/* Copyright (C) 1996-1997 Id Software, Inc. Copyright (C) 2007 Peter Mackay and Chris Swindle. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ // gl_warp.c -- sky and water polygons #include extern "C" { #include "../quakedef.h" } #include "clipping.hpp" using namespace quake; extern model_t *loadmodel; /*int skytexturenum;*/ int solidskytexture = -1; int alphaskytexture = -1; float speedscale; // for top sky and bottom sky int skytexorder[6] = {0,2,1,3,4,5}; int skyimage[6]; // Where sky images are stored char skybox_name[32] = ""; //name of current skybox, or "" if no skybox char *suf[6] = {"rt", "bk", "lf", "ft", "up", "dn"}; msurface_t *warpface; extern cvar_t gl_subdivide_size; static void BoundPoly (int numverts, float *verts, vec3_t mins, vec3_t maxs) { int i, j; float *v; mins[0] = mins[1] = mins[2] = 9999; maxs[0] = maxs[1] = maxs[2] = -9999; v = verts; for (i=0 ; i maxs[j]) maxs[j] = *v; } } } static void SubdividePolygon (int numverts, float *verts) { int i, j, k; vec3_t mins, maxs; float m; float *v; vec3_t front[64], back[64]; int f, b; float dist[64]; float frac; glpoly_t *poly; float s, t, subdivide_size;; if (numverts > 60) Sys_Error ("numverts = %i", numverts); subdivide_size = fmax(1, gl_subdivide_size.value); BoundPoly (numverts, verts, mins, maxs); for (i=0 ; i<3 ; i++) { m = (mins[i] + maxs[i]) * 0.5; m = subdivide_size * floorf (m / subdivide_size + 0.5); if (maxs[i] - m < 8) continue; if (m - mins[i] < 8) continue; // cut it v = verts + i; for (j=0 ; j= 0) { VectorCopy (v, front[f]); f++; } if (dist[j] <= 0) { VectorCopy (v, back[b]); b++; } if (dist[j] == 0 || dist[j+1] == 0) continue; if ( (dist[j] > 0) != (dist[j+1] > 0) ) { // clip point frac = dist[j] / (dist[j] - dist[j+1]); for (k=0 ; k<3 ; k++) front[f][k] = back[b][k] = v[k] + frac*(v[3+k] - v[k]); f++; b++; } } SubdividePolygon (f, front[0]); SubdividePolygon (b, back[0]); return; } poly = static_cast(Hunk_Alloc (sizeof(glpoly_t) + (numverts - 1) * sizeof(glvert_t))); poly->next = warpface->polys; warpface->polys = poly; poly->numverts = numverts; for (i=0 ; iverts[i].xyz); s = DotProduct (verts, warpface->texinfo->vecs[0]); t = DotProduct (verts, warpface->texinfo->vecs[1]); poly->verts[i].st[0] = s; poly->verts[i].st[1] = t; } } /* ================ GL_SubdivideSurface Breaks a polygon up along axial 64 unit boundaries so that turbulent and sky warps can be done reasonably. ================ */ void GL_SubdivideSurface (msurface_t *fa) { vec3_t verts[64]; int numverts; int i; int lindex; float *vec; warpface = fa; // // convert edges back to a normal polygon // numverts = 0; for (i=0 ; inumedges ; i++) { lindex = loadmodel->surfedges[fa->firstedge + i]; if (lindex > 0) vec = loadmodel->vertexes[loadmodel->edges[lindex].v[0]].position; else vec = loadmodel->vertexes[loadmodel->edges[-lindex].v[1]].position; VectorCopy (vec, verts[numverts]); numverts++; } SubdividePolygon (numverts, verts[0]); } //========================================================= #define TURBSINSIZE 128 #define TURBSCALE ((float)TURBSINSIZE / (2 * M_PI)) byte turbsin[TURBSINSIZE] = { 127, 133, 139, 146, 152, 158, 164, 170, 176, 182, 187, 193, 198, 203, 208, 213, 217, 221, 226, 229, 233, 236, 239, 242, 245, 247, 249, 251, 252, 253, 254, 254, 255, 254, 254, 253, 252, 251, 249, 247, 245, 242, 239, 236, 233, 229, 226, 221, 217, 213, 208, 203, 198, 193, 187, 182, 176, 170, 164, 158, 152, 146, 139, 133, 127, 121, 115, 108, 102, 96, 90, 84, 78, 72, 67, 61, 56, 51, 46, 41, 37, 33, 28, 25, 21, 18, 15, 12, 9, 7, 5, 3, 2, 1, 0, 0, 0, 0, 0, 1, 2, 3, 5, 7, 9, 12, 15, 18, 21, 25, 28, 33, 37, 41, 46, 51, 56, 61, 67, 72, 78, 84, 90, 96, 102, 108, 115, 121, }; __inline static float SINTABLE_APPROX (float time) { float sinlerpf, lerptime, lerp; int sinlerp1, sinlerp2; sinlerpf = time * TURBSCALE; sinlerp1 = floor(sinlerpf); sinlerp2 = sinlerp1 + 1; lerptime = sinlerpf - sinlerp1; lerp = turbsin[sinlerp1 & (TURBSINSIZE - 1)] * (1 - lerptime) + turbsin[sinlerp2 & (TURBSINSIZE - 1)] * lerptime; return -8 + 16 * lerp / 255.0; } /* ================ GL_Surface ================ */ void GL_Surface (msurface_t *fa) { vec3_t verts[64]; int numverts; int i; int lindex; float *vec; glpoly_t *poly; //float texscale; float s, t; //texscale = (1.0/32.0); // // convert edges back to a normal polygon // numverts = 0; for (i=0 ; inumedges ; i++) { lindex = loadmodel->surfedges[fa->firstedge + i]; if (lindex > 0) vec = loadmodel->vertexes[loadmodel->edges[lindex].v[0]].position; else vec = loadmodel->vertexes[loadmodel->edges[-lindex].v[1]].position; VectorCopy (vec, verts[numverts]); numverts++; } //create the poly poly = static_cast(Hunk_Alloc (sizeof(glpoly_t) + (numverts - 1) * sizeof(glvert_t))); poly->next = NULL; fa->polys = poly; poly->numverts = numverts; for (i=0, vec=(float *)verts; iverts[i].xyz); s = DotProduct(vec, fa->texinfo->vecs[0]);// * texscale; t = DotProduct(vec, fa->texinfo->vecs[1]);// * texscale; poly->verts[i].st[0] = s; poly->verts[i].st[1] = t; } } /* ============= EmitFlatPoly ============= */ void EmitFlatPoly (msurface_t *fa) { // For each polygon... for (const glpoly_t* p = fa->polys; p; p = p->next) { // Allocate memory for this polygon. const int unclipped_vertex_count = p->numverts; glvert_t* const unclipped_vertices = static_cast(sceGuGetMemory(sizeof(glvert_t) * unclipped_vertex_count)); // Generate each vertex. const glvert_t* src = p->verts; const glvert_t* last_vertex = src + unclipped_vertex_count; glvert_t* dst = unclipped_vertices; while (src != last_vertex) { // Fill in the vertex data. dst->st[0] = src->st[0]; //Tex dst->st[1] = src->st[1]; dst->xyz[0] = src->xyz[0]; //Verts dst->xyz[1] = src->xyz[1]; dst->xyz[2] = src->xyz[2]; // Next vertex. ++src; ++dst; } // Do these vertices need clipped? if (clipping::is_clipping_required(unclipped_vertices, unclipped_vertex_count)) { // Clip the polygon. const glvert_t* clipped_vertices; std::size_t clipped_vertex_count; clipping::clip( unclipped_vertices, unclipped_vertex_count, &clipped_vertices, &clipped_vertex_count); // Any vertices left? if (clipped_vertex_count) { // Copy the vertices to the display list. const std::size_t buffer_size = clipped_vertex_count * sizeof(glvert_t); glvert_t* const display_list_vertices = static_cast(sceGuGetMemory(buffer_size)); memcpy(display_list_vertices, clipped_vertices, buffer_size); // Draw the clipped vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, clipped_vertex_count, 0, display_list_vertices); } } else { // Draw the vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, unclipped_vertex_count, 0, unclipped_vertices); } } } /* ============= EmitWaterPolys Does a water warp on the pre-fragmented glpoly_t chain ============= */ void EmitWaterPolys (msurface_t *fa) { //const float real_time = static_cast(realtime); const float scale = (1.0f / 64); /* //jkrige - clamp waterripple values if(r_waterripple.value>10) r_waterripple.value=10; if(r_waterripple.value<0) r_waterripple.value=0; //jkrige - clamp waterripple values */ // For each polygon... for (const glpoly_t* p = fa->polys; p; p = p->next) { // Allocate memory for this polygon. const int unclipped_vertex_count = p->numverts; glvert_t* const unclipped_vertices = static_cast(sceGuGetMemory(sizeof(glvert_t) * unclipped_vertex_count)); // Generate each vertex. const glvert_t* src = p->verts; const glvert_t* last_vertex = src + unclipped_vertex_count; glvert_t* dst = unclipped_vertices; while (src != last_vertex) { // Get the input UVs. const float os = src->st[0]; const float ot = src->st[1]; // Fill in the vertex data. dst->st[0] = (os + SINTABLE_APPROX(ot * 0.125 + cl.time)) * scale; dst->st[1] = (ot + SINTABLE_APPROX(os * 0.125 + cl.time)) * scale; dst->xyz[0] = src->xyz[0]; dst->xyz[1] = src->xyz[1]; dst->xyz[2] = src->xyz[2]; //dst->xyz[2] = src->xyz[2] + r_waterripple.value * sin(src->xyz[0]*0.05+realtime)*sin(src->xyz[2]*0.05+realtime); // Next vertex. ++src; ++dst; } if (!(fa->flags & SURF_NEEDSCLIPPING)) { sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, unclipped_vertex_count, 0, unclipped_vertices); return; } // Do these vertices need clipped? if (clipping::is_clipping_required(unclipped_vertices, unclipped_vertex_count)) { // Clip the polygon. const glvert_t* clipped_vertices; std::size_t clipped_vertex_count; clipping::clip( unclipped_vertices, unclipped_vertex_count, &clipped_vertices, &clipped_vertex_count); // Any vertices left? if (clipped_vertex_count) { // Copy the vertices to the display list. const std::size_t buffer_size = clipped_vertex_count * sizeof(glvert_t); glvert_t* const display_list_vertices = static_cast(sceGuGetMemory(buffer_size)); memcpy(display_list_vertices, clipped_vertices, buffer_size); // Draw the clipped vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, clipped_vertex_count, 0, display_list_vertices); } } else { // Draw the vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, unclipped_vertex_count, 0, unclipped_vertices); } } } /* ============= EmitUnderWaterPolys based on water polys! By Crow_bar. ============= */ /* void EmitUnderWaterPolys (void) { const float scale = (-3 * (0.5 / 64)); extern glpoly_t *caustics_polys; sceGuEnable(GU_BLEND); sceGuBlendFunc (GU_ADD, GU_DST_COLOR, GU_SRC_COLOR, 0, 0); sceGuTexFunc(GU_TFX_DECAL, GU_TCC_RGBA); // For each polygon... for (const glpoly_t* p = caustics_polys ; p ; p = p->caustics_chain) { // Allocate memory for this polygon. const int unclipped_vertex_count = p->numverts; glvert_t* const unclipped_vertices = static_cast(sceGuGetMemory(sizeof(glvert_t) * unclipped_vertex_count)); // Generate each vertex. const glvert_t* src = p->verts; const glvert_t* last_vertex = src + unclipped_vertex_count; glvert_t* dst = unclipped_vertices; while (src != last_vertex) { // Get the input UVs. const float os = src->st[0]; const float ot = src->st[1]; // Fill in the vertex data. dst->st[0] = (os + SINTABLE_APPROX(0.465 * (cl.time + ot))) * scale; dst->st[1] = (ot + SINTABLE_APPROX(0.465 * (cl.time + os))) * scale; dst->xyz[0] = src->xyz[0]; dst->xyz[1] = src->xyz[1]; dst->xyz[2] = src->xyz[2]; // Next vertex. ++src; ++dst; } // Do these vertices need clipped? if (clipping::is_clipping_required(unclipped_vertices, unclipped_vertex_count)) { // Clip the polygon. const glvert_t* clipped_vertices; std::size_t clipped_vertex_count; clipping::clip( unclipped_vertices, unclipped_vertex_count, &clipped_vertices, &clipped_vertex_count); // Any vertices left? if (clipped_vertex_count) { // Copy the vertices to the display list. const std::size_t buffer_size = clipped_vertex_count * sizeof(glvert_t); glvert_t* const display_list_vertices = static_cast(sceGuGetMemory(buffer_size)); memcpy(display_list_vertices, clipped_vertices, buffer_size); // Draw the clipped vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, clipped_vertex_count, 0, display_list_vertices); } } else { // Draw the vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, unclipped_vertex_count, 0, unclipped_vertices); } } sceGuTexFunc(GU_TFX_REPLACE, GU_TCC_RGBA); sceGuBlendFunc(GU_ADD, GU_SRC_ALPHA, GU_ONE_MINUS_SRC_ALPHA, 0, 0); sceGuDisable (GU_BLEND); caustics_polys = NULL; } */ /* ============= EmitSkyPolys ============= */ void EmitSkyPolys (msurface_t *fa) { for (const glpoly_t* p = fa->polys; p; p = p->next) { // Allocate memory for this polygon. const int unclipped_vertex_count = p->numverts; glvert_t* const unclipped_vertices = static_cast(sceGuGetMemory(sizeof(glvert_t) * unclipped_vertex_count)); vec3_t dir; // Generate each vertex. const glvert_t* src = p->verts; const glvert_t* last_vertex = src + unclipped_vertex_count; glvert_t* dst = unclipped_vertices; while (src != last_vertex) { VectorSubtract(src->xyz, r_origin, dir); dir[2] *= 3; // flatten the sphere const float length = 6 * 63 / sqrtf(DotProduct(dir, dir)); dir[0] *= length; dir[1] *= length; dst->st[0] = (speedscale + dir[0]) * (1.0f / 128.0f); dst->st[1] = (speedscale + dir[1]) * (1.0f / 128.0f); dst->xyz[0] = src->xyz[0]; dst->xyz[1] = src->xyz[1]; dst->xyz[2] = src->xyz[2]; // Next vertex. ++src; ++dst; } // Do these vertices need clipped? if (clipping::is_clipping_required(unclipped_vertices, unclipped_vertex_count)) { // Clip the polygon. const glvert_t* clipped_vertices; std::size_t clipped_vertex_count; clipping::clip( unclipped_vertices, unclipped_vertex_count, &clipped_vertices, &clipped_vertex_count); // Any vertices left? if (clipped_vertex_count) { // Copy the vertices to the display list. const std::size_t buffer_size = clipped_vertex_count * sizeof(glvert_t); glvert_t* const display_list_vertices = static_cast(sceGuGetMemory(buffer_size)); memcpy(display_list_vertices, clipped_vertices, buffer_size); // Draw the clipped vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, clipped_vertex_count, 0, display_list_vertices); } } else { // Draw the vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, unclipped_vertex_count, 0, unclipped_vertices); } } } /* ============= EmitScrollPolys Does a scroll on the pre-fragmented glpoly_t chain ============= */ void EmitScrollPolys (msurface_t *fa) { const float real_time = static_cast(realtime); const float scroll = (-64 * ((real_time*0.5) - (int)(real_time*0.5))); // For each polygon... for (const glpoly_t* p = fa->polys; p; p = p->next) { // Allocate memory for this polygon. const int unclipped_vertex_count = p->numverts; glvert_t* const unclipped_vertices = static_cast(sceGuGetMemory(sizeof(glvert_t) * unclipped_vertex_count)); // Generate each vertex. const glvert_t* src = p->verts; const glvert_t* last_vertex = src + unclipped_vertex_count; glvert_t* dst = unclipped_vertices; while (src != last_vertex) { // Fill in the vertex data. dst->st[0] = src->st[0] + scroll; dst->st[1] = src->st[1]; dst->xyz[0] = src->xyz[0]; dst->xyz[1] = src->xyz[1]; dst->xyz[2] = src->xyz[2]; // Next vertex. ++src; ++dst; } // Do these vertices need clipped? if (clipping::is_clipping_required(unclipped_vertices, unclipped_vertex_count)) { // Clip the polygon. const glvert_t* clipped_vertices; std::size_t clipped_vertex_count; clipping::clip( unclipped_vertices, unclipped_vertex_count, &clipped_vertices, &clipped_vertex_count); // Any vertices left? if (clipped_vertex_count) { // Copy the vertices to the display list. const std::size_t buffer_size = clipped_vertex_count * sizeof(glvert_t); glvert_t* const display_list_vertices = static_cast(sceGuGetMemory(buffer_size)); memcpy(display_list_vertices, clipped_vertices, buffer_size); // Draw the clipped vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, clipped_vertex_count, 0, display_list_vertices); } } else { // Draw the vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, unclipped_vertex_count, 0, unclipped_vertices); } } } extern int ref_texture; /* ============= EmitReflectivePolys Does a reflective warp on the pre-fragmented glpoly_t chain ============= */ void EmitReflectivePolys (msurface_t *fa) { // For each polygon... for (const glpoly_t* p = fa->polys; p; p = p->next) { // Allocate memory for this polygon. const int unclipped_vertex_count = p->numverts; glvert_t* const unclipped_vertices = static_cast(sceGuGetMemory(sizeof(glvert_t) * unclipped_vertex_count)); // Generate each vertex. const glvert_t* src = p->verts; const glvert_t* last_vertex = src + unclipped_vertex_count; glvert_t* dst = unclipped_vertices; while (src != last_vertex) { vec3_t dir; VectorSubtract(src->xyz, r_origin, dir); dir[2] *= 3; // flatten the sphere const float length = 6 * 63 / sqrtf(DotProduct(dir, dir)); dir[0] *= length; dir[1] *= length; dst->st[0] = (dir[0]) * (1.0f / 256.0f); dst->st[1] = (dir[1]) * (1.0f / 256.0f); dst->xyz[0] = src->xyz[0]; dst->xyz[1] = src->xyz[1]; dst->xyz[2] = src->xyz[2]; // Next vertex. ++src; ++dst; } // Do these vertices need clipped? if (clipping::is_clipping_required(unclipped_vertices, unclipped_vertex_count)) { // Clip the polygon. const glvert_t* clipped_vertices; std::size_t clipped_vertex_count; clipping::clip( unclipped_vertices, unclipped_vertex_count, &clipped_vertices, &clipped_vertex_count); // Any vertices left? if (clipped_vertex_count) { // Copy the vertices to the display list. const std::size_t buffer_size = clipped_vertex_count * sizeof(glvert_t); glvert_t* const display_list_vertices = static_cast(sceGuGetMemory(buffer_size)); memcpy(display_list_vertices, clipped_vertices, buffer_size); // Draw the clipped vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, clipped_vertex_count, 0, display_list_vertices); } } else { // Draw the vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, unclipped_vertex_count, 0, unclipped_vertices); } } } /* =============== EmitBothSkyLayers Does a sky warp on the pre-fragmented glpoly_t chain This will be called for brushmodels, the world will have them chained together. =============== */ void EmitBothSkyLayers (msurface_t *fa) { GL_Bind (solidskytexture); speedscale = realtime*8; speedscale -= (int)speedscale & ~127 ; EmitSkyPolys (fa); sceGuEnable(GU_BLEND); GL_Bind (alphaskytexture); speedscale = realtime*16; speedscale -= (int)speedscale & ~127 ; EmitSkyPolys (fa); sceGuDisable(GU_BLEND); } /* =============== R_DrawScroll_SkyChain =============== */ void R_DrawScroll_SkyChain (msurface_t *s) { msurface_t *fa; GL_Bind(solidskytexture); speedscale = realtime*8; speedscale -= (int)speedscale & ~127 ; for (fa=s ; fa ; fa=fa->texturechain) EmitSkyPolys (fa); sceGuEnable(GU_BLEND); GL_Bind (alphaskytexture); speedscale = realtime*16; speedscale -= (int)speedscale & ~127 ; for (fa=s ; fa ; fa=fa->texturechain) EmitSkyPolys (fa); sceGuDisable(GU_BLEND); } /* =============== R_DrawFlat_SkyChain =============== */ void R_DrawFlat_SkyChain (msurface_t *s) { msurface_t *fa; sceGuDisable (GU_TEXTURE_2D); byte *sky_color = StringToRGB (r_skycolor.string); //Get color sceGuColor(GU_RGBA(sky_color[0], sky_color[1], sky_color[2], 255)); for (fa = s ; fa ; fa = fa->texturechain) EmitFlatPoly (fa); sceGuColor(0xffffffff); sceGuEnable (GU_TEXTURE_2D); } /* ================================================================= Quake 2 environment sky ================================================================= */ void UnloadSkyTexture (void) { for (int i = 0; i < 6; i++) { if (skyimage[i]) GL_UnloadTexture(skyimage[i]); skyimage[i] = NULL; } } /* ================== R_LoadSkys ================== */ extern int nonetexture; void Sky_LoadSkyBox (char *name) { #ifdef SLIM if (strcmp(skybox_name, name) == 0) return; //no change //purge old sky textures UnloadSkyTexture (); //turn off skybox if sky is set to "" if (name[0] == '0') { skybox_name[0] = 0; //if map don't have sky if (solidskytexture == -1) solidskytexture = nonetexture; if (alphaskytexture == -1) alphaskytexture = nonetexture; return; } for (int i = 0; i < 6; i++) { int mark = Hunk_LowMark (); if(!(skyimage[i] = loadtextureimage (va("gfx/env/%s%s", name, suf[i]), 0, 0, qfalse, GU_LINEAR)) && !(skyimage[i] = loadtextureimage (va("gfx/env/%s_%s", name, suf[i]), 0, 0, qfalse, GU_LINEAR))) { Con_Printf("Sky: %s[%s] not found, used std\n", name, suf[i]); if(!(skyimage[i] = loadtextureimage (va("gfx/env/skybox%s", suf[i]), 0, 0, qfalse, GU_LINEAR))) { Sys_Error("STD SKY NOT FOUND!"); } } Hunk_FreeToLowMark (mark); } strcpy(skybox_name, name); #endif // SLIM } /* ================= Sky_NewMap ================= */ void Sky_NewMap (void) { char key[128], value[4096]; char *data; //purge old sky textures UnloadSkyTexture (); // // initially no sky // Sky_LoadSkyBox (""); //not used // // read worldspawn (this is so ugly, and shouldn't it be done on the server?) // data = cl.worldmodel->entities; if (!data) return; //FIXME: how could this possibly ever happen? -- if there's no // worldspawn then the sever wouldn't send the loadmap message to the client data = COM_Parse(data); if (!data) //should never happen return; // error if (com_token[0] != '{') //should never happen return; // error while (1) { data = COM_Parse(data); if (!data) return; // error if (com_token[0] == '}') break; // end of worldspawn if (com_token[0] == '_') strcpy(key, com_token + 1); else strcpy(key, com_token); while (key[strlen(key)-1] == ' ') // remove trailing spaces key[strlen(key)-1] = 0; data = COM_Parse(data); if (!data) return; // error strcpy(value, com_token); if (!strcmp("sky", key)) Sky_LoadSkyBox(value); else if (!strcmp("skyname", key)) //half-life Sky_LoadSkyBox(value); else if (!strcmp("qlsky", key)) //quake lives Sky_LoadSkyBox(value); } } /* ================= Sky_SkyCommand_f ================= */ void Sky_SkyCommand_f (void) { switch (Cmd_Argc()) { case 1: Con_Printf("\"sky\" is \"%s\"\n", skybox_name); break; case 2: Sky_LoadSkyBox(Cmd_Argv(1)); break; default: Con_Printf("usage: sky \n"); } } /* ============= Sky_Init ============= */ void Sky_Init (void) { int i; Cmd_AddCommand ("sky",Sky_SkyCommand_f); for (i=0; i<6; i++) skyimage[i] = NULL; } static vec3_t skyclip[6] = { {1,1,0}, {1,-1,0}, {0,-1,1}, {0,1,1}, {1,0,1}, {-1,0,1} }; int c_sky; // 1 = s, 2 = t, 3 = 2048 static int st_to_vec[6][3] = { {3,-1,2}, {-3,1,2}, {1,3,2}, {-1,-3,2}, {-2,-1,3}, // 0 degrees yaw, look straight up {2,-1,-3} // look straight down // {-1,2,3}, // {1,2,-3} }; // s = [0]/[2], t = [1]/[2] static int vec_to_st[6][3] = { {-2,3,1}, {2,3,-1}, {1,3,2}, {-1,3,-2}, {-2,-1,3}, {-2,1,-3} // {-1,2,3}, // {1,2,-3} }; static float skymins[2][6], skymaxs[2][6]; static void DrawSkyPolygon (int nump, vec3_t vecs) { int i,j,axis; float s,t,dv,*vp; vec3_t v, av; c_sky++; // decide which face it maps to VectorCopy (vec3_origin, v); for (i=0, vp=vecs ; i av[1] && av[0] > av[2]) axis = (v[0] < 0) ? 1 : 0; else if (av[1] > av[2] && av[1] > av[0]) axis = (v[1] < 0) ? 3 : 2; else axis = (v[2] < 0) ? 5 : 4; // project new texture coords for (i=0 ; i 0) ? vecs[j - 1] : -vecs[-j - 1]; j = vec_to_st[axis][0]; s = (j < 0) ? -vecs[-j -1] / dv : vecs[j-1] / dv; j = vec_to_st[axis][1]; t = (j < 0) ? -vecs[-j -1] / dv : vecs[j-1] / dv; if (s < skymins[0][axis]) skymins[0][axis] = s; if (t < skymins[1][axis]) skymins[1][axis] = t; if (s > skymaxs[0][axis]) skymaxs[0][axis] = s; if (t > skymaxs[1][axis]) skymaxs[1][axis] = t; } } #define MAX_CLIP_VERTS 64 void ClipSkyPolygon (int nump, vec3_t vecs, int stage) { float *norm; float *v; qboolean front, back; float d, e; float dists[MAX_CLIP_VERTS]; int sides[MAX_CLIP_VERTS]; vec3_t newv[2][MAX_CLIP_VERTS]; int newc[2]; int i, j; if (nump > MAX_CLIP_VERTS-2) Sys_Error ("ClipSkyPolygon: MAX_CLIP_VERTS"); if (stage == 6) { // fully clipped, so draw it DrawSkyPolygon (nump, vecs); return; } front = back = qfalse; norm = skyclip[stage]; for (i=0, v = vecs ; i ON_EPSILON) { front = qtrue; sides[i] = SIDE_FRONT; } else if (d < ON_EPSILON) { back = qtrue; sides[i] = SIDE_BACK; } else sides[i] = SIDE_ON; dists[i] = d; } if (!front || !back) { // not clipped ClipSkyPolygon (nump, vecs, stage+1); return; } // clip it sides[i] = sides[0]; dists[i] = dists[0]; VectorCopy (vecs, (vecs+(i*3)) ); newc[0] = newc[1] = 0; for (i=0, v = vecs ; i 511.0f/512.0f) s = 511.0f/512.0f; if (t < 1.0f/512.0f) t = 1.0f/512.0f; else if (t > 511.0f/512.0f) t = 511.0f/512.0f; t = 1.0f - t; s_axis = s; t_axis = t; } void Fog_EnableGFog (void); void Fog_DisableGFog (void); void Fog_SetColorForSkyS (void); void Fog_SetColorForSkyE (void); /* ============== R_DrawSkyBox ============== */ void R_DrawSkyBox (void) { int i; Fog_DisableGFog(); //setup for Sky Fog_SetColorForSkyS(); //setup for Sky //sceGuDepthRange(32767, 65535); //not used for (i=0 ; i<6 ; i++) { // Allocate memory for this polygon. const int unclipped_vertex_count = 4; glvert_t* const unclipped_vertices = static_cast(sceGuGetMemory(sizeof(glvert_t) * unclipped_vertex_count)); if (skymins[0][i] >= skymaxs[0][i] || skymins[1][i] >= skymaxs[1][i]) continue; GL_Bind (skyimage[skytexorder[i]]); MakeSkyVec (skymins[0][i], skymins[1][i], i); unclipped_vertices[0].st[0] = s_axis; unclipped_vertices[0].st[1] = t_axis; unclipped_vertices[0].xyz[0] = v_axis[0]; unclipped_vertices[0].xyz[1] = v_axis[1]; unclipped_vertices[0].xyz[2] = v_axis[2]; MakeSkyVec (skymins[0][i], skymaxs[1][i], i); unclipped_vertices[1].st[0] = s_axis; unclipped_vertices[1].st[1] = t_axis; unclipped_vertices[1].xyz[0] = v_axis[0]; unclipped_vertices[1].xyz[1] = v_axis[1]; unclipped_vertices[1].xyz[2] = v_axis[2]; MakeSkyVec (skymaxs[0][i], skymaxs[1][i], i); unclipped_vertices[2].st[0] = s_axis; unclipped_vertices[2].st[1] = t_axis; unclipped_vertices[2].xyz[0] = v_axis[0]; unclipped_vertices[2].xyz[1] = v_axis[1]; unclipped_vertices[2].xyz[2] = v_axis[2]; MakeSkyVec (skymaxs[0][i], skymins[1][i], i); unclipped_vertices[3].st[0] = s_axis; unclipped_vertices[3].st[1] = t_axis; unclipped_vertices[3].xyz[0] = v_axis[0]; unclipped_vertices[3].xyz[1] = v_axis[1]; unclipped_vertices[3].xyz[2] = v_axis[2]; if (clipping::is_clipping_required( unclipped_vertices, unclipped_vertex_count)) { // Clip the polygon. const glvert_t* clipped_vertices; std::size_t clipped_vertex_count; clipping::clip( unclipped_vertices, unclipped_vertex_count, &clipped_vertices, &clipped_vertex_count); // Did we have any vertices left? if (clipped_vertex_count) { // Copy the vertices to the display list. const std::size_t buffer_size = clipped_vertex_count * sizeof(glvert_t); glvert_t* const display_list_vertices = static_cast(sceGuGetMemory(buffer_size)); memcpy(display_list_vertices, clipped_vertices, buffer_size); // Draw the clipped vertices. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, clipped_vertex_count, 0, display_list_vertices); } } else { // Draw the poly directly. sceGuDrawArray( GU_TRIANGLE_FAN, GU_TEXTURE_32BITF | GU_VERTEX_32BITF, unclipped_vertex_count, 0, unclipped_vertices); } } //sceGuDepthRange(0, 65535); Fog_SetColorForSkyE(); //setup for Sky Fog_EnableGFog(); //setup for Sky } //=============================================================== /* ================= R_DrawSkyChain ================= */ void R_DrawSkyChain (msurface_t *s) { msurface_t *fa; int i; vec3_t verts[MAX_CLIP_VERTS]; glpoly_t *p; if (r_fastsky.value || !skybox_name[0]) { R_DrawFlat_SkyChain (s); } else { if (skybox_name[0]) // if the skybox has a name, draw the skybox { c_sky = 0; // calculate vertex values for sky box for (fa=s ; fa ; fa=fa->texturechain) { for (p=fa->polys ; p ; p=p->next) { for (i=0 ; inumverts ; i++) { VectorSubtract (p->verts[i].xyz, r_origin, verts[i]); } ClipSkyPolygon (p->numverts, verts[0], 0); } } } else // otherwise, draw the normal quake sky { R_DrawScroll_SkyChain (s); } } } //=============================================================== /* ============= R_InitSky A sky texture is 256*128, with the right side being a masked overlay ============== */ void R_InitSky (byte *mt) { byte trans[128*128]; const byte* const src = (byte *)mt; for (int i=0 ; i<128 ; i++) { for (int j=0 ; j<128 ; j++) { const byte p = src[i*256 + j + 128]; trans[(i*128) + j] = p; } } if (solidskytexture == -1) solidskytexture = GL_LoadTexture("solidskytexture", 128, 128, trans, qfalse, GU_LINEAR, 0); for (int i=0 ; i<128 ; i++) { for (int j=0 ; j<128 ; j++) { const byte p = src[i*256 + j]; if (p == 0) trans[(i*128) + j] = 255; else trans[(i*128) + j] = p; } } if (alphaskytexture == -1) alphaskytexture = GL_LoadTexture("alphaskytexture", 128, 128, trans, qfalse, GU_LINEAR, 0); }