pandemonium_engine_minimal/thirdparty/recastnavigation/Recast/Source/RecastRasterization.cpp
2023-12-14 21:54:22 +01:00

557 lines
17 KiB
C++

//
// Copyright (c) 2009-2010 Mikko Mononen memon@inside.org
//
// This software is provided 'as-is', without any express or implied
// warranty. In no event will the authors be held liable for any damages
// arising from the use of this software.
// Permission is granted to anyone to use this software for any purpose,
// including commercial applications, and to alter it and redistribute it
// freely, subject to the following restrictions:
// 1. The origin of this software must not be misrepresented; you must not
// claim that you wrote the original software. If you use this software
// in a product, an acknowledgment in the product documentation would be
// appreciated but is not required.
// 2. Altered source versions must be plainly marked as such, and must not be
// misrepresented as being the original software.
// 3. This notice may not be removed or altered from any source distribution.
//
#include <math.h>
#include <stdio.h>
#include "Recast.h"
#include "RecastAlloc.h"
#include "RecastAssert.h"
/// Check whether two bounding boxes overlap
///
/// @param[in] aMin Min axis extents of bounding box A
/// @param[in] aMax Max axis extents of bounding box A
/// @param[in] bMin Min axis extents of bounding box B
/// @param[in] bMax Max axis extents of bounding box B
/// @returns true if the two bounding boxes overlap. False otherwise.
static bool overlapBounds(const float* aMin, const float* aMax, const float* bMin, const float* bMax)
{
return
aMin[0] <= bMax[0] && aMax[0] >= bMin[0] &&
aMin[1] <= bMax[1] && aMax[1] >= bMin[1] &&
aMin[2] <= bMax[2] && aMax[2] >= bMin[2];
}
/// Allocates a new span in the heightfield.
/// Use a memory pool and free list to minimize actual allocations.
///
/// @param[in] hf The heightfield
/// @returns A pointer to the allocated or re-used span memory.
static rcSpan* allocSpan(rcHeightfield& hf)
{
// If necessary, allocate new page and update the freelist.
if (hf.freelist == NULL || hf.freelist->next == NULL)
{
// Create new page.
// Allocate memory for the new pool.
rcSpanPool* spanPool = (rcSpanPool*)rcAlloc(sizeof(rcSpanPool), RC_ALLOC_PERM);
if (spanPool == NULL)
{
return NULL;
}
// Add the pool into the list of pools.
spanPool->next = hf.pools;
hf.pools = spanPool;
// Add new spans to the free list.
rcSpan* freeList = hf.freelist;
rcSpan* head = &spanPool->items[0];
rcSpan* it = &spanPool->items[RC_SPANS_PER_POOL];
do
{
--it;
it->next = freeList;
freeList = it;
}
while (it != head);
hf.freelist = it;
}
// Pop item from the front of the free list.
rcSpan* newSpan = hf.freelist;
hf.freelist = hf.freelist->next;
return newSpan;
}
/// Releases the memory used by the span back to the heightfield, so it can be re-used for new spans.
/// @param[in] hf The heightfield.
/// @param[in] span A pointer to the span to free
static void freeSpan(rcHeightfield& hf, rcSpan* span)
{
if (span == NULL)
{
return;
}
// Add the span to the front of the free list.
span->next = hf.freelist;
hf.freelist = span;
}
/// Adds a span to the heightfield. If the new span overlaps existing spans,
/// it will merge the new span with the existing ones.
///
/// @param[in] hf Heightfield to add spans to
/// @param[in] x The new span's column cell x index
/// @param[in] z The new span's column cell z index
/// @param[in] min The new span's minimum cell index
/// @param[in] max The new span's maximum cell index
/// @param[in] areaID The new span's area type ID
/// @param[in] flagMergeThreshold How close two spans maximum extents need to be to merge area type IDs
static bool addSpan(rcHeightfield& hf,
const int x, const int z,
const unsigned short min, const unsigned short max,
const unsigned char areaID, const int flagMergeThreshold)
{
// Create the new span.
rcSpan* newSpan = allocSpan(hf);
if (newSpan == NULL)
{
return false;
}
newSpan->smin = min;
newSpan->smax = max;
newSpan->area = areaID;
newSpan->next = NULL;
const int columnIndex = x + z * hf.width;
rcSpan* previousSpan = NULL;
rcSpan* currentSpan = hf.spans[columnIndex];
// Insert the new span, possibly merging it with existing spans.
while (currentSpan != NULL)
{
if (currentSpan->smin > newSpan->smax)
{
// Current span is completely after the new span, break.
break;
}
if (currentSpan->smax < newSpan->smin)
{
// Current span is completely before the new span. Keep going.
previousSpan = currentSpan;
currentSpan = currentSpan->next;
}
else
{
// The new span overlaps with an existing span. Merge them.
if (currentSpan->smin < newSpan->smin)
{
newSpan->smin = currentSpan->smin;
}
if (currentSpan->smax > newSpan->smax)
{
newSpan->smax = currentSpan->smax;
}
// Merge flags.
if (rcAbs((int)newSpan->smax - (int)currentSpan->smax) <= flagMergeThreshold)
{
// Higher area ID numbers indicate higher resolution priority.
newSpan->area = rcMax(newSpan->area, currentSpan->area);
}
// Remove the current span since it's now merged with newSpan.
// Keep going because there might be other overlapping spans that also need to be merged.
rcSpan* next = currentSpan->next;
freeSpan(hf, currentSpan);
if (previousSpan)
{
previousSpan->next = next;
}
else
{
hf.spans[columnIndex] = next;
}
currentSpan = next;
}
}
// Insert new span after prev
if (previousSpan != NULL)
{
newSpan->next = previousSpan->next;
previousSpan->next = newSpan;
}
else
{
// This span should go before the others in the list
newSpan->next = hf.spans[columnIndex];
hf.spans[columnIndex] = newSpan;
}
return true;
}
bool rcAddSpan(rcContext* context, rcHeightfield& heightfield,
const int x, const int z,
const unsigned short spanMin, const unsigned short spanMax,
const unsigned char areaID, const int flagMergeThreshold)
{
rcAssert(context);
if (!addSpan(heightfield, x, z, spanMin, spanMax, areaID, flagMergeThreshold))
{
context->log(RC_LOG_ERROR, "rcAddSpan: Out of memory.");
return false;
}
return true;
}
enum rcAxis
{
RC_AXIS_X = 0,
RC_AXIS_Y = 1,
RC_AXIS_Z = 2
};
/// Divides a convex polygon of max 12 vertices into two convex polygons
/// across a separating axis.
///
/// @param[in] inVerts The input polygon vertices
/// @param[in] inVertsCount The number of input polygon vertices
/// @param[out] outVerts1 Resulting polygon 1's vertices
/// @param[out] outVerts1Count The number of resulting polygon 1 vertices
/// @param[out] outVerts2 Resulting polygon 2's vertices
/// @param[out] outVerts2Count The number of resulting polygon 2 vertices
/// @param[in] axisOffset THe offset along the specified axis
/// @param[in] axis The separating axis
static void dividePoly(const float* inVerts, int inVertsCount,
float* outVerts1, int* outVerts1Count,
float* outVerts2, int* outVerts2Count,
float axisOffset, rcAxis axis)
{
rcAssert(inVertsCount <= 12);
// How far positive or negative away from the separating axis is each vertex.
float inVertAxisDelta[12];
for (int inVert = 0; inVert < inVertsCount; ++inVert)
{
inVertAxisDelta[inVert] = axisOffset - inVerts[inVert * 3 + axis];
}
int poly1Vert = 0;
int poly2Vert = 0;
for (int inVertA = 0, inVertB = inVertsCount - 1; inVertA < inVertsCount; inVertB = inVertA, ++inVertA)
{
// If the two vertices are on the same side of the separating axis
bool sameSide = (inVertAxisDelta[inVertA] >= 0) == (inVertAxisDelta[inVertB] >= 0);
if (!sameSide)
{
float s = inVertAxisDelta[inVertB] / (inVertAxisDelta[inVertB] - inVertAxisDelta[inVertA]);
outVerts1[poly1Vert * 3 + 0] = inVerts[inVertB * 3 + 0] + (inVerts[inVertA * 3 + 0] - inVerts[inVertB * 3 + 0]) * s;
outVerts1[poly1Vert * 3 + 1] = inVerts[inVertB * 3 + 1] + (inVerts[inVertA * 3 + 1] - inVerts[inVertB * 3 + 1]) * s;
outVerts1[poly1Vert * 3 + 2] = inVerts[inVertB * 3 + 2] + (inVerts[inVertA * 3 + 2] - inVerts[inVertB * 3 + 2]) * s;
rcVcopy(&outVerts2[poly2Vert * 3], &outVerts1[poly1Vert * 3]);
poly1Vert++;
poly2Vert++;
// add the inVertA point to the right polygon. Do NOT add points that are on the dividing line
// since these were already added above
if (inVertAxisDelta[inVertA] > 0)
{
rcVcopy(&outVerts1[poly1Vert * 3], &inVerts[inVertA * 3]);
poly1Vert++;
}
else if (inVertAxisDelta[inVertA] < 0)
{
rcVcopy(&outVerts2[poly2Vert * 3], &inVerts[inVertA * 3]);
poly2Vert++;
}
}
else
{
// add the inVertA point to the right polygon. Addition is done even for points on the dividing line
if (inVertAxisDelta[inVertA] >= 0)
{
rcVcopy(&outVerts1[poly1Vert * 3], &inVerts[inVertA * 3]);
poly1Vert++;
if (inVertAxisDelta[inVertA] != 0)
{
continue;
}
}
rcVcopy(&outVerts2[poly2Vert * 3], &inVerts[inVertA * 3]);
poly2Vert++;
}
}
*outVerts1Count = poly1Vert;
*outVerts2Count = poly2Vert;
}
/// Rasterize a single triangle to the heightfield.
///
/// This code is extremely hot, so much care should be given to maintaining maximum perf here.
///
/// @param[in] v0 Triangle vertex 0
/// @param[in] v1 Triangle vertex 1
/// @param[in] v2 Triangle vertex 2
/// @param[in] areaID The area ID to assign to the rasterized spans
/// @param[in] hf Heightfield to rasterize into
/// @param[in] hfBBMin The min extents of the heightfield bounding box
/// @param[in] hfBBMax The max extents of the heightfield bounding box
/// @param[in] cellSize The x and z axis size of a voxel in the heightfield
/// @param[in] inverseCellSize 1 / cellSize
/// @param[in] inverseCellHeight 1 / cellHeight
/// @param[in] flagMergeThreshold The threshold in which area flags will be merged
/// @returns true if the operation completes successfully. false if there was an error adding spans to the heightfield.
static bool rasterizeTri(const float* v0, const float* v1, const float* v2,
const unsigned char areaID, rcHeightfield& hf,
const float* hfBBMin, const float* hfBBMax,
const float cellSize, const float inverseCellSize, const float inverseCellHeight,
const int flagMergeThreshold)
{
// Calculate the bounding box of the triangle.
float triBBMin[3];
rcVcopy(triBBMin, v0);
rcVmin(triBBMin, v1);
rcVmin(triBBMin, v2);
float triBBMax[3];
rcVcopy(triBBMax, v0);
rcVmax(triBBMax, v1);
rcVmax(triBBMax, v2);
// If the triangle does not touch the bounding box of the heightfield, skip the triangle.
if (!overlapBounds(triBBMin, triBBMax, hfBBMin, hfBBMax))
{
return true;
}
const int w = hf.width;
const int h = hf.height;
const float by = hfBBMax[1] - hfBBMin[1];
// Calculate the footprint of the triangle on the grid's z-axis
int z0 = (int)((triBBMin[2] - hfBBMin[2]) * inverseCellSize);
int z1 = (int)((triBBMax[2] - hfBBMin[2]) * inverseCellSize);
// use -1 rather than 0 to cut the polygon properly at the start of the tile
z0 = rcClamp(z0, -1, h - 1);
z1 = rcClamp(z1, 0, h - 1);
// Clip the triangle into all grid cells it touches.
float buf[7 * 3 * 4];
float* in = buf;
float* inRow = buf + 7 * 3;
float* p1 = inRow + 7 * 3;
float* p2 = p1 + 7 * 3;
rcVcopy(&in[0], v0);
rcVcopy(&in[1 * 3], v1);
rcVcopy(&in[2 * 3], v2);
int nvRow;
int nvIn = 3;
for (int z = z0; z <= z1; ++z)
{
// Clip polygon to row. Store the remaining polygon as well
const float cellZ = hfBBMin[2] + (float)z * cellSize;
dividePoly(in, nvIn, inRow, &nvRow, p1, &nvIn, cellZ + cellSize, RC_AXIS_Z);
rcSwap(in, p1);
if (nvRow < 3)
{
continue;
}
if (z < 0)
{
continue;
}
// find X-axis bounds of the row
float minX = inRow[0];
float maxX = inRow[0];
for (int vert = 1; vert < nvRow; ++vert)
{
if (minX > inRow[vert * 3])
{
minX = inRow[vert * 3];
}
if (maxX < inRow[vert * 3])
{
maxX = inRow[vert * 3];
}
}
int x0 = (int)((minX - hfBBMin[0]) * inverseCellSize);
int x1 = (int)((maxX - hfBBMin[0]) * inverseCellSize);
if (x1 < 0 || x0 >= w)
{
continue;
}
x0 = rcClamp(x0, -1, w - 1);
x1 = rcClamp(x1, 0, w - 1);
int nv;
int nv2 = nvRow;
for (int x = x0; x <= x1; ++x)
{
// Clip polygon to column. store the remaining polygon as well
const float cx = hfBBMin[0] + (float)x * cellSize;
dividePoly(inRow, nv2, p1, &nv, p2, &nv2, cx + cellSize, RC_AXIS_X);
rcSwap(inRow, p2);
if (nv < 3)
{
continue;
}
if (x < 0)
{
continue;
}
// Calculate min and max of the span.
float spanMin = p1[1];
float spanMax = p1[1];
for (int vert = 1; vert < nv; ++vert)
{
spanMin = rcMin(spanMin, p1[vert * 3 + 1]);
spanMax = rcMax(spanMax, p1[vert * 3 + 1]);
}
spanMin -= hfBBMin[1];
spanMax -= hfBBMin[1];
// Skip the span if it's completely outside the heightfield bounding box
if (spanMax < 0.0f)
{
continue;
}
if (spanMin > by)
{
continue;
}
// Clamp the span to the heightfield bounding box.
if (spanMin < 0.0f)
{
spanMin = 0;
}
if (spanMax > by)
{
spanMax = by;
}
// Snap the span to the heightfield height grid.
unsigned short spanMinCellIndex = (unsigned short)rcClamp((int)floorf(spanMin * inverseCellHeight), 0, RC_SPAN_MAX_HEIGHT);
unsigned short spanMaxCellIndex = (unsigned short)rcClamp((int)ceilf(spanMax * inverseCellHeight), (int)spanMinCellIndex + 1, RC_SPAN_MAX_HEIGHT);
if (!addSpan(hf, x, z, spanMinCellIndex, spanMaxCellIndex, areaID, flagMergeThreshold))
{
return false;
}
}
}
return true;
}
bool rcRasterizeTriangle(rcContext* context,
const float* v0, const float* v1, const float* v2,
const unsigned char areaID, rcHeightfield& heightfield, const int flagMergeThreshold)
{
rcAssert(context != NULL);
rcScopedTimer timer(context, RC_TIMER_RASTERIZE_TRIANGLES);
// Rasterize the single triangle.
const float inverseCellSize = 1.0f / heightfield.cs;
const float inverseCellHeight = 1.0f / heightfield.ch;
if (!rasterizeTri(v0, v1, v2, areaID, heightfield, heightfield.bmin, heightfield.bmax, heightfield.cs, inverseCellSize, inverseCellHeight, flagMergeThreshold))
{
context->log(RC_LOG_ERROR, "rcRasterizeTriangle: Out of memory.");
return false;
}
return true;
}
bool rcRasterizeTriangles(rcContext* context,
const float* verts, const int /*nv*/,
const int* tris, const unsigned char* triAreaIDs, const int numTris,
rcHeightfield& heightfield, const int flagMergeThreshold)
{
rcAssert(context != NULL);
rcScopedTimer timer(context, RC_TIMER_RASTERIZE_TRIANGLES);
// Rasterize the triangles.
const float inverseCellSize = 1.0f / heightfield.cs;
const float inverseCellHeight = 1.0f / heightfield.ch;
for (int triIndex = 0; triIndex < numTris; ++triIndex)
{
const float* v0 = &verts[tris[triIndex * 3 + 0] * 3];
const float* v1 = &verts[tris[triIndex * 3 + 1] * 3];
const float* v2 = &verts[tris[triIndex * 3 + 2] * 3];
if (!rasterizeTri(v0, v1, v2, triAreaIDs[triIndex], heightfield, heightfield.bmin, heightfield.bmax, heightfield.cs, inverseCellSize, inverseCellHeight, flagMergeThreshold))
{
context->log(RC_LOG_ERROR, "rcRasterizeTriangles: Out of memory.");
return false;
}
}
return true;
}
bool rcRasterizeTriangles(rcContext* context,
const float* verts, const int /*nv*/,
const unsigned short* tris, const unsigned char* triAreaIDs, const int numTris,
rcHeightfield& heightfield, const int flagMergeThreshold)
{
rcAssert(context != NULL);
rcScopedTimer timer(context, RC_TIMER_RASTERIZE_TRIANGLES);
// Rasterize the triangles.
const float inverseCellSize = 1.0f / heightfield.cs;
const float inverseCellHeight = 1.0f / heightfield.ch;
for (int triIndex = 0; triIndex < numTris; ++triIndex)
{
const float* v0 = &verts[tris[triIndex * 3 + 0] * 3];
const float* v1 = &verts[tris[triIndex * 3 + 1] * 3];
const float* v2 = &verts[tris[triIndex * 3 + 2] * 3];
if (!rasterizeTri(v0, v1, v2, triAreaIDs[triIndex], heightfield, heightfield.bmin, heightfield.bmax, heightfield.cs, inverseCellSize, inverseCellHeight, flagMergeThreshold))
{
context->log(RC_LOG_ERROR, "rcRasterizeTriangles: Out of memory.");
return false;
}
}
return true;
}
bool rcRasterizeTriangles(rcContext* context,
const float* verts, const unsigned char* triAreaIDs, const int numTris,
rcHeightfield& heightfield, const int flagMergeThreshold)
{
rcAssert(context != NULL);
rcScopedTimer timer(context, RC_TIMER_RASTERIZE_TRIANGLES);
// Rasterize the triangles.
const float inverseCellSize = 1.0f / heightfield.cs;
const float inverseCellHeight = 1.0f / heightfield.ch;
for (int triIndex = 0; triIndex < numTris; ++triIndex)
{
const float* v0 = &verts[(triIndex * 3 + 0) * 3];
const float* v1 = &verts[(triIndex * 3 + 1) * 3];
const float* v2 = &verts[(triIndex * 3 + 2) * 3];
if (!rasterizeTri(v0, v1, v2, triAreaIDs[triIndex], heightfield, heightfield.bmin, heightfield.bmax, heightfield.cs, inverseCellSize, inverseCellHeight, flagMergeThreshold))
{
context->log(RC_LOG_ERROR, "rcRasterizeTriangles: Out of memory.");
return false;
}
}
return true;
}