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/** @file Implementation of the post processing step to improve the cache locality of a mesh.
*
* The algorithm is roughly basing on this paper:
* http://www.cs.princeton.edu/gfx/pubs/Sander_2007_%3ETR/tipsy.pdf
* .. although overdraw reduction isn't implemented yet ...
*/
// internal headers
#include "PostProcessing/ImproveCacheLocality.h"
#include "Common/VertexTriangleAdjacency.h"
#include
#include
#include
#include
#include
#include
namespace Assimp {
// ------------------------------------------------------------------------------------------------
// Constructor to be privately used by Importer
ImproveCacheLocalityProcess::ImproveCacheLocalityProcess() :
mConfigCacheDepth(PP_ICL_PTCACHE_SIZE) {
// empty
}
// ------------------------------------------------------------------------------------------------
// Returns whether the processing step is present in the given flag field.
bool ImproveCacheLocalityProcess::IsActive(unsigned int pFlags) const {
return (pFlags & aiProcess_ImproveCacheLocality) != 0;
}
// ------------------------------------------------------------------------------------------------
// Setup configuration
void ImproveCacheLocalityProcess::SetupProperties(const Importer *pImp) {
// AI_CONFIG_PP_ICL_PTCACHE_SIZE controls the target cache size for the optimizer
mConfigCacheDepth = pImp->GetPropertyInteger(AI_CONFIG_PP_ICL_PTCACHE_SIZE, PP_ICL_PTCACHE_SIZE);
}
// ------------------------------------------------------------------------------------------------
// Executes the post processing step on the given imported data.
void ImproveCacheLocalityProcess::Execute(aiScene *pScene) {
if (!pScene->mNumMeshes) {
ASSIMP_LOG_DEBUG("ImproveCacheLocalityProcess skipped; there are no meshes");
return;
}
ASSIMP_LOG_DEBUG("ImproveCacheLocalityProcess begin");
float out = 0.f;
unsigned int numf = 0, numm = 0;
for (unsigned int a = 0; a < pScene->mNumMeshes; ++a) {
const float res = ProcessMesh(pScene->mMeshes[a], a);
if (res) {
numf += pScene->mMeshes[a]->mNumFaces;
out += res;
++numm;
}
}
if (!DefaultLogger::isNullLogger()) {
if (numf > 0) {
ASSIMP_LOG_INFO("Cache relevant are ", numm, " meshes (", numf, " faces). Average output ACMR is ", out / numf);
}
ASSIMP_LOG_DEBUG("ImproveCacheLocalityProcess finished. ");
}
}
// ------------------------------------------------------------------------------------------------
static ai_real calculateInputACMR(aiMesh *pMesh, const aiFace *const pcEnd,
unsigned int configCacheDepth, unsigned int meshNum) {
ai_real fACMR = 0.0f;
unsigned int *piFIFOStack = new unsigned int[configCacheDepth];
memset(piFIFOStack, 0xff, configCacheDepth * sizeof(unsigned int));
unsigned int *piCur = piFIFOStack;
const unsigned int *const piCurEnd = piFIFOStack + configCacheDepth;
// count the number of cache misses
unsigned int iCacheMisses = 0;
for (const aiFace *pcFace = pMesh->mFaces; pcFace != pcEnd; ++pcFace) {
for (unsigned int qq = 0; qq < 3; ++qq) {
bool bInCache = false;
for (unsigned int *pp = piFIFOStack; pp < piCurEnd; ++pp) {
if (*pp == pcFace->mIndices[qq]) {
// the vertex is in cache
bInCache = true;
break;
}
}
if (!bInCache) {
++iCacheMisses;
if (piCurEnd == piCur) {
piCur = piFIFOStack;
}
*piCur++ = pcFace->mIndices[qq];
}
}
}
delete[] piFIFOStack;
fACMR = (ai_real)iCacheMisses / pMesh->mNumFaces;
if (3.0 == fACMR) {
char szBuff[128]; // should be sufficiently large in every case
// the JoinIdenticalVertices process has not been executed on this
// mesh, otherwise this value would normally be at least minimally
// smaller than 3.0 ...
ai_snprintf(szBuff, 128, "Mesh %u: Not suitable for vcache optimization", meshNum);
ASSIMP_LOG_WARN(szBuff);
return static_cast(0.f);
}
return fACMR;
}
// ------------------------------------------------------------------------------------------------
// Improves the cache coherency of a specific mesh
ai_real ImproveCacheLocalityProcess::ProcessMesh(aiMesh *pMesh, unsigned int meshNum) {
// TODO: rewrite this to use std::vector or boost::shared_array
ai_assert(nullptr != pMesh);
// Check whether the input data is valid
// - there must be vertices and faces
// - all faces must be triangulated or we can't operate on them
if (!pMesh->HasFaces() || !pMesh->HasPositions())
return static_cast(0.f);
if (pMesh->mPrimitiveTypes != aiPrimitiveType_TRIANGLE) {
ASSIMP_LOG_ERROR("This algorithm works on triangle meshes only");
return static_cast(0.f);
}
if (pMesh->mNumVertices <= mConfigCacheDepth) {
return static_cast(0.f);
}
ai_real fACMR = 3.f;
const aiFace *const pcEnd = pMesh->mFaces + pMesh->mNumFaces;
// Input ACMR is for logging purposes only
if (!DefaultLogger::isNullLogger()) {
fACMR = calculateInputACMR(pMesh, pcEnd, mConfigCacheDepth, meshNum);
}
// first we need to build a vertex-triangle adjacency list
VertexTriangleAdjacency adj(pMesh->mFaces, pMesh->mNumFaces, pMesh->mNumVertices, true);
// build a list to store per-vertex caching time stamps
std::vector piCachingStamps;
piCachingStamps.resize(pMesh->mNumVertices);
memset(&piCachingStamps[0], 0x0, pMesh->mNumVertices * sizeof(unsigned int));
// allocate an empty output index buffer. We store the output indices in one large array.
// Since the number of triangles won't change the input faces can be reused. This is how
// we save thousands of redundant mini allocations for aiFace::mIndices
const unsigned int iIdxCnt = pMesh->mNumFaces * 3;
std::vector piIBOutput;
piIBOutput.resize(iIdxCnt);
std::vector::iterator piCSIter = piIBOutput.begin();
// allocate the flag array to hold the information
// whether a face has already been emitted or not
std::vector abEmitted(pMesh->mNumFaces, false);
// dead-end vertex index stack
std::stack> sDeadEndVStack;
// create a copy of the piNumTriPtr buffer
unsigned int *const piNumTriPtr = adj.mLiveTriangles;
const std::vector piNumTriPtrNoModify(piNumTriPtr, piNumTriPtr + pMesh->mNumVertices);
// get the largest number of referenced triangles and allocate the "candidate buffer"
unsigned int iMaxRefTris = 0;
{
const unsigned int *piCur = adj.mLiveTriangles;
const unsigned int *const piCurEnd = adj.mLiveTriangles + pMesh->mNumVertices;
for (; piCur != piCurEnd; ++piCur) {
iMaxRefTris = std::max(iMaxRefTris, *piCur);
}
}
ai_assert(iMaxRefTris > 0);
std::vector piCandidates;
piCandidates.resize(iMaxRefTris * 3);
unsigned int iCacheMisses = 0;
// ...................................................................................
/** PSEUDOCODE for the algorithm
A = Build-Adjacency(I) Vertex-triangle adjacency
L = Get-Triangle-Counts(A) Per-vertex live triangle counts
C = Zero(Vertex-Count(I)) Per-vertex caching time stamps
D = Empty-Stack() Dead-end vertex stack
E = False(Triangle-Count(I)) Per triangle emitted flag
O = Empty-Index-Buffer() Empty output buffer
f = 0 Arbitrary starting vertex
s = k+1, i = 1 Time stamp and cursor
while f >= 0 For all valid fanning vertices
N = Empty-Set() 1-ring of next candidates
for each Triangle t in Neighbors(A, f)
if !Emitted(E,t)
for each Vertex v in t
Append(O,v) Output vertex
Push(D,v) Add to dead-end stack
Insert(N,v) Register as candidate
L[v] = L[v]-1 Decrease live triangle count
if s-C[v] > k If not in cache
C[v] = s Set time stamp
s = s+1 Increment time stamp
E[t] = true Flag triangle as emitted
Select next fanning vertex
f = Get-Next-Vertex(I,i,k,N,C,s,L,D)
return O
*/
// ...................................................................................
int ivdx = 0;
int ics = 1;
int iStampCnt = mConfigCacheDepth + 1;
while (ivdx >= 0) {
unsigned int icnt = piNumTriPtrNoModify[ivdx];
unsigned int *piList = adj.GetAdjacentTriangles(ivdx);
std::vector::iterator piCurCandidate = piCandidates.begin();
// get all triangles in the neighborhood
for (unsigned int tri = 0; tri < icnt; ++tri) {
// if they have not yet been emitted, add them to the output IB
const unsigned int fidx = *piList++;
if (!abEmitted[fidx]) {
// so iterate through all vertices of the current triangle
const aiFace *pcFace = &pMesh->mFaces[fidx];
const unsigned nind = pcFace->mNumIndices;
for (unsigned ind = 0; ind < nind; ind++) {
unsigned dp = pcFace->mIndices[ind];
// the current vertex won't have any free triangles after this step
if (ivdx != (int)dp) {
// append the vertex to the dead-end stack
sDeadEndVStack.push(dp);
// register as candidate for the next step
*piCurCandidate++ = dp;
// decrease the per-vertex triangle counts
piNumTriPtr[dp]--;
}
// append the vertex to the output index buffer
*piCSIter++ = dp;
// if the vertex is not yet in cache, set its cache count
if (iStampCnt - piCachingStamps[dp] > mConfigCacheDepth) {
piCachingStamps[dp] = iStampCnt++;
++iCacheMisses;
}
}
// flag triangle as emitted
abEmitted[fidx] = true;
}
}
// the vertex has now no living adjacent triangles anymore
piNumTriPtr[ivdx] = 0;
// get next fanning vertex
ivdx = -1;
int max_priority = -1;
for (std::vector::iterator piCur = piCandidates.begin(); piCur != piCurCandidate; ++piCur) {
const unsigned int dp = *piCur;
// must have live triangles
if (piNumTriPtr[dp] > 0) {
int priority = 0;
// will the vertex be in cache, even after fanning occurs?
unsigned int tmp;
if ((tmp = iStampCnt - piCachingStamps[dp]) + 2 * piNumTriPtr[dp] <= mConfigCacheDepth) {
priority = tmp;
}
// keep best candidate
if (priority > max_priority) {
max_priority = priority;
ivdx = dp;
}
}
}
// did we reach a dead end?
if (-1 == ivdx) {
// need to get a non-local vertex for which we have a good chance that it is still
// in the cache ...
while (!sDeadEndVStack.empty()) {
unsigned int iCachedIdx = sDeadEndVStack.top();
sDeadEndVStack.pop();
if (piNumTriPtr[iCachedIdx] > 0) {
ivdx = iCachedIdx;
break;
}
}
if (-1 == ivdx) {
// well, there isn't such a vertex. Simply get the next vertex in input order and
// hope it is not too bad ...
while (ics < (int)pMesh->mNumVertices) {
++ics;
if (piNumTriPtr[ics] > 0) {
ivdx = ics;
break;
}
}
}
}
}
ai_real fACMR2 = 0.0f;
if (!DefaultLogger::isNullLogger()) {
fACMR2 = static_cast(iCacheMisses / pMesh->mNumFaces);
const ai_real averageACMR = ((fACMR - fACMR2) / fACMR) * 100.f;
// very intense verbose logging ... prepare for much text if there are many meshes
if (DefaultLogger::get()->getLogSeverity() == Logger::VERBOSE) {
ASSIMP_LOG_VERBOSE_DEBUG("Mesh ", meshNum, "| ACMR in: ", fACMR, " out: ", fACMR2, " | average ACMR ", averageACMR);
}
fACMR2 *= pMesh->mNumFaces;
}
// sort the output index buffer back to the input array
piCSIter = piIBOutput.begin();
for (aiFace *pcFace = pMesh->mFaces; pcFace != pcEnd; ++pcFace) {
unsigned nind = pcFace->mNumIndices;
unsigned *ind = pcFace->mIndices;
if (nind > 0)
ind[0] = *piCSIter++;
if (nind > 1)
ind[1] = *piCSIter++;
if (nind > 2)
ind[2] = *piCSIter++;
}
return fACMR2;
}
} // namespace Assimp