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authormarha <marha@users.sourceforge.net>2009-10-08 13:15:52 +0000
committermarha <marha@users.sourceforge.net>2009-10-08 13:15:52 +0000
commita0c4815433ccd57322f4f7703ca35e9ccfa59250 (patch)
treef5213802ec12adb86ec3136001c1c29fe5343700 /mesalib/src/mesa/swrast/s_aatritemp.h
parentc73dc01b6de45612b24dc2dd34fba24d81ebf46c (diff)
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Added MesaLib-7.6
Diffstat (limited to 'mesalib/src/mesa/swrast/s_aatritemp.h')
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diff --git a/mesalib/src/mesa/swrast/s_aatritemp.h b/mesalib/src/mesa/swrast/s_aatritemp.h
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+/*
+ * Mesa 3-D graphics library
+ * Version: 7.0.3
+ *
+ * Copyright (C) 1999-2007 Brian Paul All Rights Reserved.
+ *
+ * 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
+ * BRIAN PAUL 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.
+ */
+
+
+/*
+ * Antialiased Triangle Rasterizer Template
+ *
+ * This file is #include'd to generate custom AA triangle rasterizers.
+ * NOTE: this code hasn't been optimized yet. That'll come after it
+ * works correctly.
+ *
+ * The following macros may be defined to indicate what auxillary information
+ * must be copmuted across the triangle:
+ * DO_Z - if defined, compute Z values
+ * DO_RGBA - if defined, compute RGBA values
+ * DO_INDEX - if defined, compute color index values
+ * DO_ATTRIBS - if defined, compute texcoords, varying, etc.
+ */
+
+/*void triangle( GLcontext *ctx, GLuint v0, GLuint v1, GLuint v2, GLuint pv )*/
+{
+ const SWcontext *swrast = SWRAST_CONTEXT(ctx);
+ const GLfloat *p0 = v0->attrib[FRAG_ATTRIB_WPOS];
+ const GLfloat *p1 = v1->attrib[FRAG_ATTRIB_WPOS];
+ const GLfloat *p2 = v2->attrib[FRAG_ATTRIB_WPOS];
+ const SWvertex *vMin, *vMid, *vMax;
+ GLint iyMin, iyMax;
+ GLfloat yMin, yMax;
+ GLboolean ltor;
+ GLfloat majDx, majDy; /* major (i.e. long) edge dx and dy */
+
+ SWspan span;
+
+#ifdef DO_Z
+ GLfloat zPlane[4];
+#endif
+#ifdef DO_RGBA
+ GLfloat rPlane[4], gPlane[4], bPlane[4], aPlane[4];
+#endif
+#ifdef DO_INDEX
+ GLfloat iPlane[4];
+#endif
+#if defined(DO_ATTRIBS)
+ GLfloat attrPlane[FRAG_ATTRIB_MAX][4][4];
+ GLfloat wPlane[4]; /* win[3] */
+#endif
+ GLfloat bf = SWRAST_CONTEXT(ctx)->_BackfaceCullSign;
+
+ (void) swrast;
+
+ INIT_SPAN(span, GL_POLYGON);
+ span.arrayMask = SPAN_COVERAGE;
+
+ /* determine bottom to top order of vertices */
+ {
+ GLfloat y0 = v0->attrib[FRAG_ATTRIB_WPOS][1];
+ GLfloat y1 = v1->attrib[FRAG_ATTRIB_WPOS][1];
+ GLfloat y2 = v2->attrib[FRAG_ATTRIB_WPOS][1];
+ if (y0 <= y1) {
+ if (y1 <= y2) {
+ vMin = v0; vMid = v1; vMax = v2; /* y0<=y1<=y2 */
+ }
+ else if (y2 <= y0) {
+ vMin = v2; vMid = v0; vMax = v1; /* y2<=y0<=y1 */
+ }
+ else {
+ vMin = v0; vMid = v2; vMax = v1; bf = -bf; /* y0<=y2<=y1 */
+ }
+ }
+ else {
+ if (y0 <= y2) {
+ vMin = v1; vMid = v0; vMax = v2; bf = -bf; /* y1<=y0<=y2 */
+ }
+ else if (y2 <= y1) {
+ vMin = v2; vMid = v1; vMax = v0; bf = -bf; /* y2<=y1<=y0 */
+ }
+ else {
+ vMin = v1; vMid = v2; vMax = v0; /* y1<=y2<=y0 */
+ }
+ }
+ }
+
+ majDx = vMax->attrib[FRAG_ATTRIB_WPOS][0] - vMin->attrib[FRAG_ATTRIB_WPOS][0];
+ majDy = vMax->attrib[FRAG_ATTRIB_WPOS][1] - vMin->attrib[FRAG_ATTRIB_WPOS][1];
+
+ /* front/back-face determination and cullling */
+ {
+ const GLfloat botDx = vMid->attrib[FRAG_ATTRIB_WPOS][0] - vMin->attrib[FRAG_ATTRIB_WPOS][0];
+ const GLfloat botDy = vMid->attrib[FRAG_ATTRIB_WPOS][1] - vMin->attrib[FRAG_ATTRIB_WPOS][1];
+ const GLfloat area = majDx * botDy - botDx * majDy;
+ /* Do backface culling */
+ if (area * bf < 0 || area == 0 || IS_INF_OR_NAN(area))
+ return;
+ ltor = (GLboolean) (area < 0.0F);
+
+ span.facing = area * swrast->_BackfaceSign > 0.0F;
+ }
+
+ /* Plane equation setup:
+ * We evaluate plane equations at window (x,y) coordinates in order
+ * to compute color, Z, fog, texcoords, etc. This isn't terribly
+ * efficient but it's easy and reliable.
+ */
+#ifdef DO_Z
+ compute_plane(p0, p1, p2, p0[2], p1[2], p2[2], zPlane);
+ span.arrayMask |= SPAN_Z;
+#endif
+#ifdef DO_RGBA
+ if (ctx->Light.ShadeModel == GL_SMOOTH) {
+ compute_plane(p0, p1, p2, v0->color[RCOMP], v1->color[RCOMP], v2->color[RCOMP], rPlane);
+ compute_plane(p0, p1, p2, v0->color[GCOMP], v1->color[GCOMP], v2->color[GCOMP], gPlane);
+ compute_plane(p0, p1, p2, v0->color[BCOMP], v1->color[BCOMP], v2->color[BCOMP], bPlane);
+ compute_plane(p0, p1, p2, v0->color[ACOMP], v1->color[ACOMP], v2->color[ACOMP], aPlane);
+ }
+ else {
+ constant_plane(v2->color[RCOMP], rPlane);
+ constant_plane(v2->color[GCOMP], gPlane);
+ constant_plane(v2->color[BCOMP], bPlane);
+ constant_plane(v2->color[ACOMP], aPlane);
+ }
+ span.arrayMask |= SPAN_RGBA;
+#endif
+#ifdef DO_INDEX
+ if (ctx->Light.ShadeModel == GL_SMOOTH) {
+ compute_plane(p0, p1, p2, (GLfloat) v0->attrib[FRAG_ATTRIB_CI][0],
+ v1->attrib[FRAG_ATTRIB_CI][0], v2->attrib[FRAG_ATTRIB_CI][0], iPlane);
+ }
+ else {
+ constant_plane(v2->attrib[FRAG_ATTRIB_CI][0], iPlane);
+ }
+ span.arrayMask |= SPAN_INDEX;
+#endif
+#if defined(DO_ATTRIBS)
+ {
+ const GLfloat invW0 = v0->attrib[FRAG_ATTRIB_WPOS][3];
+ const GLfloat invW1 = v1->attrib[FRAG_ATTRIB_WPOS][3];
+ const GLfloat invW2 = v2->attrib[FRAG_ATTRIB_WPOS][3];
+ compute_plane(p0, p1, p2, invW0, invW1, invW2, wPlane);
+ span.attrStepX[FRAG_ATTRIB_WPOS][3] = plane_dx(wPlane);
+ span.attrStepY[FRAG_ATTRIB_WPOS][3] = plane_dy(wPlane);
+ ATTRIB_LOOP_BEGIN
+ GLuint c;
+ if (swrast->_InterpMode[attr] == GL_FLAT) {
+ for (c = 0; c < 4; c++) {
+ constant_plane(v2->attrib[attr][c] * invW2, attrPlane[attr][c]);
+ }
+ }
+ else {
+ for (c = 0; c < 4; c++) {
+ const GLfloat a0 = v0->attrib[attr][c] * invW0;
+ const GLfloat a1 = v1->attrib[attr][c] * invW1;
+ const GLfloat a2 = v2->attrib[attr][c] * invW2;
+ compute_plane(p0, p1, p2, a0, a1, a2, attrPlane[attr][c]);
+ }
+ }
+ for (c = 0; c < 4; c++) {
+ span.attrStepX[attr][c] = plane_dx(attrPlane[attr][c]);
+ span.attrStepY[attr][c] = plane_dy(attrPlane[attr][c]);
+ }
+ ATTRIB_LOOP_END
+ }
+#endif
+
+ /* Begin bottom-to-top scan over the triangle.
+ * The long edge will either be on the left or right side of the
+ * triangle. We always scan from the long edge toward the shorter
+ * edges, stopping when we find that coverage = 0. If the long edge
+ * is on the left we scan left-to-right. Else, we scan right-to-left.
+ */
+ yMin = vMin->attrib[FRAG_ATTRIB_WPOS][1];
+ yMax = vMax->attrib[FRAG_ATTRIB_WPOS][1];
+ iyMin = (GLint) yMin;
+ iyMax = (GLint) yMax + 1;
+
+ if (ltor) {
+ /* scan left to right */
+ const GLfloat *pMin = vMin->attrib[FRAG_ATTRIB_WPOS];
+ const GLfloat *pMid = vMid->attrib[FRAG_ATTRIB_WPOS];
+ const GLfloat *pMax = vMax->attrib[FRAG_ATTRIB_WPOS];
+ const GLfloat dxdy = majDx / majDy;
+ const GLfloat xAdj = dxdy < 0.0F ? -dxdy : 0.0F;
+ GLfloat x = pMin[0] - (yMin - iyMin) * dxdy;
+ GLint iy;
+ for (iy = iyMin; iy < iyMax; iy++, x += dxdy) {
+ GLint ix, startX = (GLint) (x - xAdj);
+ GLuint count;
+ GLfloat coverage = 0.0F;
+
+ /* skip over fragments with zero coverage */
+ while (startX < MAX_WIDTH) {
+ coverage = compute_coveragef(pMin, pMid, pMax, startX, iy);
+ if (coverage > 0.0F)
+ break;
+ startX++;
+ }
+
+ /* enter interior of triangle */
+ ix = startX;
+
+#if defined(DO_ATTRIBS)
+ /* compute attributes at left-most fragment */
+ span.attrStart[FRAG_ATTRIB_WPOS][3] = solve_plane(ix + 0.5, iy + 0.5, wPlane);
+ ATTRIB_LOOP_BEGIN
+ GLuint c;
+ for (c = 0; c < 4; c++) {
+ span.attrStart[attr][c] = solve_plane(ix + 0.5, iy + 0.5, attrPlane[attr][c]);
+ }
+ ATTRIB_LOOP_END
+#endif
+
+ count = 0;
+ while (coverage > 0.0F) {
+ /* (cx,cy) = center of fragment */
+ const GLfloat cx = ix + 0.5F, cy = iy + 0.5F;
+ SWspanarrays *array = span.array;
+#ifdef DO_INDEX
+ array->coverage[count] = (GLfloat) compute_coveragei(pMin, pMid, pMax, ix, iy);
+#else
+ array->coverage[count] = coverage;
+#endif
+#ifdef DO_Z
+ array->z[count] = (GLuint) solve_plane(cx, cy, zPlane);
+#endif
+#ifdef DO_RGBA
+ array->rgba[count][RCOMP] = solve_plane_chan(cx, cy, rPlane);
+ array->rgba[count][GCOMP] = solve_plane_chan(cx, cy, gPlane);
+ array->rgba[count][BCOMP] = solve_plane_chan(cx, cy, bPlane);
+ array->rgba[count][ACOMP] = solve_plane_chan(cx, cy, aPlane);
+#endif
+#ifdef DO_INDEX
+ array->index[count] = (GLint) solve_plane(cx, cy, iPlane);
+#endif
+ ix++;
+ count++;
+ coverage = compute_coveragef(pMin, pMid, pMax, ix, iy);
+ }
+
+ if (ix <= startX)
+ continue;
+
+ span.x = startX;
+ span.y = iy;
+ span.end = (GLuint) ix - (GLuint) startX;
+#if defined(DO_RGBA)
+ _swrast_write_rgba_span(ctx, &span);
+#else
+ _swrast_write_index_span(ctx, &span);
+#endif
+ }
+ }
+ else {
+ /* scan right to left */
+ const GLfloat *pMin = vMin->attrib[FRAG_ATTRIB_WPOS];
+ const GLfloat *pMid = vMid->attrib[FRAG_ATTRIB_WPOS];
+ const GLfloat *pMax = vMax->attrib[FRAG_ATTRIB_WPOS];
+ const GLfloat dxdy = majDx / majDy;
+ const GLfloat xAdj = dxdy > 0 ? dxdy : 0.0F;
+ GLfloat x = pMin[0] - (yMin - iyMin) * dxdy;
+ GLint iy;
+ for (iy = iyMin; iy < iyMax; iy++, x += dxdy) {
+ GLint ix, left, startX = (GLint) (x + xAdj);
+ GLuint count, n;
+ GLfloat coverage = 0.0F;
+
+ /* make sure we're not past the window edge */
+ if (startX >= ctx->DrawBuffer->_Xmax) {
+ startX = ctx->DrawBuffer->_Xmax - 1;
+ }
+
+ /* skip fragments with zero coverage */
+ while (startX > 0) {
+ coverage = compute_coveragef(pMin, pMax, pMid, startX, iy);
+ if (coverage > 0.0F)
+ break;
+ startX--;
+ }
+
+ /* enter interior of triangle */
+ ix = startX;
+ count = 0;
+ while (coverage > 0.0F) {
+ /* (cx,cy) = center of fragment */
+ const GLfloat cx = ix + 0.5F, cy = iy + 0.5F;
+ SWspanarrays *array = span.array;
+ ASSERT(ix >= 0);
+#ifdef DO_INDEX
+ array->coverage[ix] = (GLfloat) compute_coveragei(pMin, pMax, pMid, ix, iy);
+#else
+ array->coverage[ix] = coverage;
+#endif
+#ifdef DO_Z
+ array->z[ix] = (GLuint) solve_plane(cx, cy, zPlane);
+#endif
+#ifdef DO_RGBA
+ array->rgba[ix][RCOMP] = solve_plane_chan(cx, cy, rPlane);
+ array->rgba[ix][GCOMP] = solve_plane_chan(cx, cy, gPlane);
+ array->rgba[ix][BCOMP] = solve_plane_chan(cx, cy, bPlane);
+ array->rgba[ix][ACOMP] = solve_plane_chan(cx, cy, aPlane);
+#endif
+#ifdef DO_INDEX
+ array->index[ix] = (GLint) solve_plane(cx, cy, iPlane);
+#endif
+ ix--;
+ count++;
+ coverage = compute_coveragef(pMin, pMax, pMid, ix, iy);
+ }
+
+#if defined(DO_ATTRIBS)
+ /* compute attributes at left-most fragment */
+ span.attrStart[FRAG_ATTRIB_WPOS][3] = solve_plane(ix + 1.5, iy + 0.5, wPlane);
+ ATTRIB_LOOP_BEGIN
+ GLuint c;
+ for (c = 0; c < 4; c++) {
+ span.attrStart[attr][c] = solve_plane(ix + 1.5, iy + 0.5, attrPlane[attr][c]);
+ }
+ ATTRIB_LOOP_END
+#endif
+
+ if (startX <= ix)
+ continue;
+
+ n = (GLuint) startX - (GLuint) ix;
+
+ left = ix + 1;
+
+ /* shift all values to the left */
+ /* XXX this is temporary */
+ {
+ SWspanarrays *array = span.array;
+ GLint j;
+ for (j = 0; j < (GLint) n; j++) {
+ array->coverage[j] = array->coverage[j + left];
+#ifdef DO_RGBA
+ COPY_CHAN4(array->rgba[j], array->rgba[j + left]);
+#endif
+#ifdef DO_INDEX
+ array->index[j] = array->index[j + left];
+#endif
+#ifdef DO_Z
+ array->z[j] = array->z[j + left];
+#endif
+ }
+ }
+
+ span.x = left;
+ span.y = iy;
+ span.end = n;
+#if defined(DO_RGBA)
+ _swrast_write_rgba_span(ctx, &span);
+#else
+ _swrast_write_index_span(ctx, &span);
+#endif
+ }
+ }
+}
+
+
+#undef DO_Z
+#undef DO_RGBA
+#undef DO_INDEX
+#undef DO_ATTRIBS
+#undef DO_OCCLUSION_TEST