/* * Mesa 3-D graphics library * * Copyright (C) 1999-2006 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 * THE AUTHORS OR COPYRIGHT HOLDERS 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. * * Authors: * Keith Whitwell */ #include /** * \file t_dd_dmatmp.h * Template for render stages which build and emit vertices directly * to fixed-size dma buffers. Useful for rendering strips and other * native primitives where clipping and per-vertex tweaks such as * those in t_dd_tritmp.h are not required. * * Produces code for both inline triangles and indexed triangles. * Where various primitive types are unaccelerated by hardware, the * code attempts to fallback to other primitive types (quadstrips to * tristrips, lineloops to linestrips), or to indexed vertices. */ #if !HAVE_TRIANGLES || !HAVE_LINES || !HAVE_LINE_STRIPS || !HAVE_TRI_STRIPS || !HAVE_TRI_FANS #error "must have lines, line strips, triangles, triangle fans, and triangle strips to use render template" #endif #if HAVE_QUAD_STRIPS || HAVE_QUADS || HAVE_ELTS #error "ELTs, quads, and quad strips not supported by render template" #endif /**********************************************************************/ /* Render whole begin/end objects */ /**********************************************************************/ static inline void *TAG(emit_verts)(struct gl_context *ctx, GLuint start, GLuint count, void *buf) { return EMIT_VERTS(ctx, start, count, buf); } /*********************************************************************** * Render non-indexed primitives. ***********************************************************************/ static void TAG(render_points_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { if (HAVE_POINTS) { LOCAL_VARS; const unsigned dmasz = GET_SUBSEQUENT_VB_MAX_VERTS(); unsigned currentsz; GLuint j, nr; INIT(GL_POINTS); currentsz = GET_CURRENT_VB_MAX_VERTS(); if (currentsz < 8) currentsz = dmasz; for (j = 0; j < count; j += nr) { nr = MIN2(currentsz, count - j); TAG(emit_verts)(ctx, start + j, nr, ALLOC_VERTS(nr)); currentsz = dmasz; } } else { fprintf(stderr, "%s - cannot draw primitive\n", __func__); return; } } static void TAG(render_lines_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { LOCAL_VARS; const unsigned dmasz = GET_SUBSEQUENT_VB_MAX_VERTS() & ~1; unsigned currentsz; GLuint j, nr; INIT(GL_LINES); /* Emit whole number of lines in total and in each buffer: */ count -= count & 1; currentsz = GET_CURRENT_VB_MAX_VERTS(); currentsz -= currentsz & 1; if (currentsz < 8) currentsz = dmasz; for (j = 0; j < count; j += nr) { nr = MIN2(currentsz, count - j); TAG(emit_verts)(ctx, start + j, nr, ALLOC_VERTS(nr)); currentsz = dmasz; } } static void TAG(render_line_strip_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { LOCAL_VARS; const unsigned dmasz = GET_SUBSEQUENT_VB_MAX_VERTS(); unsigned currentsz; GLuint j, nr; INIT(GL_LINE_STRIP); currentsz = GET_CURRENT_VB_MAX_VERTS(); if (currentsz < 8) currentsz = dmasz; for (j = 0; j + 1 < count; j += nr - 1) { nr = MIN2(currentsz, count - j); TAG(emit_verts)(ctx, start + j, nr, ALLOC_VERTS(nr)); currentsz = dmasz; } FLUSH(); } static void TAG(render_line_loop_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { LOCAL_VARS; const unsigned dmasz = GET_SUBSEQUENT_VB_MAX_VERTS() - 1; unsigned currentsz; GLuint j, nr; INIT(GL_LINE_STRIP); j = (flags & PRIM_BEGIN) ? 0 : 1; /* Ensure last vertex won't wrap buffers: */ currentsz = GET_CURRENT_VB_MAX_VERTS(); currentsz--; if (currentsz < 8) currentsz = dmasz; if (j + 1 < count) { for (/* empty */; j + 1 < count; j += nr - 1) { nr = MIN2(currentsz, count - j); if (j + nr >= count && count > 1 && (flags & PRIM_END)) { void *tmp; tmp = ALLOC_VERTS(nr+1); tmp = TAG(emit_verts)(ctx, start + j, nr, tmp); tmp = TAG(emit_verts)( ctx, start, 1, tmp ); (void) tmp; } else { TAG(emit_verts)(ctx, start + j, nr, ALLOC_VERTS(nr)); currentsz = dmasz; } } } else if (count > 1 && (flags & PRIM_END)) { void *tmp; tmp = ALLOC_VERTS(2); tmp = TAG(emit_verts)( ctx, start+1, 1, tmp ); tmp = TAG(emit_verts)( ctx, start, 1, tmp ); (void) tmp; } FLUSH(); } static void TAG(render_triangles_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { LOCAL_VARS; const unsigned dmasz = (GET_SUBSEQUENT_VB_MAX_VERTS() / 3) * 3; unsigned currentsz; GLuint j, nr; INIT(GL_TRIANGLES); currentsz = (GET_CURRENT_VB_MAX_VERTS() / 3) * 3; /* Emit whole number of tris in total. dmasz is already a multiple * of 3. */ count -= count % 3; if (currentsz < 8) currentsz = dmasz; for (j = 0; j < count; j += nr) { nr = MIN2(currentsz, count - j); TAG(emit_verts)(ctx, start + j, nr, ALLOC_VERTS(nr)); currentsz = dmasz; } } static void TAG(render_tri_strip_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { LOCAL_VARS; GLuint j, nr; const unsigned dmasz = GET_SUBSEQUENT_VB_MAX_VERTS() & ~1; unsigned currentsz; INIT(GL_TRIANGLE_STRIP); currentsz = GET_CURRENT_VB_MAX_VERTS(); if (currentsz < 8) currentsz = dmasz; /* From here on emit even numbers of tris when wrapping over buffers: */ currentsz -= (currentsz & 1); for (j = 0; j + 2 < count; j += nr - 2) { nr = MIN2(currentsz, count - j); TAG(emit_verts)(ctx, start + j, nr, ALLOC_VERTS(nr)); currentsz = dmasz; } FLUSH(); } static void TAG(render_tri_fan_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { LOCAL_VARS; GLuint j, nr; const unsigned dmasz = GET_SUBSEQUENT_VB_MAX_VERTS(); unsigned currentsz; INIT(GL_TRIANGLE_FAN); currentsz = GET_CURRENT_VB_MAX_VERTS(); if (currentsz < 8) currentsz = dmasz; for (j = 1; j + 1 < count; j += nr - 2) { void *tmp; nr = MIN2(currentsz, count - j + 1); tmp = ALLOC_VERTS(nr); tmp = TAG(emit_verts)(ctx, start, 1, tmp); tmp = TAG(emit_verts)(ctx, start + j, nr - 1, tmp); (void) tmp; currentsz = dmasz; } FLUSH(); } static void TAG(render_poly_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { if (HAVE_POLYGONS) { LOCAL_VARS; GLuint j, nr; const unsigned dmasz = GET_SUBSEQUENT_VB_MAX_VERTS(); unsigned currentsz; INIT(GL_POLYGON); currentsz = GET_CURRENT_VB_MAX_VERTS(); if (currentsz < 8) { currentsz = dmasz; } for (j = 1; j + 1 < count; j += nr - 2) { void *tmp; nr = MIN2(currentsz, count - j + 1); tmp = ALLOC_VERTS(nr); tmp = TAG(emit_verts)(ctx, start, 1, tmp); tmp = TAG(emit_verts)(ctx, start + j, nr - 1, tmp); (void) tmp; currentsz = dmasz; } FLUSH(); } else if (ctx->Light.ShadeModel == GL_SMOOTH) { TAG(render_tri_fan_verts)( ctx, start, count, flags ); } else { fprintf(stderr, "%s - cannot draw primitive\n", __func__); return; } } static void TAG(render_quad_strip_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { GLuint j, nr; if (ctx->Light.ShadeModel == GL_FLAT && TNL_CONTEXT(ctx)->vb.AttribPtr[_TNL_ATTRIB_COLOR0]->stride) { /* Vertices won't fit in a single buffer or elts not available - should * never happen. */ fprintf(stderr, "%s - cannot draw primitive\n", __func__); return; } else { LOCAL_VARS; const unsigned dmasz = GET_SUBSEQUENT_VB_MAX_VERTS() & ~1; unsigned currentsz; /* Emit smooth-shaded quadstrips as tristrips: */ FLUSH(); INIT(GL_TRIANGLE_STRIP); /* Emit whole number of quads in total, and in each buffer. */ currentsz = GET_CURRENT_VB_MAX_VERTS(); currentsz -= currentsz & 1; count -= count & 1; if (currentsz < 8) currentsz = dmasz; for (j = 0; j + 3 < count; j += nr - 2) { nr = MIN2(currentsz, count - j); TAG(emit_verts)(ctx, start + j, nr, ALLOC_VERTS(nr)); currentsz = dmasz; } FLUSH(); } } static void TAG(render_quads_verts)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { LOCAL_VARS; GLuint j; /* Emit whole number of quads in total. */ count -= count & 3; /* Hardware doesn't have a quad primitive type -- try to simulate it using * triangle primitive. This is a win for gears, but is it useful in the * broader world? */ INIT(GL_TRIANGLES); for (j = 0; j + 3 < count; j += 4) { void *tmp = ALLOC_VERTS(6); /* Send v0, v1, v3 */ tmp = EMIT_VERTS(ctx, start + j, 2, tmp); tmp = EMIT_VERTS(ctx, start + j + 3, 1, tmp); /* Send v1, v2, v3 */ tmp = EMIT_VERTS(ctx, start + j + 1, 3, tmp); (void) tmp; } } static void TAG(render_noop)(struct gl_context *ctx, GLuint start, GLuint count, GLuint flags) { (void) ctx; (void) start; (void) count; (void) flags; } static const tnl_render_func TAG(render_tab_verts)[GL_POLYGON+2] = { TAG(render_points_verts), TAG(render_lines_verts), TAG(render_line_loop_verts), TAG(render_line_strip_verts), TAG(render_triangles_verts), TAG(render_tri_strip_verts), TAG(render_tri_fan_verts), TAG(render_quads_verts), TAG(render_quad_strip_verts), TAG(render_poly_verts), TAG(render_noop), }; /* Pre-check the primitives in the VB to prevent the need for * fallbacks later on. */ static bool TAG(validate_render)(struct gl_context *ctx, struct vertex_buffer *VB) { GLint i; if (VB->ClipOrMask & ~CLIP_CULL_BIT) return false; if (VB->Elts) return false; for (i = 0 ; i < VB->PrimitiveCount ; i++) { GLuint prim = VB->Primitive[i].mode; GLuint count = VB->Primitive[i].count; bool ok = false; if (!count) continue; switch (prim & PRIM_MODE_MASK) { case GL_POINTS: ok = HAVE_POINTS; break; case GL_LINES: case GL_LINE_STRIP: case GL_LINE_LOOP: ok = !ctx->Line.StippleFlag; break; case GL_TRIANGLES: case GL_TRIANGLE_STRIP: case GL_TRIANGLE_FAN: ok = true; break; case GL_POLYGON: ok = (HAVE_POLYGONS) || ctx->Light.ShadeModel == GL_SMOOTH; break; case GL_QUAD_STRIP: ok = VB->Elts || (ctx->Light.ShadeModel != GL_FLAT || VB->AttribPtr[_TNL_ATTRIB_COLOR0]->stride == 0); break; case GL_QUADS: ok = true; /* flatshading is ok. */ break; default: break; } if (!ok) { /* fprintf(stderr, "not ok %s\n", _mesa_enum_to_string(prim & PRIM_MODE_MASK)); */ return false; } } return true; }