#import "qedefs.h" //define NOLIGHT vec3_t r_origin, r_matrix[3]; int t_width, t_height; unsigned *t_data; int t_widthmask, t_heightmask, t_widthshift; float t_widthadd, t_heightadd; int r_width, r_height; float *r_zbuffer; unsigned *r_picbuffer; vec5_t rightside, leftside, rightstep,leftstep; face_t *r_face; BOOL r_drawflat; pixel32_t r_flatcolor; int sy[20]; /* ==================== REN_ClearBuffers ==================== */ void REN_ClearBuffers (void) { int size; size = r_width * r_height*4; memset (r_zbuffer, 0, size); memset (r_picbuffer, 0, size); } /* ==================== REN_SetTexture ==================== */ void REN_SetTexture (face_t *face) { int i; int t_heightshift; qtexture_t *q; if (!face->qtexture) face->qtexture = TEX_ForName (face->texture.texture); // try to load q = face->qtexture; t_width = q->width; t_height = q->height; t_data = q->data; r_flatcolor = q->flatcolor; r_flatcolor.chan[0] *= r_face->light; r_flatcolor.chan[1] *= r_face->light; r_flatcolor.chan[2] *= r_face->light; t_widthadd = t_width*1024; t_heightadd = t_height*1024; t_widthmask = t_width-1; t_heightmask = t_height-1; t_widthshift = 0; i = t_width; while (i >= 2) { t_widthshift++; i>>=1; } t_heightshift = 0; i = t_width; while (i >= 2) { t_heightshift++; i>>=1; } if ( (1<= r_height) return; x1 = (leftside[0]); x2 = (rightside[0]); count = x2 - x1; if (count < 0) return; zfrac = leftside[2]; ufrac = leftside[3]; vfrac = leftside[4]; lightfrac = r_face->light; if (!count) scale = 1; else scale = 1.0/count; zstep = (rightside[2] - zfrac)*scale; ustep = (rightside[3] - ufrac)*scale; vstep = (rightside[4] - vfrac)*scale; if (x1 < 0) { ufrac -= x1*ustep; vfrac -= x1*vstep; zfrac -= x1*zstep; x1 = 0; } if (x2 > r_width) x2 = r_width; ofs = y*r_width+x1; // this should be specialized for 1.0 / 0.5 / 0.75 light levels for (x=x1 ; x < x2 ; x++) { if (r_zbuffer[ofs] <= zfrac) { scale = 1/zfrac; r_zbuffer[ofs] = zfrac; if (t_widthshift) { tx = (int)((ufrac*scale)) & t_widthmask; ty = (int)((vfrac*scale)) & t_heightmask; in = (pixel32_t *)&t_data [(ty<chan[0] = in->chan[0]*lightfrac; out->chan[1] = in->chan[1]*lightfrac; out->chan[2] = in->chan[2]*lightfrac; out->chan[3] = 0xff; #endif } ufrac += ustep; vfrac += vstep; zfrac += zstep; ofs++; } } /* ================== REN_DrawFlatSpan ================== */ void REN_DrawFlatSpan (int y) { int x, count; int ofs; int x1, x2; float zfrac, zstep; int *out; if (y<0 || y >= r_height) return; x1 = (leftside[0]); x2 = (rightside[0]); count = x2 - x1; if (count < 0) return; zfrac = leftside[2]; zstep = (rightside[2] - zfrac)/count; if (x1 < 0) { zfrac -= x1*zstep; x1 = 0; } if (x2 > r_width) x2 = r_width; ofs = y*r_width+x1; // this should be specialized for 1.0 / 0.5 / 0.75 light levels for (x=x1 ; x < x2 ; x++) { if (r_zbuffer[ofs] <= zfrac) { r_zbuffer[ofs] = zfrac; out = (int *)&r_picbuffer[ofs]; *out = r_flatcolor.p; } zfrac += zstep; ofs++; } } /* ===================== REN_RasterizeFace ===================== */ void REN_RasterizeFace (winding_t *w) { int y; int i; int top, bot; int leftv, rightv; int count; int numvertex; // // find top vertex // numvertex = w->numpoints; top = 0x7fffffff; bot = 0x80000000; leftv = 0; for (i=0 ; ipoints[i][3] *= w->points[i][2]; w->points[i][4] *= w->points[i][2]; sy[i] = (int)w->points[i][1]; if (sy[i] < top) { top = sy[i]; leftv = i; } if (sy[i] > bot) bot = sy[i]; } rightv = leftv; if (top < 0 || bot > r_height || top > bot) return; // shouldn't have to have this... // // render a trapezoid // y = top; while (y < bot) { if (y >= sy[leftv]) { do { for (i=0 ; i<5 ; i++) leftside[i] = w->points[leftv][i]; leftv--; if (leftv == -1) leftv = numvertex-1; } while (sy[leftv] <= y); count = sy[leftv]-y; for (i=0 ; i<5 ; i++) leftstep[i] = (w->points[leftv][i] - leftside[i])/count; } if (y >= sy[rightv]) { do { for (i=0 ; i<5 ; i++) rightside[i] = w->points[rightv][i]; rightv++; if (rightv == numvertex) rightv = 0; } while (sy[rightv] <= y); count = sy[rightv]-y; for (i=0 ; i<5 ; i++) rightstep[i] = (w->points[rightv][i] - rightside[i])/count; } if (r_drawflat) REN_DrawFlatSpan (y); else REN_DrawSpan (y); for (i=0 ; i<5 ; i++) { leftside[i] += leftstep[i]; rightside[i] += rightstep[i]; } y++; } } //============================================================================= /* ================== REN_DrawSpanLinear ================== */ void REN_DrawSpanLinear (int y) { int x, count; int ofs; int tx, ty; int x1, x2; float ufrac, vfrac, zfrac, ustep, vstep, zstep; pixel32_t *in, *out; float scale; if (y<0 || y >= r_height) return; x1 = (leftside[0]); x2 = (rightside[0]); count = x2 - x1; if (count < 0) return; zfrac = leftside[2]; ufrac = leftside[3]; vfrac = leftside[4]; if (!count) scale = 1; else scale = 1.0/count; zstep = (rightside[2] - zfrac)*scale; ustep = (rightside[3] - ufrac)*scale; vstep = (rightside[4] - vfrac)*scale; if (x1 < 0) { ufrac -= x1*ustep; vfrac -= x1*vstep; zfrac -= x1*zstep; x1 = 0; } if (x2 > r_width) x2 = r_width; ofs = y*r_width+x1; for (x=x1 ; x < x2 ; x++) { if (r_zbuffer[ofs] <= zfrac) { r_zbuffer[ofs] = zfrac; if (t_widthshift) { tx = (int)ufrac & t_widthmask; ty = (int)vfrac & t_heightmask; in = (pixel32_t *)&t_data [(ty<numpoints; top = 0x7fffffff; bot = 0x80000000; leftv = 0; for (i=0 ; ipoints[i][1]; if (sy[i] < top) { top = sy[i]; leftv = i; } if (sy[i] > bot) bot = sy[i]; } rightv = leftv; if (top < 0 || bot > r_height || top > bot) return; // shouldn't have to have this... // // render a trapezoid // y = top; while (y < bot) { if (y >= sy[leftv]) { do { for (i=0 ; i<5 ; i++) leftside[i] = w->points[leftv][i]; leftv--; if (leftv == -1) leftv = numvertex-1; } while (sy[leftv] <= y); count = sy[leftv]-y; for (i=0 ; i<5 ; i++) leftstep[i] = (w->points[leftv][i] - leftside[i])/count; } if (y >= sy[rightv]) { do { for (i=0 ; i<5 ; i++) rightside[i] = w->points[rightv][i]; rightv++; if (rightv == numvertex) rightv = 0; } while (sy[rightv] <= y); count = sy[rightv]-y; for (i=0 ; i<5 ; i++) rightstep[i] = (w->points[rightv][i] - rightside[i])/count; } REN_DrawSpanLinear (y); for (i=0 ; i<5 ; i++) { leftside[i] += leftstep[i]; rightside[i] += rightstep[i]; } y++; } } //============================================================================ /* ================== REN_BeginCamera =================== */ float r_width_2, r_height_3; plane_t frustum[5]; void REN_BeginCamera (void) { r_width_2 = (float)r_width / 2; r_height_3 = (float)r_height / 3; // clip to right side frustum[0].normal[0] = -1; frustum[0].normal[1] = 0; frustum[0].normal[2] = 1; frustum[0].dist = 0; // clip to left side frustum[1].normal[0] = 1; frustum[1].normal[1] = 0; frustum[1].normal[2] = 1; frustum[1].dist = 0; // clip to top side frustum[2].normal[0] = 0; frustum[2].normal[1] = -1; frustum[2].normal[2] = r_height_3 / r_width_2; frustum[2].dist = 0; // clip to bottom side frustum[3].normal[0] = 0; frustum[3].normal[1] = 1; frustum[3].normal[2] = 2*r_height_3 / r_width_2; frustum[3].dist = 0; // near Z frustum[4].normal[0] = 0; frustum[4].normal[1] = 0; frustum[4].normal[2] = 1; frustum[4].dist = 1; } void REN_BeginXY (void) { frustum[0].normal[0] = 1; frustum[0].normal[1] = 0; frustum[0].normal[2] = 0; frustum[0].dist = 0; frustum[1].normal[0] = -1; frustum[1].normal[1] = 0; frustum[1].normal[2] = 0; frustum[1].dist = -r_width; frustum[2].normal[0] = 0; frustum[2].normal[1] = 1; frustum[2].normal[2] = 0; frustum[2].dist = 0; frustum[3].normal[0] = 0; frustum[3].normal[1] = -1; frustum[3].normal[2] = 0; frustum[3].dist = -r_height; } /* ===================== REN_DrawCameraFace ===================== */ void REN_DrawCameraFace (face_t *idpol) { int i; float scale; int numvertex; winding_t *w, *in; vec3_t temp; if (!idpol->w) return; // overconstrained plane r_face = idpol; // // back face cull // if (DotProduct (r_origin, idpol->plane.normal) <= idpol->plane.dist) return; // // transform in 3D (FIXME: clip first, then transform) // in = idpol->w; numvertex = in->numpoints; w = NewWinding (numvertex); w->numpoints = numvertex; for (i=0 ; ipoints[i], r_origin, temp); w->points[i][0] = DotProduct(temp,r_matrix[0]); w->points[i][1] = DotProduct(temp,r_matrix[1]); w->points[i][2] = DotProduct(temp,r_matrix[2]); w->points[i][3] = in->points[i][3]; w->points[i][4] = in->points[i][4]; } // // 3D clip // for (i=0 ; i<4 ; i++) { w = ClipWinding (w, &frustum[i]); if (!w) return; } // // project to 2D // for (i=0 ; inumpoints ; i++) { scale = r_width_2 / w->points[i][2]; w->points[i][0] = r_width_2 + scale*w->points[i][0]; w->points[i][1] = r_height_3 - scale*w->points[i][1]; w->points[i][2] = scale; } // // draw it // REN_SetTexture (idpol); REN_RasterizeFace (w); free (w); } /* ===================== REN_DrawXYFace ===================== */ void REN_DrawXYFace (face_t *idpol) { int i, j, numvertex; winding_t *w, *in; float *dest, *source; float temp; if (!idpol->w) return; // overconstrained plane w = idpol->w; r_face = idpol; // // back (and side) face cull // if (DotProduct (idpol->plane.normal, xy_viewnormal) > -VECTOR_EPSILON) return; // // transform // in = idpol->w; numvertex = in->numpoints; w = NewWinding (numvertex); w->numpoints = numvertex; for (i=0 ; ipoints[i][0] = (in->points[i][0] - r_origin[0])*r_origin[2]; w->points[i][1] = r_height - (in->points[i][1] - r_origin[1])*r_origin[2]; w->points[i][2] = in->points[i][2] + 3000; w->points[i][3] = in->points[i][3]; w->points[i][4] = in->points[i][4]; } // // clip // for (i=0 ; i<4 ; i++) { w = ClipWinding (w, &frustum[i]); if (!w) return; } // // project to 2D // for (i=0 ; inumpoints ; i++) { dest = w->points[i]; if (dest[0] < 0) dest[0] = 0; if (dest[0] > r_width) dest[0] = r_width; if (dest[1] < 0) dest[1] = 0; if (dest[1] > r_height) dest[1] = r_height; if (xy_viewnormal[2] > 0) dest[2] = 4096-dest[2]; } if (xy_viewnormal[2] > 0) { // flip order when upside down for (i=0 ; inumpoints/2 ; i++) { dest = w->points[i]; source = w->points[w->numpoints-1-i]; for (j=0 ; j<5 ; j++) { temp = dest[j]; dest[j] = source[j]; source[j] = temp; } } } REN_SetTexture (idpol); // // draw it // REN_RasterizeFaceLinear (w); free (w); }