Data structures sepatared for aligned memory access.

This commit is contained in:
Dario Manesku 2013-11-13 17:53:44 +01:00
parent d7647a4cb7
commit 0381c60b6d

View file

@ -11,6 +11,7 @@ using namespace std::tr1;
#include <bgfx.h>
#include <bx/timer.h>
#include <bx/readerwriter.h>
#include <bx/allocator.h>
#include <bx/float4_t.h>
#include "entry/entry.h"
#include "fpumath.h"
@ -697,24 +698,16 @@ typedef std::vector<Face> FaceArray;
struct Edge
{
Edge(const float* _v0, const float* _v1)
: m_faceIndex(0)
{
memcpy(m_v0, _v0, 3*sizeof(float) );
memcpy(m_v1, _v1, 3*sizeof(float) );
}
struct Plane
{
float m_plane[4];
};
Plane m_face[2];
bool m_faceReverseOrder[2];
uint8_t m_faceIndex;
float m_v0[3], m_v1[3];
};
struct Plane
{
float m_plane[4];
};
struct HalfEdge
{
#define INVALID_EDGE_INDEX UINT16_MAX
@ -840,6 +833,7 @@ struct Group
m_indices = NULL;
m_numEdges = 0;
m_edges = NULL;
m_edgePlanesUnalignedPtr = NULL;
m_prims.clear();
}
@ -882,8 +876,24 @@ struct Group
//init faces and edges
m_faces.reserve(m_numIndices/3); //1 face = 3 indices
m_edges = (Edge*)malloc(m_numIndices * sizeof(Edge)); //1 triangle = 3 indices = 3 edges.
m_edgePlanesUnalignedPtr = (Plane*)malloc(m_numIndices * sizeof(Plane) + 15);
m_edgePlanes = (Plane*)bx::alignPtr(m_edgePlanesUnalignedPtr, 0, 16);
typedef std::map<f6_t, Edge, EdgeComparator> EdgeMap;
struct EdgeAndPlane
{
EdgeAndPlane(const float* _v0, const float* _v1)
: m_faceIndex(0)
{
memcpy(m_v0, _v0, 3*sizeof(float) );
memcpy(m_v1, _v1, 3*sizeof(float) );
}
bool m_faceReverseOrder[2];
uint8_t m_faceIndex;
float m_v0[3], m_v1[3];
Plane m_plane[2];
};
typedef std::map<f6_t, EdgeAndPlane, EdgeComparator> EdgeMap;
EdgeMap edgeMap;
for (uint32_t ii = 0, size = m_numIndices/3; ii < size; ++ii)
@ -927,24 +937,32 @@ struct Group
EdgeMap::iterator iter = edgeMap.find(keyInv);
if (iter != edgeMap.end())
{
Edge& edge = iter->second;
memcpy(edge.m_face[edge.m_faceIndex].m_plane, plane, 4*sizeof(float) );
edge.m_faceReverseOrder[edge.m_faceIndex] = true;
EdgeAndPlane& ep = iter->second;
memcpy(ep.m_plane[ep.m_faceIndex].m_plane, plane, 4*sizeof(float) );
ep.m_faceReverseOrder[ep.m_faceIndex] = true;
}
else
{
std::pair<EdgeMap::iterator, bool> result = edgeMap.insert(std::make_pair(key, Edge(v0, v1)) );
Edge& edge = result.first->second;
memcpy(edge.m_face[edge.m_faceIndex].m_plane, plane, 4*sizeof(float) );
edge.m_faceReverseOrder[edge.m_faceIndex] = false;
edge.m_faceIndex++;
std::pair<EdgeMap::iterator, bool> result = edgeMap.insert(std::make_pair(key, EdgeAndPlane(v0, v1)) );
EdgeAndPlane& ep = result.first->second;
memcpy(ep.m_plane[ep.m_faceIndex].m_plane, plane, 4*sizeof(float) );
ep.m_faceReverseOrder[ep.m_faceIndex] = false;
ep.m_faceIndex++;
}
}
}
uint32_t index = 0;
for (EdgeMap::const_iterator iter = edgeMap.begin(), end = edgeMap.end(); iter != end; ++iter)
{
memcpy(&m_edges[m_numEdges++], &iter->second, sizeof(Edge));
Edge* edge = &m_edges[m_numEdges];
Plane* plane = &m_edgePlanes[index];
memcpy(edge, iter->second.m_faceReverseOrder, sizeof(Edge));
memcpy(plane, iter->second.m_plane, 2 * sizeof(Plane));
m_numEdges++;
index += 2;
}
}
@ -961,6 +979,8 @@ struct Group
m_indices = NULL;
free(m_edges);
m_edges = NULL;
free(m_edgePlanesUnalignedPtr);
m_edgePlanesUnalignedPtr = NULL;
m_halfEdges.destroy();
}
@ -976,6 +996,8 @@ struct Group
PrimitiveArray m_prims;
uint32_t m_numEdges;
Edge* m_edges;
Plane* m_edgePlanesUnalignedPtr;
Plane* m_edgePlanes;
FaceArray m_faces;
HalfEdges m_halfEdges;
};
@ -1355,11 +1377,12 @@ void shadowVolumeCreate(ShadowVolume& _shadowVolume
, bool _textureAsStencil = false
)
{
const uint8_t* vertices = _group.m_vertices;
const FaceArray& faces = _group.m_faces;
const Edge* edges = _group.m_edges;
const uint32_t numEdges = _group.m_numEdges;
HalfEdges& halfEdges = _group.m_halfEdges;
const uint8_t* vertices = _group.m_vertices;
const FaceArray& faces = _group.m_faces;
const Edge* edges = _group.m_edges;
const Plane* edgePlanes = _group.m_edgePlanes;
const uint32_t numEdges = _group.m_numEdges;
HalfEdges& halfEdges = _group.m_halfEdges;
struct VertexData
{
@ -1500,7 +1523,7 @@ void shadowVolumeCreate(ShadowVolume& _shadowVolume
uint32_t ii = 0;
#if SV_USE_SIMD
uint32_t numEdgesRounded = uint32_t(numEdges / 2) * 2;
uint32_t numEdgesRounded = numEdges & (~0x1);
using namespace bx;
@ -1512,6 +1535,8 @@ void shadowVolumeCreate(ShadowVolume& _shadowVolume
{
const Edge& edge0 = edges[ii];
const Edge& edge1 = edges[ii+1];
const Plane* edgePlane0 = &edgePlanes[ii*2];
const Plane* edgePlane1 = &edgePlanes[ii*2 + 2];
const float4_t reverse = float4_ild(edge0.m_faceReverseOrder[0]
, edge1.m_faceReverseOrder[0]
@ -1519,10 +1544,10 @@ void shadowVolumeCreate(ShadowVolume& _shadowVolume
, edge1.m_faceReverseOrder[1]
);
const float4_t v0 = float4_ldu(edge0.m_face[0].m_plane);
const float4_t v1 = float4_ldu(edge1.m_face[0].m_plane);
const float4_t v2 = float4_ldu(edge0.m_face[1].m_plane);
const float4_t v3 = float4_ldu(edge1.m_face[1].m_plane);
const float4_t v0 = float4_ld(edgePlane0[0].m_plane);
const float4_t v1 = float4_ld(edgePlane1[0].m_plane);
const float4_t v2 = float4_ld(edgePlane0[1].m_plane);
const float4_t v3 = float4_ld(edgePlane1[1].m_plane);
const float4_t xxyy0 = float4_shuf_xAyB(v0, v2);
const float4_t zzww0 = float4_shuf_zCwD(v0, v2);
@ -1583,11 +1608,10 @@ void shadowVolumeCreate(ShadowVolume& _shadowVolume
for (; ii < numEdges; ++ii)
{
const Edge& edge = edges[ii];
const Edge::Plane& face0 = edge.m_face[0];
const Edge::Plane& face1 = edge.m_face[1];
const Plane* edgePlane = &edgePlanes[ii*2];
int16_t s0 = ( (vec3Dot(face0.m_plane, _light) + face0.m_plane[3]) > 0.0f) ^ edge.m_faceReverseOrder[0];
int16_t s1 = ( (vec3Dot(face1.m_plane, _light) + face1.m_plane[3]) > 0.0f) ^ edge.m_faceReverseOrder[1];
int16_t s0 = ( (vec3Dot(edgePlane[0].m_plane, _light) + edgePlane[0].m_plane[3]) > 0.0f) ^ edge.m_faceReverseOrder[0];
int16_t s1 = ( (vec3Dot(edgePlane[1].m_plane, _light) + edgePlane[1].m_plane[3]) > 0.0f) ^ edge.m_faceReverseOrder[1];
int16_t k = ( (s0 + s1) << 1) - 2;
if (k != 0)