/********************************************************** * Copyright 2008-2009 VMware, Inc. 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. * **********************************************************/ #include "util/u_inlines.h" #include "pipe/p_defines.h" #include "util/u_math.h" #include "util/u_memory.h" #include "util/u_bitmask.h" #include "tgsi/tgsi_ureg.h" #include "svga_context.h" #include "svga_state.h" #include "svga_cmd.h" #include "svga_tgsi.h" #include "svga_hw_reg.h" static INLINE int compare_fs_keys( const struct svga_fs_compile_key *a, const struct svga_fs_compile_key *b ) { unsigned keysize_a = svga_fs_key_size( a ); unsigned keysize_b = svga_fs_key_size( b ); if (keysize_a != keysize_b) { return (int)(keysize_a - keysize_b); } return memcmp( a, b, keysize_a ); } static struct svga_shader_result *search_fs_key( struct svga_fragment_shader *fs, const struct svga_fs_compile_key *key ) { struct svga_shader_result *result = fs->base.results; assert(key); for ( ; result; result = result->next) { if (compare_fs_keys( key, &result->key.fkey ) == 0) return result; } return NULL; } /** * If we fail to compile a fragment shader (because it uses too many * registers, for example) we'll use a dummy/fallback shader that * simply emits a constant color. */ static const struct tgsi_token * get_dummy_fragment_shader(void) { static const float red[4] = { 1.0, 0.0, 0.0, 0.0 }; struct ureg_program *ureg; const struct tgsi_token *tokens; struct ureg_src src; struct ureg_dst dst; unsigned num_tokens; ureg = ureg_create(TGSI_PROCESSOR_FRAGMENT); if (!ureg) return NULL; dst = ureg_DECL_output(ureg, TGSI_SEMANTIC_COLOR, 0); src = ureg_DECL_immediate(ureg, red, 4); ureg_MOV(ureg, dst, src); ureg_END(ureg); tokens = ureg_get_tokens(ureg, &num_tokens); ureg_destroy(ureg); return tokens; } static enum pipe_error compile_fs( struct svga_context *svga, struct svga_fragment_shader *fs, const struct svga_fs_compile_key *key, struct svga_shader_result **out_result ) { struct svga_shader_result *result; enum pipe_error ret = PIPE_ERROR; result = svga_translate_fragment_program( fs, key ); if (result == NULL) { /* some problem during translation, try the dummy shader */ const struct tgsi_token *dummy = get_dummy_fragment_shader(); if (!dummy) { ret = PIPE_ERROR_OUT_OF_MEMORY; goto fail; } debug_printf("Failed to compile fragment shader, using dummy shader instead.\n"); FREE((void *) fs->base.tokens); fs->base.tokens = dummy; result = svga_translate_fragment_program(fs, key); if (result == NULL) { ret = PIPE_ERROR; goto fail; } } result->id = util_bitmask_add(svga->fs_bm); if(result->id == UTIL_BITMASK_INVALID_INDEX) { ret = PIPE_ERROR_OUT_OF_MEMORY; goto fail; } ret = SVGA3D_DefineShader(svga->swc, result->id, SVGA3D_SHADERTYPE_PS, result->tokens, result->nr_tokens * sizeof result->tokens[0]); if (ret != PIPE_OK) goto fail; *out_result = result; result->next = fs->base.results; fs->base.results = result; return PIPE_OK; fail: if (result) { if (result->id != UTIL_BITMASK_INVALID_INDEX) util_bitmask_clear( svga->fs_bm, result->id ); svga_destroy_shader_result( result ); } return ret; } /* SVGA_NEW_TEXTURE_BINDING * SVGA_NEW_RAST * SVGA_NEW_NEED_SWTNL * SVGA_NEW_SAMPLER */ static enum pipe_error make_fs_key(const struct svga_context *svga, struct svga_fragment_shader *fs, struct svga_fs_compile_key *key) { unsigned i; int idx = 0; memset(key, 0, sizeof *key); /* Only need fragment shader fixup for twoside lighting if doing * hwtnl. Otherwise the draw module does the whole job for us. * * SVGA_NEW_SWTNL */ if (!svga->state.sw.need_swtnl) { /* SVGA_NEW_RAST */ key->light_twoside = svga->curr.rast->templ.light_twoside; key->front_ccw = svga->curr.rast->templ.front_ccw; } /* The blend workaround for simulating logicop xor behaviour * requires that the incoming fragment color be white. This change * achieves that by creating a variant of the current fragment * shader that overrides all output colors with 1,1,1,1 * * This will work for most shaders, including those containing * TEXKIL and/or depth-write. However, it will break on the * combination of xor-logicop plus alphatest. * * Ultimately, we could implement alphatest in the shader using * texkil prior to overriding the outgoing fragment color. * * SVGA_NEW_BLEND */ if (svga->curr.blend->need_white_fragments) { key->white_fragments = 1; } /* XXX: want to limit this to the textures that the shader actually * refers to. * * SVGA_NEW_TEXTURE_BINDING | SVGA_NEW_SAMPLER */ for (i = 0; i < svga->curr.num_sampler_views; i++) { if (svga->curr.sampler_views[i]) { assert(svga->curr.sampler[i]); assert(svga->curr.sampler_views[i]->texture); key->tex[i].texture_target = svga->curr.sampler_views[i]->texture->target; if (!svga->curr.sampler[i]->normalized_coords) { key->tex[i].width_height_idx = idx++; key->tex[i].unnormalized = TRUE; ++key->num_unnormalized_coords; } key->tex[i].swizzle_r = svga->curr.sampler_views[i]->swizzle_r; key->tex[i].swizzle_g = svga->curr.sampler_views[i]->swizzle_g; key->tex[i].swizzle_b = svga->curr.sampler_views[i]->swizzle_b; key->tex[i].swizzle_a = svga->curr.sampler_views[i]->swizzle_a; } } key->num_textures = svga->curr.num_sampler_views; idx = 0; for (i = 0; i < svga->curr.num_samplers; ++i) { if (svga->curr.sampler[i]) { key->tex[i].compare_mode = svga->curr.sampler[i]->compare_mode; key->tex[i].compare_func = svga->curr.sampler[i]->compare_func; } } /* sprite coord gen state */ for (i = 0; i < svga->curr.num_samplers; ++i) { key->tex[i].sprite_texgen = svga->curr.rast->templ.sprite_coord_enable & (1 << i); } key->sprite_origin_lower_left = (svga->curr.rast->templ.sprite_coord_mode == PIPE_SPRITE_COORD_LOWER_LEFT); return PIPE_OK; } static enum pipe_error emit_hw_fs(struct svga_context *svga, unsigned dirty) { struct svga_shader_result *result = NULL; unsigned id = SVGA3D_INVALID_ID; enum pipe_error ret = PIPE_OK; struct svga_fragment_shader *fs = svga->curr.fs; struct svga_fs_compile_key key; /* SVGA_NEW_BLEND * SVGA_NEW_TEXTURE_BINDING * SVGA_NEW_RAST * SVGA_NEW_NEED_SWTNL * SVGA_NEW_SAMPLER */ ret = make_fs_key( svga, fs, &key ); if (ret != PIPE_OK) return ret; result = search_fs_key( fs, &key ); if (!result) { ret = compile_fs( svga, fs, &key, &result ); if (ret != PIPE_OK) return ret; } assert (result); id = result->id; assert(id != SVGA3D_INVALID_ID); if (result != svga->state.hw_draw.fs) { ret = SVGA3D_SetShader(svga->swc, SVGA3D_SHADERTYPE_PS, id ); if (ret != PIPE_OK) return ret; svga->dirty |= SVGA_NEW_FS_RESULT; svga->state.hw_draw.fs = result; } return PIPE_OK; } struct svga_tracked_state svga_hw_fs = { "fragment shader (hwtnl)", (SVGA_NEW_FS | SVGA_NEW_TEXTURE_BINDING | SVGA_NEW_NEED_SWTNL | SVGA_NEW_RAST | SVGA_NEW_SAMPLER | SVGA_NEW_BLEND), emit_hw_fs };