pMemObjInfo->mem;
} else {
char str[1024];
sprintf(str, "Trying to get mem binding for object %p but object has no mem binding", (void*)object);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_MISSING_MEM_BINDINGS, "MEM", str);
printObjList();
}
} else {
char str[1024];
sprintf(str, "Trying to get mem binding for object %p but no such object in global list", (void*)object);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_INVALID_OBJECT, "MEM", str);
printObjList();
}
return mem;
}
// Print details of MemObjInfo list
static void printMemList(
void)
{
MT_MEM_OBJ_INFO* pInfo = NULL;
// Just printing each msg individually for now, may want to package these into single large print
char str[1024];
sprintf(str, "MEM INFO : Details of Memory Object list of size %lu elements", memObjMap.size());
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
if (memObjMap.size() <= 0)
return;
for (map<VkDeviceMemory, MT_MEM_OBJ_INFO*>::iterator ii=memObjMap.begin(); ii!=memObjMap.end(); ++ii) {
pInfo = (*ii).second;
sprintf(str, " ===MemObjInfo at %p===", (void*)pInfo);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
sprintf(str, " Mem object: %p", (void*)pInfo->mem);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
sprintf(str, " Ref Count: %u", pInfo->refCount);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
if (0 != pInfo->allocInfo.allocationSize) {
string pAllocInfoMsg = vk_print_vkmemoryallocinfo(&pInfo->allocInfo, "{MEM}INFO : ");
sprintf(str, " Mem Alloc info:\n%s", pAllocInfoMsg.c_str());
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
} else {
sprintf(str, " Mem Alloc info is NULL (alloc done by vkCreateSwapChainWSI())");
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
}
sprintf(str, " VK OBJECT Binding list of size %lu elements:", pInfo->pObjBindings.size());
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
if (pInfo->pObjBindings.size() > 0) {
for (list<VkObject>::iterator it = pInfo->pObjBindings.begin(); it != pInfo->pObjBindings.end(); ++it) {
sprintf(str, " VK OBJECT %p", (*it));
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
}
}
sprintf(str, " VK Command Buffer (CB) binding list of size %lu elements", pInfo->pCmdBufferBindings.size());
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
if (pInfo->pCmdBufferBindings.size() > 0)
{
for (list<VkCmdBuffer>::iterator it = pInfo->pCmdBufferBindings.begin(); it != pInfo->pCmdBufferBindings.end(); ++it) {
sprintf(str, " VK CB %p", (*it));
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
}
}
}
}
static void printCBList(
void)
{
char str[1024] = {0};
MT_CB_INFO* pCBInfo = NULL;
sprintf(str, "Details of CB list of size %lu elements", cbMap.size());
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
if (cbMap.size() <= 0)
return;
for (map<VkCmdBuffer, MT_CB_INFO*>::iterator ii=cbMap.begin(); ii!=cbMap.end(); ++ii) {
pCBInfo = (*ii).second;
sprintf(str, " CB Info (%p) has CB %p, fenceId %" PRIx64", and fence %p",
(void*)pCBInfo, (void*)pCBInfo->cmdBuffer, pCBInfo->fenceId,
(void*)getFenceFromId(pCBInfo->fenceId));
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
if (pCBInfo->pMemObjList.size() <= 0)
continue;
for (list<VkDeviceMemory>::iterator it = pCBInfo->pMemObjList.begin(); it != pCBInfo->pMemObjList.end(); ++it) {
sprintf(str, " Mem obj %p", (*it));
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, NULL, 0, MEMTRACK_NONE, "MEM", str);
}
}
}
static void initMemTracker(
void)
{
const char *strOpt;
// initialize MemTracker options
getLayerOptionEnum("MemTrackerReportLevel", (uint32_t *) &g_reportingLevel);
g_actionIsDefault = getLayerOptionEnum("MemTrackerDebugAction", (uint32_t *) &g_debugAction);
if (g_debugAction & VK_DBG_LAYER_ACTION_LOG_MSG)
{
strOpt = getLayerOption("MemTrackerLogFilename");
if (strOpt) {
g_logFile = fopen(strOpt, "w");
}
if (g_logFile == NULL) {
g_logFile = stdout;
}
}
// initialize Layer dispatch table
// TODO handle multiple GPUs
PFN_vkGetProcAddr fpNextGPA;
fpNextGPA = pCurObj->pGPA;
assert(fpNextGPA);
layer_initialize_dispatch_table(&nextTable, fpNextGPA, (VkPhysicalDevice) pCurObj->nextObject);
if (!globalLockInitialized)
{
// TODO/TBD: Need to delete this mutex sometime. How??? One
// suggestion is to call this during vkCreateInstance(), and then we
// can clean it up during vkDestroyInstance(). However, that requires
// that the layer have per-instance locks. We need to come back and
// address this soon.
loader_platform_thread_create_mutex(&globalLock);
globalLockInitialized = 1;
}
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateDevice(
VkPhysicalDevice gpu,
const VkDeviceCreateInfo *pCreateInfo,
VkDevice *pDevice)
{
pCurObj = (VkBaseLayerObject *) gpu;
loader_platform_thread_once(&g_initOnce, initMemTracker);
VkResult result = nextTable.CreateDevice(gpu, pCreateInfo, pDevice);
// Save off device in case we need it to create Fences
globalDevice = *pDevice;
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkDestroyDevice(
VkDevice device)
{
char str[1024];
sprintf(str, "Printing List details prior to vkDestroyDevice()");
loader_platform_thread_lock_mutex(&globalLock);
layerCbMsg(VK_DBG_MSG_UNKNOWN, VK_VALIDATION_LEVEL_0, device, 0, MEMTRACK_NONE, "MEM", str);
printMemList();
printCBList();
printObjList();
if (VK_FALSE == deleteCBInfoList()) {
sprintf(str, "Issue deleting global CB list in vkDestroyDevice()");
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, device, 0, MEMTRACK_INTERNAL_ERROR, "MEM", str);
}
// Report any memory leaks
MT_MEM_OBJ_INFO* pInfo = NULL;
if (memObjMap.size() > 0) {
for (map<VkDeviceMemory, MT_MEM_OBJ_INFO*>::iterator ii=memObjMap.begin(); ii!=memObjMap.end(); ++ii) {
pInfo = (*ii).second;
if (pInfo->allocInfo.allocationSize != 0) {
sprintf(str, "Mem Object %p has not been freed. You should clean up this memory by calling "
"vkFreeMemory(%p) prior to vkDestroyDevice().", pInfo->mem, pInfo->mem);
layerCbMsg(VK_DBG_MSG_WARNING, VK_VALIDATION_LEVEL_0, pInfo->mem, 0, MEMTRACK_MEMORY_LEAK, "MEM", str);
}
}
}
// Queues persist until device is destroyed
deleteQueueInfoList();
loader_platform_thread_unlock_mutex(&globalLock);
VkResult result = nextTable.DestroyDevice(device);
return result;
}
struct extProps {
uint32_t version;
const char * const name;
};
#define MEM_TRACKER_LAYER_EXT_ARRAY_SIZE 2
static const struct extProps mtExts[MEM_TRACKER_LAYER_EXT_ARRAY_SIZE] = {
// TODO what is the version?
0x10, "MemTracker",
0x10, "Validation"
};
VK_LAYER_EXPORT VkResult VKAPI vkGetGlobalExtensionInfo(
VkExtensionInfoType infoType,
uint32_t extensionIndex,
size_t *pDataSize,
void *pData)
{
/* This entrypoint is NOT going to init it's own dispatch table since loader calls here early */
VkExtensionProperties *ext_props;
uint32_t *count;
if (pDataSize == NULL) {
return VK_ERROR_INVALID_POINTER;
}
switch (infoType) {
case VK_EXTENSION_INFO_TYPE_COUNT:
*pDataSize = sizeof(uint32_t);
if (pData == NULL) {
return VK_SUCCESS;
}
count = (uint32_t *) pData;
*count = MEM_TRACKER_LAYER_EXT_ARRAY_SIZE;
break;
case VK_EXTENSION_INFO_TYPE_PROPERTIES:
*pDataSize = sizeof(VkExtensionProperties);
if (pData == NULL) {
return VK_SUCCESS;
}
if (extensionIndex >= MEM_TRACKER_LAYER_EXT_ARRAY_SIZE) {
return VK_ERROR_INVALID_VALUE;
}
ext_props = (VkExtensionProperties *) pData;
ext_props->version = mtExts[extensionIndex].version;
strncpy(ext_props->extName, mtExts[extensionIndex].name,
VK_MAX_EXTENSION_NAME);
ext_props->extName[VK_MAX_EXTENSION_NAME - 1] = '\0';
break;
default:
return VK_ERROR_INVALID_VALUE;
};
return VK_SUCCESS;
}
VK_LAYER_EXPORT VkResult VKAPI vkEnumerateLayers(
VkPhysicalDevice gpu,
size_t maxStringSize,
size_t *pLayerCount,
char* const *pOutLayers,
void *pReserved)
{
if (gpu != NULL)
{
pCurObj = (VkBaseLayerObject *) gpu;
loader_platform_thread_once(&g_initOnce, initMemTracker);
VkResult result = nextTable.EnumerateLayers(gpu,
maxStringSize, pLayerCount, pOutLayers, pReserved);
return result;
} else
{
if (pLayerCount == NULL || pOutLayers == NULL || pOutLayers[0] == NULL) {
return VK_ERROR_INVALID_POINTER;
}
// This layer compatible with all GPUs
*pLayerCount = 1;
strncpy((char *) pOutLayers[0], "MemTracker", maxStringSize);
return VK_SUCCESS;
}
}
VK_LAYER_EXPORT VkResult VKAPI vkGetDeviceQueue(
VkDevice device,
uint32_t queueNodeIndex,
uint32_t queueIndex,
VkQueue *pQueue)
{
VkResult result = nextTable.GetDeviceQueue(device, queueNodeIndex, queueIndex, pQueue);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addQueueInfo(*pQueue);
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkQueueAddMemReferences(
VkQueue queue,
uint32_t count,
const VkDeviceMemory *pMems)
{
VkResult result = nextTable.QueueAddMemReferences(queue, count, pMems);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
MT_QUEUE_INFO *pQueueInfo = queueMap[queue];
if (pQueueInfo == NULL) {
char str[1024];
sprintf(str, "Unknown Queue %p", queue);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, queue, 0, MEMTRACK_INVALID_QUEUE, "MEM", str);
} else {
for (uint32_t i = 0; i < count; i++) {
if (checkMemRef(queue, pMems[i]) == VK_TRUE) {
// Alread in list, just warn
char str[1024];
sprintf(str, "Request to add a memory reference (%p) to Queue %p -- ref is already "
"present in the queue's reference list", pMems[i], queue);
layerCbMsg(VK_DBG_MSG_WARNING, VK_VALIDATION_LEVEL_0, pMems[i], 0, MEMTRACK_INVALID_MEM_REF, "MEM", str);
} else {
// Add to queue's memory reference list
pQueueInfo->pMemRefList.push_front(pMems[i]);
}
}
}
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkQueueRemoveMemReferences(
VkQueue queue,
uint32_t count,
const VkDeviceMemory *pMems)
{
// TODO : Decrement ref count for this memory reference on this queue. Remove if ref count is zero.
VkResult result = nextTable.QueueRemoveMemReferences(queue, count, pMems);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
MT_QUEUE_INFO *pQueueInfo = queueMap[queue];
if (pQueueInfo == NULL) {
char str[1024];
sprintf(str, "Unknown Queue %p", queue);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, queue, 0, MEMTRACK_INVALID_QUEUE, "MEM", str);
} else {
for (uint32_t i = 0; i < count; i++) {
if (pQueueInfo->pMemRefList.size() > 0) {
for (list<VkDeviceMemory>::iterator it = pQueueInfo->pMemRefList.begin(); it != pQueueInfo->pMemRefList.end();) {
if ((*it) == pMems[i]) {
it = pQueueInfo->pMemRefList.erase(it);
} else {
++it;
}
}
}
}
}
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkQueueSubmit(
VkQueue queue,
uint32_t cmdBufferCount,
const VkCmdBuffer *pCmdBuffers,
VkFence fence)
{
loader_platform_thread_lock_mutex(&globalLock);
// TODO : Need to track fence and clear mem references when fence clears
MT_CB_INFO* pCBInfo = NULL;
uint64_t fenceId = addFenceInfo(fence, queue);
printMemList();
printCBList();
for (uint32_t i = 0; i < cmdBufferCount; i++) {
pCBInfo = getCBInfo(pCmdBuffers[i]);
pCBInfo->fenceId = fenceId;
}
validateQueueMemRefs(queue, cmdBufferCount, pCmdBuffers);
loader_platform_thread_unlock_mutex(&globalLock);
VkResult result = nextTable.QueueSubmit(queue, cmdBufferCount, pCmdBuffers, getFenceFromId(fenceId));
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkAllocMemory(
VkDevice device,
const VkMemoryAllocInfo *pAllocInfo,
VkDeviceMemory *pMem)
{
VkResult result = nextTable.AllocMemory(device, pAllocInfo, pMem);
// TODO : Track allocations and overall size here
loader_platform_thread_lock_mutex(&globalLock);
addMemObjInfo(*pMem, pAllocInfo);
printMemList();
loader_platform_thread_unlock_mutex(&globalLock);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkFreeMemory(
VkDevice device,
VkDeviceMemory mem)
{
/* From spec : A memory object is freed by calling vkFreeMemory() when it is no longer needed. Before
* freeing a memory object, an application must ensure the memory object is unbound from
* all API objects referencing it and that it is not referenced by any queued command buffers
*/
loader_platform_thread_lock_mutex(&globalLock);
if (VK_FALSE == freeMemObjInfo(mem, false)) {
char str[1024];
sprintf(str, "Issue while freeing mem obj %p", (void*)mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, mem, 0, MEMTRACK_FREE_MEM_ERROR, "MEM", str);
}
printMemList();
printObjList();
printCBList();
loader_platform_thread_unlock_mutex(&globalLock);
VkResult result = nextTable.FreeMemory(device, mem);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkSetMemoryPriority(
VkDevice device,
VkDeviceMemory mem,
VkMemoryPriority priority)
{
// TODO : Update tracking for this alloc
// Make sure memory is not pinned, which can't have priority set
VkResult result = nextTable.SetMemoryPriority(device, mem, priority);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkMapMemory(
VkDevice device,
VkDeviceMemory mem,
VkDeviceSize offset,
VkDeviceSize size,
VkFlags flags,
void **ppData)
{
// TODO : Track when memory is mapped
loader_platform_thread_lock_mutex(&globalLock);
MT_MEM_OBJ_INFO *pMemObj = getMemObjInfo(mem);
if ((pMemObj->allocInfo.memProps & VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT) == 0) {
char str[1024];
sprintf(str, "Mapping Memory (%p) without VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT set", (void*)mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, mem, 0, MEMTRACK_INVALID_STATE, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
VkResult result = nextTable.MapMemory(device, mem, offset, size, flags, ppData);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkUnmapMemory(
VkDevice device,
VkDeviceMemory mem)
{
// TODO : Track as memory gets unmapped, do we want to check what changed following map?
// Make sure that memory was ever mapped to begin with
VkResult result = nextTable.UnmapMemory(device, mem);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkPinSystemMemory(
VkDevice device,
const void *pSysMem,
size_t memSize,
VkDeviceMemory *pMem)
{
// TODO : Track this
// Verify that memory is actually pinnable
VkResult result = nextTable.PinSystemMemory(device, pSysMem, memSize, pMem);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkOpenSharedMemory(
VkDevice device,
const VkMemoryOpenInfo *pOpenInfo,
VkDeviceMemory *pMem)
{
// TODO : Track this
VkResult result = nextTable.OpenSharedMemory(device, pOpenInfo, pMem);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkOpenPeerMemory(
VkDevice device,
const VkPeerMemoryOpenInfo *pOpenInfo,
VkDeviceMemory *pMem)
{
// TODO : Track this
VkResult result = nextTable.OpenPeerMemory(device, pOpenInfo, pMem);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkOpenPeerImage(
VkDevice device,
const VkPeerImageOpenInfo *pOpenInfo,
VkImage *pImage,
VkDeviceMemory *pMem)
{
// TODO : Track this
VkResult result = nextTable.OpenPeerImage(device, pOpenInfo, pImage, pMem);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkDestroyObject(
VkDevice device,
VkObjectType objType,
VkObject object)
{
loader_platform_thread_lock_mutex(&globalLock);
// First check if this is a CmdBuffer
if (NULL != getCBInfo((VkCmdBuffer)object)) {
deleteCBInfo((VkCmdBuffer)object);
}
if (objectMap.find(object) != objectMap.end()) {
MT_OBJ_INFO* pDelInfo = objectMap[object];
if (pDelInfo->pMemObjInfo) {
// Wsi allocated Memory is tied to image object so clear the binding and free that memory automatically
if (0 == pDelInfo->pMemObjInfo->allocInfo.allocationSize) { // Wsi allocated memory has NULL allocInfo w/ 0 size
VkDeviceMemory memToFree = pDelInfo->pMemObjInfo->mem;
clearObjectBinding(object);
freeMemObjInfo(memToFree, true);
}
else {
char str[1024];
sprintf(str, "Destroying obj %p that is still bound to memory object %p\nYou should first clear binding "
"by calling vkQueueBindObjectMemory(queue, %p, 0, VK_NULL_HANDLE, 0)",
object, (void*)pDelInfo->pMemObjInfo->mem, object);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_DESTROY_OBJECT_ERROR, "MEM", str);
// From the spec : If an object has previous memory binding, it is required to unbind memory
// from an API object before it is destroyed.
clearObjectBinding(object);
}
}
delete pDelInfo;
objectMap.erase(object);
}
loader_platform_thread_unlock_mutex(&globalLock);
VkResult result = nextTable.DestroyObject(device, objType, object);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkGetObjectInfo(
VkDevice device,
VkObjectType objType,
VkObject object,
VkObjectInfoType infoType,
size_t *pDataSize,
void *pData)
{
// TODO : What to track here?
// Could potentially save returned mem requirements and validate values passed into QueueBindObjectMemory for this object
// From spec : The only objects that are guaranteed to have no external memory requirements are devices, queues,
// command buffers, shaders and memory objects.
VkResult result = nextTable.GetObjectInfo(device, objType, object, infoType, pDataSize, pData);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkQueueBindObjectMemory(
VkQueue queue,
VkObjectType objType,
VkObject object,
uint32_t allocationIdx,
VkDeviceMemory mem,
VkDeviceSize offset)
{
VkResult result = nextTable.QueueBindObjectMemory(queue, objType, object, allocationIdx, mem, offset);
loader_platform_thread_lock_mutex(&globalLock);
// Track objects tied to memory
if (VK_FALSE == updateObjectBinding(object, mem)) {
char str[1024];
sprintf(str, "Unable to set object %p binding to mem obj %p", (void*)object, (void*)mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
printObjList();
printMemList();
loader_platform_thread_unlock_mutex(&globalLock);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkQueueBindObjectMemoryRange(
VkQueue queue,
VkObjectType objType,
VkObject object,
uint32_t allocationIdx,
VkDeviceSize rangeOffset,
VkDeviceSize rangeSize,
VkDeviceMemory mem,
VkDeviceSize memOffset)
{
VkResult result = nextTable.QueueBindObjectMemoryRange(queue, objType, object, allocationIdx, rangeOffset, rangeSize, mem, memOffset);
loader_platform_thread_lock_mutex(&globalLock);
// Track objects tied to memory
if (VK_FALSE == updateObjectBinding(object, mem)) {
char str[1024];
sprintf(str, "Unable to set object %p binding to mem obj %p", (void*)object, (void*)mem);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, object, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
printObjList();
printMemList();
loader_platform_thread_unlock_mutex(&globalLock);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateFence(
VkDevice device,
const VkFenceCreateInfo *pCreateInfo,
VkFence *pFence)
{
VkResult result = nextTable.CreateFence(device, pCreateInfo, pFence);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pFence, pCreateInfo->sType, pCreateInfo, sizeof(VkFenceCreateInfo), "fence");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkResetFences(
VkDevice device,
uint32_t fenceCount,
VkFence *pFences)
{
VkResult result = nextTable.ResetFences(device, fenceCount, pFences);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
// Reset fence state in fenceCreateInfo structure
for (uint32_t i = 0; i < fenceCount; i++) {
MT_OBJ_INFO* pObjectInfo = getObjectInfo(pFences[i]);
if (pObjectInfo != NULL) {
// Validate fences in SIGNALED state
if (!(pObjectInfo->create_info.fence_create_info.flags & VK_FENCE_CREATE_SIGNALED_BIT)) {
char str[1024];
sprintf(str, "Fence %p submitted to VkResetFences in UNSIGNALED STATE", pFences[i]);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, pFences[i], 0, MEMTRACK_INVALID_FENCE_STATE, "MEM", str);
result = VK_ERROR_INVALID_VALUE;
}
else {
pObjectInfo->create_info.fence_create_info.flags =
static_cast<VkFenceCreateFlags>(pObjectInfo->create_info.fence_create_info.flags & ~VK_FENCE_CREATE_SIGNALED_BIT);
}
}
}
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkGetFenceStatus(
VkDevice device,
VkFence fence)
{
VkResult result = nextTable.GetFenceStatus(device, fence);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
updateFenceTracking(fence);
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkWaitForFences(
VkDevice device,
uint32_t fenceCount,
const VkFence *pFences,
bool32_t waitAll,
uint64_t timeout)
{
// Verify fence status of submitted fences
for(uint32_t i = 0; i < fenceCount; i++) {
MT_OBJ_INFO* pObjectInfo = getObjectInfo(pFences[i]);
if (pObjectInfo != NULL) {
if (pObjectInfo->create_info.fence_create_info.flags & VK_FENCE_CREATE_SIGNALED_BIT) {
char str[1024];
sprintf(str, "VkWaitForFences specified fence %p already in SIGNALED state.", pFences[i]);
layerCbMsg(VK_DBG_MSG_WARNING, VK_VALIDATION_LEVEL_0, pFences[i], 0, MEMTRACK_INVALID_FENCE_STATE, "MEM", str);
}
}
}
VkResult result = nextTable.WaitForFences(device, fenceCount, pFences, waitAll, timeout);
loader_platform_thread_lock_mutex(&globalLock);
if (VK_SUCCESS == result) {
if (waitAll || fenceCount == 1) { // Clear all the fences
for(uint32_t i = 0; i < fenceCount; i++) {
updateFenceTracking(pFences[i]);
}
}
}
loader_platform_thread_unlock_mutex(&globalLock);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkQueueWaitIdle(
VkQueue queue)
{
VkResult result = nextTable.QueueWaitIdle(queue);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
retireQueueFences(queue);
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkDeviceWaitIdle(
VkDevice device)
{
VkResult result = nextTable.DeviceWaitIdle(device);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
retireDeviceFences(device);
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateEvent(
VkDevice device,
const VkEventCreateInfo *pCreateInfo,
VkEvent *pEvent)
{
VkResult result = nextTable.CreateEvent(device, pCreateInfo, pEvent);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pEvent, pCreateInfo->sType, pCreateInfo, sizeof(VkEventCreateInfo), "event");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateQueryPool(
VkDevice device,
const VkQueryPoolCreateInfo *pCreateInfo,
VkQueryPool *pQueryPool)
{
VkResult result = nextTable.CreateQueryPool(device, pCreateInfo, pQueryPool);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pQueryPool, pCreateInfo->sType, pCreateInfo, sizeof(VkQueryPoolCreateInfo), "query_pool");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateBuffer(
VkDevice device,
const VkBufferCreateInfo *pCreateInfo,
VkBuffer *pBuffer)
{
VkResult result = nextTable.CreateBuffer(device, pCreateInfo, pBuffer);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pBuffer, pCreateInfo->sType, pCreateInfo, sizeof(VkBufferCreateInfo), "buffer");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateBufferView(
VkDevice device,
const VkBufferViewCreateInfo *pCreateInfo,
VkBufferView *pView)
{
VkResult result = nextTable.CreateBufferView(device, pCreateInfo, pView);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pView, pCreateInfo->sType, pCreateInfo, sizeof(VkBufferViewCreateInfo), "buffer_view");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateImage(
VkDevice device,
const VkImageCreateInfo *pCreateInfo,
VkImage *pImage)
{
VkResult result = nextTable.CreateImage(device, pCreateInfo, pImage);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pImage, pCreateInfo->sType, pCreateInfo, sizeof(VkImageCreateInfo), "image");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateImageView(
VkDevice device,
const VkImageViewCreateInfo *pCreateInfo,
VkImageView *pView)
{
VkResult result = nextTable.CreateImageView(device, pCreateInfo, pView);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pView, pCreateInfo->sType, pCreateInfo, sizeof(VkImageViewCreateInfo), "image_view");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateColorAttachmentView(
VkDevice device,
const VkColorAttachmentViewCreateInfo *pCreateInfo,
VkColorAttachmentView *pView)
{
VkResult result = nextTable.CreateColorAttachmentView(device, pCreateInfo, pView);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pView, pCreateInfo->sType, pCreateInfo, sizeof(VkColorAttachmentViewCreateInfo), "color_attachment_view");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateDepthStencilView(
VkDevice device,
const VkDepthStencilViewCreateInfo *pCreateInfo,
VkDepthStencilView *pView)
{
VkResult result = nextTable.CreateDepthStencilView(device, pCreateInfo, pView);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pView, pCreateInfo->sType, pCreateInfo, sizeof(VkDepthStencilViewCreateInfo), "ds_view");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateShader(
VkDevice device,
const VkShaderCreateInfo *pCreateInfo,
VkShader *pShader)
{
VkResult result = nextTable.CreateShader(device, pCreateInfo, pShader);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateGraphicsPipeline(
VkDevice device,
const VkGraphicsPipelineCreateInfo *pCreateInfo,
VkPipeline *pPipeline)
{
VkResult result = nextTable.CreateGraphicsPipeline(device, pCreateInfo, pPipeline);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pPipeline, pCreateInfo->sType, pCreateInfo, sizeof(VkGraphicsPipelineCreateInfo), "graphics_pipeline");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateGraphicsPipelineDerivative(
VkDevice device,
const VkGraphicsPipelineCreateInfo *pCreateInfo,
VkPipeline basePipeline,
VkPipeline *pPipeline)
{
VkResult result = nextTable.CreateGraphicsPipelineDerivative(device, pCreateInfo, basePipeline, pPipeline);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pPipeline, pCreateInfo->sType, pCreateInfo, sizeof(VkGraphicsPipelineCreateInfo), "graphics_pipeline");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateComputePipeline(
VkDevice device,
const VkComputePipelineCreateInfo *pCreateInfo,
VkPipeline *pPipeline)
{
VkResult result = nextTable.CreateComputePipeline(device, pCreateInfo, pPipeline);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pPipeline, pCreateInfo->sType, pCreateInfo, sizeof(VkComputePipelineCreateInfo), "compute_pipeline");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateSampler(
VkDevice device,
const VkSamplerCreateInfo *pCreateInfo,
VkSampler *pSampler)
{
VkResult result = nextTable.CreateSampler(device, pCreateInfo, pSampler);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pSampler, pCreateInfo->sType, pCreateInfo, sizeof(VkSamplerCreateInfo), "sampler");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateDynamicViewportState(
VkDevice device,
const VkDynamicVpStateCreateInfo *pCreateInfo,
VkDynamicVpState *pState)
{
VkResult result = nextTable.CreateDynamicViewportState(device, pCreateInfo, pState);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pState, pCreateInfo->sType, pCreateInfo, sizeof(VkDynamicVpStateCreateInfo), "viewport_state");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateDynamicRasterState(
VkDevice device,
const VkDynamicRsStateCreateInfo *pCreateInfo,
VkDynamicRsState *pState)
{
VkResult result = nextTable.CreateDynamicRasterState(device, pCreateInfo, pState);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pState, pCreateInfo->sType, pCreateInfo, sizeof(VkDynamicRsStateCreateInfo), "raster_state");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateDynamicColorBlendState(
VkDevice device,
const VkDynamicCbStateCreateInfo *pCreateInfo,
VkDynamicCbState *pState)
{
VkResult result = nextTable.CreateDynamicColorBlendState(device, pCreateInfo, pState);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pState, pCreateInfo->sType, pCreateInfo, sizeof(VkDynamicCbStateCreateInfo), "cb_state");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateDynamicDepthStencilState(
VkDevice device,
const VkDynamicDsStateCreateInfo *pCreateInfo,
VkDynamicDsState *pState)
{
VkResult result = nextTable.CreateDynamicDepthStencilState(device, pCreateInfo, pState);
if (result == VK_SUCCESS) {
loader_platform_thread_lock_mutex(&globalLock);
addObjectInfo(*pState, pCreateInfo->sType, pCreateInfo, sizeof(VkDynamicDsStateCreateInfo), "ds_state");
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateCommandBuffer(
VkDevice device,
const VkCmdBufferCreateInfo *pCreateInfo,
VkCmdBuffer *pCmdBuffer)
{
VkResult result = nextTable.CreateCommandBuffer(device, pCreateInfo, pCmdBuffer);
// At time of cmd buffer creation, create global cmd buffer info for the returned cmd buffer
loader_platform_thread_lock_mutex(&globalLock);
if (*pCmdBuffer)
addCBInfo(*pCmdBuffer);
printCBList();
loader_platform_thread_unlock_mutex(&globalLock);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkBeginCommandBuffer(
VkCmdBuffer cmdBuffer,
const VkCmdBufferBeginInfo *pBeginInfo)
{
// This implicitly resets the Cmd Buffer so make sure any fence is done and then clear memory references
MT_CB_INFO* pCBInfo = getCBInfo(cmdBuffer);
if (pCBInfo && (!fenceRetired(pCBInfo->fenceId))) {
bool32_t cbDone = checkCBCompleted(cmdBuffer);
if (VK_FALSE == cbDone) {
char str[1024];
sprintf(str, "Calling vkBeginCommandBuffer() on active CB %p before it has completed. "
"You must check CB flag before this call.", cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_RESET_CB_WHILE_IN_FLIGHT, "MEM", str);
}
}
VkResult result = nextTable.BeginCommandBuffer(cmdBuffer, pBeginInfo);
loader_platform_thread_lock_mutex(&globalLock);
freeCBBindings(cmdBuffer);
loader_platform_thread_unlock_mutex(&globalLock);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkEndCommandBuffer(
VkCmdBuffer cmdBuffer)
{
// TODO : Anything to do here?
VkResult result = nextTable.EndCommandBuffer(cmdBuffer);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkResetCommandBuffer(
VkCmdBuffer cmdBuffer)
{
// Verify that CB is complete (not in-flight)
MT_CB_INFO* pCBInfo = getCBInfo(cmdBuffer);
if (pCBInfo && (!fenceRetired(pCBInfo->fenceId))) {
bool32_t cbDone = checkCBCompleted(cmdBuffer);
if (VK_FALSE == cbDone) {
char str[1024];
sprintf(str, "Resetting CB %p before it has completed. You must check CB flag before "
"calling vkResetCommandBuffer().", cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_RESET_CB_WHILE_IN_FLIGHT, "MEM", str);
}
}
// Clear memory references as this point.
loader_platform_thread_lock_mutex(&globalLock);
freeCBBindings(cmdBuffer);
loader_platform_thread_unlock_mutex(&globalLock);
VkResult result = nextTable.ResetCommandBuffer(cmdBuffer);
return result;
}
// TODO : For any vkCmdBind* calls that include an object which has mem bound to it,
// need to account for that mem now having binding to given cmdBuffer
VK_LAYER_EXPORT void VKAPI vkCmdBindPipeline(
VkCmdBuffer cmdBuffer,
VkPipelineBindPoint pipelineBindPoint,
VkPipeline pipeline)
{
#if 0
// TODO : If memory bound to pipeline, then need to tie that mem to cmdBuffer
if (getPipeline(pipeline)) {
MT_CB_INFO *pCBInfo = getCBInfo(cmdBuffer);
if (pCBInfo) {
pCBInfo->pipelines[pipelineBindPoint] = pipeline;
} else {
char str[1024];
sprintf(str, "Attempt to bind Pipeline %p to non-existant command buffer %p!", (void*)pipeline, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_INVALID_CB, (char *) "DS", (char *) str);
}
}
else {
char str[1024];
sprintf(str, "Attempt to bind Pipeline %p that doesn't exist!", (void*)pipeline);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, pipeline, 0, MEMTRACK_INVALID_OBJECT, (char *) "DS", (char *) str);
}
#endif
nextTable.CmdBindPipeline(cmdBuffer, pipelineBindPoint, pipeline);
}
VK_LAYER_EXPORT void VKAPI vkCmdBindDynamicStateObject(
VkCmdBuffer cmdBuffer,
VkStateBindPoint stateBindPoint,
VkDynamicStateObject state)
{
MT_OBJ_INFO *pObjInfo;
loader_platform_thread_lock_mutex(&globalLock);
MT_CB_INFO *pCmdBuf = getCBInfo(cmdBuffer);
if (!pCmdBuf) {
char str[1024];
sprintf(str, "Unable to find command buffer object %p, was it ever created?", (void*)cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_INVALID_CB, "DD", str);
}
pObjInfo = getObjectInfo(state);
if (!pObjInfo) {
char str[1024];
sprintf(str, "Unable to find dynamic state object %p, was it ever created?", (void*)state);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, state, 0, MEMTRACK_INVALID_OBJECT, "DD", str);
}
pCmdBuf->pDynamicState[stateBindPoint] = pObjInfo;
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdBindDynamicStateObject(cmdBuffer, stateBindPoint, state);
}
VK_LAYER_EXPORT void VKAPI vkCmdBindDescriptorSets(
VkCmdBuffer cmdBuffer,
VkPipelineBindPoint pipelineBindPoint,
uint32_t firstSet,
uint32_t setCount,
const VkDescriptorSet *pDescriptorSets,
uint32_t dynamicOffsetCount,
const uint32_t *pDynamicOffsets)
{
// TODO : Somewhere need to verify that all textures referenced by shaders in DS are in some type of *SHADER_READ* state
nextTable.CmdBindDescriptorSets(cmdBuffer, pipelineBindPoint, firstSet, setCount, pDescriptorSets, dynamicOffsetCount, pDynamicOffsets);
}
VK_LAYER_EXPORT void VKAPI vkCmdBindVertexBuffers(
VkCmdBuffer cmdBuffer,
uint32_t startBinding,
uint32_t bindingCount,
const VkBuffer *pBuffers,
const VkDeviceSize *pOffsets)
{
nextTable.CmdBindVertexBuffers(cmdBuffer, startBinding, bindingCount, pBuffers, pOffsets);
}
VK_LAYER_EXPORT void VKAPI vkCmdBindIndexBuffer(
VkCmdBuffer cmdBuffer,
VkBuffer buffer,
VkDeviceSize offset,
VkIndexType indexType)
{
nextTable.CmdBindIndexBuffer(cmdBuffer, buffer, offset, indexType);
}
VK_LAYER_EXPORT void VKAPI vkCmdDrawIndirect(
VkCmdBuffer cmdBuffer,
VkBuffer buffer,
VkDeviceSize offset,
uint32_t count,
uint32_t stride)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(buffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdDrawIndirect() call unable to update binding of buffer %p to cmdBuffer %p", buffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdDrawIndirect(cmdBuffer, buffer, offset, count, stride);
}
VK_LAYER_EXPORT void VKAPI vkCmdDrawIndexedIndirect(
VkCmdBuffer cmdBuffer,
VkBuffer buffer,
VkDeviceSize offset,
uint32_t count,
uint32_t stride)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(buffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdDrawIndexedIndirect() call unable to update binding of buffer %p to cmdBuffer %p", buffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdDrawIndexedIndirect(cmdBuffer, buffer, offset, count, stride);
}
VK_LAYER_EXPORT void VKAPI vkCmdDispatchIndirect(
VkCmdBuffer cmdBuffer,
VkBuffer buffer,
VkDeviceSize offset)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(buffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdDispatchIndirect() call unable to update binding of buffer %p to cmdBuffer %p", buffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdDispatchIndirect(cmdBuffer, buffer, offset);
}
VK_LAYER_EXPORT void VKAPI vkCmdCopyBuffer(
VkCmdBuffer cmdBuffer,
VkBuffer srcBuffer,
VkBuffer destBuffer,
uint32_t regionCount,
const VkBufferCopy *pRegions)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(srcBuffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdCopyBuffer() call unable to update binding of srcBuffer %p to cmdBuffer %p", srcBuffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
mem = getMemBindingFromObject(destBuffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdCopyBuffer() call unable to update binding of destBuffer %p to cmdBuffer %p", destBuffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdCopyBuffer(cmdBuffer, srcBuffer, destBuffer, regionCount, pRegions);
}
VK_LAYER_EXPORT void VKAPI vkCmdCopyImage(
VkCmdBuffer cmdBuffer,
VkImage srcImage,
VkImageLayout srcImageLayout,
VkImage destImage,
VkImageLayout destImageLayout,
uint32_t regionCount,
const VkImageCopy *pRegions)
{
// TODO : Each image will have mem mapping so track them
nextTable.CmdCopyImage(cmdBuffer, srcImage, srcImageLayout, destImage, destImageLayout, regionCount, pRegions);
}
VK_LAYER_EXPORT void VKAPI vkCmdBlitImage(
VkCmdBuffer cmdBuffer,
VkImage srcImage,
VkImageLayout srcImageLayout,
VkImage destImage,
VkImageLayout destImageLayout,
uint32_t regionCount,
const VkImageBlit *pRegions)
{
// TODO : Each image will have mem mapping so track them
nextTable.CmdBlitImage(cmdBuffer, srcImage, srcImageLayout, destImage, destImageLayout, regionCount, pRegions);
}
VK_LAYER_EXPORT void VKAPI vkCmdCopyBufferToImage(
VkCmdBuffer cmdBuffer,
VkBuffer srcBuffer,
VkImage destImage,
VkImageLayout destImageLayout,
uint32_t regionCount,
const VkBufferImageCopy *pRegions)
{
// TODO : Track this
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(destImage);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdCopyMemoryToImage() call unable to update binding of destImage buffer %p to cmdBuffer %p", destImage, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
mem = getMemBindingFromObject(srcBuffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdCopyMemoryToImage() call unable to update binding of srcBuffer %p to cmdBuffer %p", srcBuffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdCopyBufferToImage(cmdBuffer, srcBuffer, destImage, destImageLayout, regionCount, pRegions);
}
VK_LAYER_EXPORT void VKAPI vkCmdCopyImageToBuffer(
VkCmdBuffer cmdBuffer,
VkImage srcImage,
VkImageLayout srcImageLayout,
VkBuffer destBuffer,
uint32_t regionCount,
const VkBufferImageCopy *pRegions)
{
// TODO : Track this
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(srcImage);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdCopyImageToMemory() call unable to update binding of srcImage buffer %p to cmdBuffer %p", srcImage, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
mem = getMemBindingFromObject(destBuffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdCopyImageToMemory() call unable to update binding of destBuffer %p to cmdBuffer %p", destBuffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdCopyImageToBuffer(cmdBuffer, srcImage, srcImageLayout, destBuffer, regionCount, pRegions);
}
VK_LAYER_EXPORT void VKAPI vkCmdCloneImageData(
VkCmdBuffer cmdBuffer,
VkImage srcImage,
VkImageLayout srcImageLayout,
VkImage destImage,
VkImageLayout destImageLayout)
{
// TODO : Each image will have mem mapping so track them
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(srcImage);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdCloneImageData() call unable to update binding of srcImage buffer %p to cmdBuffer %p", srcImage, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
mem = getMemBindingFromObject(destImage);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdCloneImageData() call unable to update binding of destImage buffer %p to cmdBuffer %p", destImage, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdCloneImageData(cmdBuffer, srcImage, srcImageLayout, destImage, destImageLayout);
}
VK_LAYER_EXPORT void VKAPI vkCmdUpdateBuffer(
VkCmdBuffer cmdBuffer,
VkBuffer destBuffer,
VkDeviceSize destOffset,
VkDeviceSize dataSize,
const uint32_t *pData)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(destBuffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdUpdateMemory() call unable to update binding of destBuffer %p to cmdBuffer %p", destBuffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdUpdateBuffer(cmdBuffer, destBuffer, destOffset, dataSize, pData);
}
VK_LAYER_EXPORT void VKAPI vkCmdFillBuffer(
VkCmdBuffer cmdBuffer,
VkBuffer destBuffer,
VkDeviceSize destOffset,
VkDeviceSize fillSize,
uint32_t data)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(destBuffer);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdFillMemory() call unable to update binding of destBuffer %p to cmdBuffer %p", destBuffer, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdFillBuffer(cmdBuffer, destBuffer, destOffset, fillSize, data);
}
VK_LAYER_EXPORT void VKAPI vkCmdClearColorImage(
VkCmdBuffer cmdBuffer,
VkImage image,
VkImageLayout imageLayout,
VkClearColor color,
uint32_t rangeCount,
const VkImageSubresourceRange *pRanges)
{
// TODO : Verify memory is in VK_IMAGE_STATE_CLEAR state
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(image);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdClearColorImage() call unable to update binding of image buffer %p to cmdBuffer %p", image, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdClearColorImage(cmdBuffer, image, imageLayout, color, rangeCount, pRanges);
}
VK_LAYER_EXPORT void VKAPI vkCmdClearDepthStencil(
VkCmdBuffer cmdBuffer,
VkImage image,
VkImageLayout imageLayout,
float depth,
uint32_t stencil,
uint32_t rangeCount,
const VkImageSubresourceRange *pRanges)
{
// TODO : Verify memory is in VK_IMAGE_STATE_CLEAR state
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(image);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdClearDepthStencil() call unable to update binding of image buffer %p to cmdBuffer %p", image, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdClearDepthStencil(cmdBuffer, image, imageLayout, depth, stencil, rangeCount, pRanges);
}
VK_LAYER_EXPORT void VKAPI vkCmdResolveImage(
VkCmdBuffer cmdBuffer,
VkImage srcImage,
VkImageLayout srcImageLayout,
VkImage destImage,
VkImageLayout destImageLayout,
uint32_t regionCount,
const VkImageResolve *pRegions)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(srcImage);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdResolveImage() call unable to update binding of srcImage buffer %p to cmdBuffer %p", srcImage, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
mem = getMemBindingFromObject(destImage);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdResolveImage() call unable to update binding of destImage buffer %p to cmdBuffer %p", destImage, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdResolveImage(cmdBuffer, srcImage, srcImageLayout, destImage, destImageLayout, regionCount, pRegions);
}
VK_LAYER_EXPORT void VKAPI vkCmdBeginQuery(
VkCmdBuffer cmdBuffer,
VkQueryPool queryPool,
uint32_t slot,
VkFlags flags)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(queryPool);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdBeginQuery() call unable to update binding of queryPool buffer %p to cmdBuffer %p", queryPool, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdBeginQuery(cmdBuffer, queryPool, slot, flags);
}
VK_LAYER_EXPORT void VKAPI vkCmdEndQuery(
VkCmdBuffer cmdBuffer,
VkQueryPool queryPool,
uint32_t slot)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(queryPool);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdEndQuery() call unable to update binding of queryPool buffer %p to cmdBuffer %p", queryPool, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdEndQuery(cmdBuffer, queryPool, slot);
}
VK_LAYER_EXPORT void VKAPI vkCmdResetQueryPool(
VkCmdBuffer cmdBuffer,
VkQueryPool queryPool,
uint32_t startQuery,
uint32_t queryCount)
{
loader_platform_thread_lock_mutex(&globalLock);
VkDeviceMemory mem = getMemBindingFromObject(queryPool);
if (VK_FALSE == updateCBBinding(cmdBuffer, mem)) {
char str[1024];
sprintf(str, "In vkCmdResetQueryPool() call unable to update binding of queryPool buffer %p to cmdBuffer %p", queryPool, cmdBuffer);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, cmdBuffer, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
loader_platform_thread_unlock_mutex(&globalLock);
nextTable.CmdResetQueryPool(cmdBuffer, queryPool, startQuery, queryCount);
}
VK_LAYER_EXPORT VkResult VKAPI vkDbgRegisterMsgCallback(
VkInstance instance,
VK_DBG_MSG_CALLBACK_FUNCTION pfnMsgCallback,
void *pUserData)
{
// This layer intercepts callbacks
VK_LAYER_DBG_FUNCTION_NODE *pNewDbgFuncNode = (VK_LAYER_DBG_FUNCTION_NODE*)malloc(sizeof(VK_LAYER_DBG_FUNCTION_NODE));
if (!pNewDbgFuncNode)
return VK_ERROR_OUT_OF_HOST_MEMORY;
pNewDbgFuncNode->pfnMsgCallback = pfnMsgCallback;
pNewDbgFuncNode->pUserData = pUserData;
pNewDbgFuncNode->pNext = g_pDbgFunctionHead;
g_pDbgFunctionHead = pNewDbgFuncNode;
// force callbacks if DebugAction hasn't been set already other than initial value
if (g_actionIsDefault) {
g_debugAction = VK_DBG_LAYER_ACTION_CALLBACK;
}
VkResult result = nextTable.DbgRegisterMsgCallback(instance, pfnMsgCallback, pUserData);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkDbgUnregisterMsgCallback(
VkInstance instance,
VK_DBG_MSG_CALLBACK_FUNCTION pfnMsgCallback)
{
VK_LAYER_DBG_FUNCTION_NODE *pInfo = g_pDbgFunctionHead;
VK_LAYER_DBG_FUNCTION_NODE *pPrev = pInfo;
while (pInfo) {
if (pInfo->pfnMsgCallback == pfnMsgCallback) {
pPrev->pNext = pInfo->pNext;
if (g_pDbgFunctionHead == pInfo) {
g_pDbgFunctionHead = pInfo->pNext;
}
free(pInfo);
break;
}
pPrev = pInfo;
pInfo = pInfo->pNext;
}
if (g_pDbgFunctionHead == NULL) {
if (g_actionIsDefault) {
g_debugAction = VK_DBG_LAYER_ACTION_LOG_MSG;
} else {
g_debugAction = (VK_LAYER_DBG_ACTION)(g_debugAction & ~((uint32_t)VK_DBG_LAYER_ACTION_CALLBACK));
}
}
VkResult result = nextTable.DbgUnregisterMsgCallback(instance, pfnMsgCallback);
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkCreateSwapChainWSI(
VkDevice device,
const VkSwapChainCreateInfoWSI *pCreateInfo,
VkSwapChainWSI *pSwapChain)
{
VkResult result = nextTable.CreateSwapChainWSI(device, pCreateInfo, pSwapChain);
if (VK_SUCCESS == result) {
loader_platform_thread_lock_mutex(&globalLock);
addSwapChainInfo(*pSwapChain);
loader_platform_thread_unlock_mutex(&globalLock);
}
return result;
}
VK_LAYER_EXPORT VkResult VKAPI vkDestroySwapChainWSI(
VkSwapChainWSI swapChain)
{
loader_platform_thread_lock_mutex(&globalLock);
if (swapChainMap.find(swapChain) != swapChainMap.end()) {
MT_SWAP_CHAIN_INFO* pInfo = swapChainMap[swapChain];
if (pInfo->images.size() > 0) {
for (std::vector<VkSwapChainImageInfoWSI>::const_iterator it = pInfo->images.begin();
it != pInfo->images.end(); it++) {
clearObjectBinding(it->image);
freeMemObjInfo(it->memory, true);
MT_OBJ_INFO* pDelInfo = objectMap[it->image];
delete pDelInfo;
objectMap.erase(it->image);
}
}
delete pInfo;
swapChainMap.erase(swapChain);
}
loader_platform_thread_unlock_mutex(&globalLock);
return nextTable.DestroySwapChainWSI(swapChain);
}
VK_LAYER_EXPORT VkResult VKAPI vkGetSwapChainInfoWSI(
VkSwapChainWSI swapChain,
VkSwapChainInfoTypeWSI infoType,
size_t *pDataSize,
void *pData)
{
VkResult result = nextTable.GetSwapChainInfoWSI(swapChain, infoType, pDataSize, pData);
if (infoType == VK_SWAP_CHAIN_INFO_TYPE_PERSISTENT_IMAGES_WSI && result == VK_SUCCESS) {
const size_t count = *pDataSize / sizeof(VkSwapChainImageInfoWSI);
MT_SWAP_CHAIN_INFO *pInfo = swapChainMap[swapChain];
if (pInfo->images.empty()) {
pInfo->images.resize(count);
memcpy(&pInfo->images[0], pData, sizeof(pInfo->images[0]) * count);
if (pInfo->images.size() > 0) {
for (std::vector<VkSwapChainImageInfoWSI>::const_iterator it = pInfo->images.begin();
it != pInfo->images.end(); it++) {
// Add image object, then insert the new Mem Object and then bind it to created image
addObjectInfo(it->image, VK_STRUCTURE_TYPE_MAX_ENUM, &pInfo->createInfo, sizeof(pInfo->createInfo), "persistent_image");
addMemObjInfo(it->memory, NULL);
if (VK_FALSE == updateObjectBinding(it->image, it->memory)) {
char str[1024];
sprintf(str, "In vkGetSwapChainInfoWSI(), unable to set image %p binding to mem obj %p", (void*)it->image, (void*)it->memory);
layerCbMsg(VK_DBG_MSG_ERROR, VK_VALIDATION_LEVEL_0, it->image, 0, MEMTRACK_MEMORY_BINDING_ERROR, "MEM", str);
}
}
}
} else {
const bool mismatch = (pInfo->images.size() != count ||
memcmp(&pInfo->images[0], pData, sizeof(pInfo->images[0]) * count));
if (mismatch) {
char str[1024];
sprintf(str, "vkGetSwapChainInfoWSI(%p, VK_SWAP_CHAIN_INFO_TYPE_PERSISTENT_IMAGES_WSI) returned mismatching data", swapChain);
layerCbMsg(VK_DBG_MSG_WARNING, VK_VALIDATION_LEVEL_0, (VkObject) swapChain, 0, MEMTRACK_NONE, "SWAP_CHAIN", str);
}
}
}
return result;
}
VK_LAYER_EXPORT void* VKAPI vkGetProcAddr(
VkPhysicalDevice gpu,
const char *funcName)
{
VkBaseLayerObject* gpuw = (VkBaseLayerObject *) gpu;
if (gpu == NULL) {
return NULL;
}
pCurObj = gpuw;
loader_platform_thread_once(&g_initOnce, initMemTracker);
if (!strcmp(funcName, "vkGetProcAddr"))
return (void *) vkGetProcAddr;
if (!strcmp(funcName, "vkCreateDevice"))
return (void*) vkCreateDevice;
if (!strcmp(funcName, "vkDestroyDevice"))
return (void*) vkDestroyDevice;
if (!strcmp(funcName, "vkEnumerateLayers"))
return (void*) vkEnumerateLayers;
if (!strcmp(funcName, "vkQueueSubmit"))
return (void*) vkQueueSubmit;
if (!strcmp(funcName, "vkAllocMemory"))
return (void*) vkAllocMemory;
if (!strcmp(funcName, "vkFreeMemory"))
return (void*) vkFreeMemory;
if (!strcmp(funcName, "vkSetMemoryPriority"))
return (void*) vkSetMemoryPriority;
if (!strcmp(funcName, "vkMapMemory"))
return (void*) vkMapMemory;
if (!strcmp(funcName, "vkUnmapMemory"))
return (void*) vkUnmapMemory;
if (!strcmp(funcName, "vkPinSystemMemory"))
return (void*) vkPinSystemMemory;
if (!strcmp(funcName, "vkOpenSharedMemory"))
return (void*) vkOpenSharedMemory;
if (!strcmp(funcName, "vkOpenPeerMemory"))
return (void*) vkOpenPeerMemory;
if (!strcmp(funcName, "vkOpenPeerImage"))
return (void*) vkOpenPeerImage;
if (!strcmp(funcName, "vkDestroyObject"))
return (void*) vkDestroyObject;
if (!strcmp(funcName, "vkGetObjectInfo"))
return (void*) vkGetObjectInfo;
if (!strcmp(funcName, "vkQueueBindObjectMemory"))
return (void*) vkQueueBindObjectMemory;
if (!strcmp(funcName, "vkQueueBindObjectMemoryRange"))
return (void*) vkQueueBindObjectMemoryRange;
if (!strcmp(funcName, "vkCreateFence"))
return (void*) vkCreateFence;
if (!strcmp(funcName, "vkGetFenceStatus"))
return (void*) vkGetFenceStatus;
if (!strcmp(funcName, "vkResetFences"))
return (void*) vkResetFences;
if (!strcmp(funcName, "vkWaitForFences"))
return (void*) vkWaitForFences;
if (!strcmp(funcName, "vkQueueWaitIdle"))
return (void*) vkQueueWaitIdle;
if (!strcmp(funcName, "vkDeviceWaitIdle"))
return (void*) vkDeviceWaitIdle;
if (!strcmp(funcName, "vkCreateEvent"))
return (void*) vkCreateEvent;
if (!strcmp(funcName, "vkCreateQueryPool"))
return (void*) vkCreateQueryPool;
if (!strcmp(funcName, "vkCreateBuffer"))
return (void*) vkCreateBuffer;
if (!strcmp(funcName, "vkCreateBufferView"))
return (void*) vkCreateBufferView;
if (!strcmp(funcName, "vkCreateImage"))
return (void*) vkCreateImage;
if (!strcmp(funcName, "vkCreateImageView"))
return (void*) vkCreateImageView;
if (!strcmp(funcName, "vkCreateColorAttachmentView"))
return (void*) vkCreateColorAttachmentView;
if (!strcmp(funcName, "vkCreateDepthStencilView"))
return (void*) vkCreateDepthStencilView;
if (!strcmp(funcName, "vkCreateShader"))
return (void*) vkCreateShader;
if (!strcmp(funcName, "vkCreateGraphicsPipeline"))
return (void*) vkCreateGraphicsPipeline;
if (!strcmp(funcName, "vkCreateGraphicsPipelineDerivative"))
return (void*) vkCreateGraphicsPipelineDerivative;
if (!strcmp(funcName, "vkCreateComputePipeline"))
return (void*) vkCreateComputePipeline;
if (!strcmp(funcName, "vkCreateSampler"))
return (void*) vkCreateSampler;
if (!strcmp(funcName, "vkCreateDynamicViewportState"))
return (void*) vkCreateDynamicViewportState;
if (!strcmp(funcName, "vkCreateDynamicRasterState"))
return (void*) vkCreateDynamicRasterState;
if (!strcmp(funcName, "vkCreateDynamicColorBlendState"))
return (void*) vkCreateDynamicColorBlendState;
if (!strcmp(funcName, "vkCreateDynamicDepthStencilState"))
return (void*) vkCreateDynamicDepthStencilState;
if (!strcmp(funcName, "vkCreateCommandBuffer"))
return (void*) vkCreateCommandBuffer;
if (!strcmp(funcName, "vkBeginCommandBuffer"))
return (void*) vkBeginCommandBuffer;
if (!strcmp(funcName, "vkEndCommandBuffer"))
return (void*) vkEndCommandBuffer;
if (!strcmp(funcName, "vkResetCommandBuffer"))
return (void*) vkResetCommandBuffer;
if (!strcmp(funcName, "vkCmdBindPipeline"))
return (void*) vkCmdBindPipeline;
if (!strcmp(funcName, "vkCmdBindDynamicStateObject"))
return (void*) vkCmdBindDynamicStateObject;
if (!strcmp(funcName, "vkCmdBindDescriptorSets"))
return (void*) vkCmdBindDescriptorSets;
if (!strcmp(funcName, "vkCmdBindVertexBuffers"))
return (void*) vkCmdBindVertexBuffers;
if (!strcmp(funcName, "vkCmdBindIndexBuffer"))
return (void*) vkCmdBindIndexBuffer;
if (!strcmp(funcName, "vkCmdDrawIndirect"))
return (void*) vkCmdDrawIndirect;
if (!strcmp(funcName, "vkCmdDrawIndexedIndirect"))
return (void*) vkCmdDrawIndexedIndirect;
if (!strcmp(funcName, "vkCmdDispatchIndirect"))
return (void*) vkCmdDispatchIndirect;
if (!strcmp(funcName, "vkCmdCopyBuffer"))
return (void*) vkCmdCopyBuffer;
if (!strcmp(funcName, "vkCmdCopyImage"))
return (void*) vkCmdCopyImage;
if (!strcmp(funcName, "vkCmdCopyBufferToImage"))
return (void*) vkCmdCopyBufferToImage;
if (!strcmp(funcName, "vkCmdCopyImageToBuffer"))
return (void*) vkCmdCopyImageToBuffer;
if (!strcmp(funcName, "vkCmdCloneImageData"))
return (void*) vkCmdCloneImageData;
if (!strcmp(funcName, "vkCmdUpdateBuffer"))
return (void*) vkCmdUpdateBuffer;
if (!strcmp(funcName, "vkCmdFillBuffer"))
return (void*) vkCmdFillBuffer;
if (!strcmp(funcName, "vkCmdClearColorImage"))
return (void*) vkCmdClearColorImage;
if (!strcmp(funcName, "vkCmdClearDepthStencil"))
return (void*) vkCmdClearDepthStencil;
if (!strcmp(funcName, "vkCmdResolveImage"))
return (void*) vkCmdResolveImage;
if (!strcmp(funcName, "vkCmdBeginQuery"))
return (void*) vkCmdBeginQuery;
if (!strcmp(funcName, "vkCmdEndQuery"))
return (void*) vkCmdEndQuery;
if (!strcmp(funcName, "vkCmdResetQueryPool"))
return (void*) vkCmdResetQueryPool;
if (!strcmp(funcName, "vkDbgRegisterMsgCallback"))
return (void*) vkDbgRegisterMsgCallback;
if (!strcmp(funcName, "vkDbgUnregisterMsgCallback"))
return (void*) vkDbgUnregisterMsgCallback;
if (!strcmp(funcName, "vkGetDeviceQueue"))
return (void*) vkGetDeviceQueue;
if (!strcmp(funcName, "vkQueueAddMemReferences"))
return (void*) vkQueueAddMemReferences;
if (!strcmp(funcName, "vkQueueRemoveMemReferences"))
return (void*) vkQueueRemoveMemReferences;
if (!strcmp(funcName, "vkCreateSwapChainWSI"))
return (void*) vkCreateSwapChainWSI;
if (!strcmp(funcName, "vkDestroySwapChainWSI"))
return (void*) vkDestroySwapChainWSI;
if (!strcmp(funcName, "vkGetSwapChainInfoWSI"))
return (void*) vkGetSwapChainInfoWSI;
else {
if (gpuw->pGPA == NULL) {
return NULL;
}
return gpuw->pGPA((VkPhysicalDevice)gpuw->nextObject, funcName);
}
}