shader: move header emission to use the error state.

This should avoid all the unnecessary return overheads, at the
expense of some extra runtime overheads in the unwanted error case.

Reviewed-by: Erik Faye-Lund <erik.faye-lund@collabora.com>
Signed-off-by: Dave Airlie <airlied@redhat.com>
macos/master
Dave Airlie 6 years ago
parent 375b424a1b
commit 06799bf223
  1. 230
      src/vrend_shader.c

@ -517,22 +517,16 @@ static void outdent_buf(struct dump_ctx *ctx)
if (!_ret) return false; \ if (!_ret) return false; \
} while(0) } while(0)
static bool add_str_to_glsl_hdr(struct dump_ctx *ctx, const char *buf) static void emit_hdr(struct dump_ctx *ctx, const char *buf)
{ {
strbuf_append(&ctx->glsl_hdr, buf); strbuf_append(&ctx->glsl_hdr, buf);
return !strbuf_get_error(&ctx->glsl_hdr);
} }
static bool emit_hdr(struct dump_ctx *ctx, const char *buf) static void set_hdr_error(struct dump_ctx *ctx)
{ {
return add_str_to_glsl_hdr(ctx, buf); strbuf_set_error(&ctx->glsl_hdr);
} }
#define EMIT_HDR_WITH_RET(ctx, buf) do { \
bool _ret = emit_hdr((ctx), (buf)); \
if (!_ret) return false; \
} while(0)
static bool allocate_temp_range(struct dump_ctx *ctx, int first, int last, static bool allocate_temp_range(struct dump_ctx *ctx, int first, int last,
int array_id) int array_id)
{ {
@ -4036,16 +4030,16 @@ prolog(struct tgsi_iterate_context *iter)
/* reserve space for: "#extension GL_ARB_gpu_shader5 : require\n" */ /* reserve space for: "#extension GL_ARB_gpu_shader5 : require\n" */
#define PAD_GPU_SHADER5(ctx) \ #define PAD_GPU_SHADER5(ctx) \
EMIT_HDR_WITH_RET(ctx, " \n") emit_hdr(ctx, " \n")
#define PAD_GPU_MSINTERPOL(ctx) \ #define PAD_GPU_MSINTERPOL(ctx) \
EMIT_HDR_WITH_RET(ctx, " \n") emit_hdr(ctx, " \n")
static bool emit_header(struct dump_ctx *ctx) static void emit_header(struct dump_ctx *ctx)
{ {
if (ctx->cfg->use_gles) { if (ctx->cfg->use_gles) {
char buf[32]; char buf[32];
snprintf(buf, sizeof(buf), "#version %d es\n", ctx->cfg->glsl_version); snprintf(buf, sizeof(buf), "#version %d es\n", ctx->cfg->glsl_version);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
if (ctx->cfg->glsl_version < 320 && if (ctx->cfg->glsl_version < 320 &&
(ctx->prog_type == TGSI_PROCESSOR_VERTEX || (ctx->prog_type == TGSI_PROCESSOR_VERTEX ||
@ -4056,60 +4050,60 @@ static bool emit_header(struct dump_ctx *ctx)
} }
if (ctx->shader_req_bits & SHADER_REQ_SAMPLER_MS) if (ctx->shader_req_bits & SHADER_REQ_SAMPLER_MS)
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_texture_storage_multisample_2d_array : require\n"); emit_hdr(ctx, "#extension GL_OES_texture_storage_multisample_2d_array : require\n");
if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT) { if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT) {
if (ctx->shader_req_bits & SHADER_REQ_FBFETCH) if (ctx->shader_req_bits & SHADER_REQ_FBFETCH)
EMIT_HDR_WITH_RET(ctx, "#extension GL_EXT_shader_framebuffer_fetch : require\n"); emit_hdr(ctx, "#extension GL_EXT_shader_framebuffer_fetch : require\n");
} }
if (ctx->prog_type == TGSI_PROCESSOR_GEOMETRY) { if (ctx->prog_type == TGSI_PROCESSOR_GEOMETRY) {
EMIT_HDR_WITH_RET(ctx, "#extension GL_EXT_geometry_shader : require\n"); emit_hdr(ctx, "#extension GL_EXT_geometry_shader : require\n");
if (ctx->shader_req_bits & SHADER_REQ_PSIZE) if (ctx->shader_req_bits & SHADER_REQ_PSIZE)
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_geometry_point_size : enable\n"); emit_hdr(ctx, "#extension GL_OES_geometry_point_size : enable\n");
} }
if ((ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL || if ((ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL ||
ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL)) { ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL)) {
if (ctx->cfg->glsl_version < 320) if (ctx->cfg->glsl_version < 320)
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_tessellation_shader : require\n"); emit_hdr(ctx, "#extension GL_OES_tessellation_shader : require\n");
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_tessellation_point_size : enable\n"); emit_hdr(ctx, "#extension GL_OES_tessellation_point_size : enable\n");
} }
if (ctx->cfg->glsl_version < 320) { if (ctx->cfg->glsl_version < 320) {
if (ctx->shader_req_bits & SHADER_REQ_SAMPLE_SHADING) if (ctx->shader_req_bits & SHADER_REQ_SAMPLE_SHADING)
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_sample_variables : require\n"); emit_hdr(ctx, "#extension GL_OES_sample_variables : require\n");
if (ctx->shader_req_bits & SHADER_REQ_GPU_SHADER5) { if (ctx->shader_req_bits & SHADER_REQ_GPU_SHADER5) {
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_gpu_shader5 : require\n"); emit_hdr(ctx, "#extension GL_OES_gpu_shader5 : require\n");
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_shader_multisample_interpolation : require\n"); emit_hdr(ctx, "#extension GL_OES_shader_multisample_interpolation : require\n");
} }
if (ctx->shader_req_bits & SHADER_REQ_CUBE_ARRAY) if (ctx->shader_req_bits & SHADER_REQ_CUBE_ARRAY)
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_texture_cube_map_array : require\n"); emit_hdr(ctx, "#extension GL_OES_texture_cube_map_array : require\n");
if (ctx->shader_req_bits & SHADER_REQ_LAYER) if (ctx->shader_req_bits & SHADER_REQ_LAYER)
EMIT_HDR_WITH_RET(ctx, "#extension GL_EXT_geometry_shader : require\n"); emit_hdr(ctx, "#extension GL_EXT_geometry_shader : require\n");
if (ctx->shader_req_bits & SHADER_REQ_IMAGE_ATOMIC) if (ctx->shader_req_bits & SHADER_REQ_IMAGE_ATOMIC)
EMIT_HDR_WITH_RET(ctx, "#extension GL_OES_shader_image_atomic : require\n"); emit_hdr(ctx, "#extension GL_OES_shader_image_atomic : require\n");
} }
PAD_GPU_SHADER5(ctx); PAD_GPU_SHADER5(ctx);
EMIT_HDR_WITH_RET(ctx, "precision highp float;\n"); emit_hdr(ctx, "precision highp float;\n");
EMIT_HDR_WITH_RET(ctx, "precision highp int;\n"); emit_hdr(ctx, "precision highp int;\n");
} else { } else {
char buf[128]; char buf[128];
if (ctx->prog_type == TGSI_PROCESSOR_COMPUTE) { if (ctx->prog_type == TGSI_PROCESSOR_COMPUTE) {
EMIT_HDR_WITH_RET(ctx, "#version 330\n"); emit_hdr(ctx, "#version 330\n");
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_compute_shader : require\n"); emit_hdr(ctx, "#extension GL_ARB_compute_shader : require\n");
} else { } else {
if (ctx->prog_type == TGSI_PROCESSOR_GEOMETRY || if (ctx->prog_type == TGSI_PROCESSOR_GEOMETRY ||
ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL || ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL ||
ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL || ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL ||
ctx->glsl_ver_required == 150) ctx->glsl_ver_required == 150)
EMIT_HDR_WITH_RET(ctx, "#version 150\n"); emit_hdr(ctx, "#version 150\n");
else if (ctx->glsl_ver_required == 140) else if (ctx->glsl_ver_required == 140)
EMIT_HDR_WITH_RET(ctx, "#version 140\n"); emit_hdr(ctx, "#version 140\n");
else else
EMIT_HDR_WITH_RET(ctx, "#version 130\n"); emit_hdr(ctx, "#version 130\n");
if (ctx->prog_type == TGSI_PROCESSOR_VERTEX || if (ctx->prog_type == TGSI_PROCESSOR_VERTEX ||
ctx->prog_type == TGSI_PROCESSOR_GEOMETRY || ctx->prog_type == TGSI_PROCESSOR_GEOMETRY ||
ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL) ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL)
@ -4118,24 +4112,24 @@ static bool emit_header(struct dump_ctx *ctx)
if (ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL || if (ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL ||
ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL) ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL)
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_tessellation_shader : require\n"); emit_hdr(ctx, "#extension GL_ARB_tessellation_shader : require\n");
if (ctx->prog_type == TGSI_PROCESSOR_VERTEX && ctx->cfg->use_explicit_locations) if (ctx->prog_type == TGSI_PROCESSOR_VERTEX && ctx->cfg->use_explicit_locations)
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_explicit_attrib_location : require\n"); emit_hdr(ctx, "#extension GL_ARB_explicit_attrib_location : require\n");
if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT && fs_emit_layout(ctx)) if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT && fs_emit_layout(ctx))
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_fragment_coord_conventions : require\n"); emit_hdr(ctx, "#extension GL_ARB_fragment_coord_conventions : require\n");
if (ctx->num_ubo) if (ctx->num_ubo)
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_uniform_buffer_object : require\n"); emit_hdr(ctx, "#extension GL_ARB_uniform_buffer_object : require\n");
if (ctx->num_cull_dist_prop || ctx->key->prev_stage_num_cull_out) if (ctx->num_cull_dist_prop || ctx->key->prev_stage_num_cull_out)
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_cull_distance : require\n"); emit_hdr(ctx, "#extension GL_ARB_cull_distance : require\n");
if (ctx->ssbo_used_mask) if (ctx->ssbo_used_mask)
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_shader_storage_buffer_object : require\n"); emit_hdr(ctx, "#extension GL_ARB_shader_storage_buffer_object : require\n");
if (ctx->num_abo) { if (ctx->num_abo) {
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_shader_atomic_counters : require\n"); emit_hdr(ctx, "#extension GL_ARB_shader_atomic_counters : require\n");
EMIT_HDR_WITH_RET(ctx, "#extension GL_ARB_shader_atomic_counter_ops : require\n"); emit_hdr(ctx, "#extension GL_ARB_shader_atomic_counter_ops : require\n");
} }
for (uint32_t i = 0; i < ARRAY_SIZE(shader_req_table); i++) { for (uint32_t i = 0; i < ARRAY_SIZE(shader_req_table); i++) {
@ -4144,12 +4138,10 @@ static bool emit_header(struct dump_ctx *ctx)
if (ctx->shader_req_bits & shader_req_table[i].key) { if (ctx->shader_req_bits & shader_req_table[i].key) {
snprintf(buf, 128, "#extension GL_%s : require\n", shader_req_table[i].string); snprintf(buf, 128, "#extension GL_%s : require\n", shader_req_table[i].string);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
} }
return true;
} }
char vrend_shader_samplerreturnconv(enum tgsi_return_type type) char vrend_shader_samplerreturnconv(enum tgsi_return_type type)
@ -4239,7 +4231,7 @@ static const char *get_aux_string(unsigned location)
} }
} }
static bool emit_sampler_decl(struct dump_ctx *ctx, static void emit_sampler_decl(struct dump_ctx *ctx,
uint32_t i, uint32_t range, uint32_t i, uint32_t range,
const struct vrend_shader_sampler *sampler) const struct vrend_shader_sampler *sampler)
{ {
@ -4262,16 +4254,14 @@ static bool emit_sampler_decl(struct dump_ctx *ctx,
else else
snprintf(buf, 255, "uniform %s%csampler%s %ssamp%d;\n", precision, ptc, stc, sname, i); snprintf(buf, 255, "uniform %s%csampler%s %ssamp%d;\n", precision, ptc, stc, sname, i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
if (is_shad) { if (is_shad) {
snprintf(buf, 255, "uniform %svec4 %sshadmask%d;\n", precision, sname, i); snprintf(buf, 255, "uniform %svec4 %sshadmask%d;\n", precision, sname, i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
snprintf(buf, 255, "uniform %svec4 %sshadadd%d;\n", precision, sname, i); snprintf(buf, 255, "uniform %svec4 %sshadadd%d;\n", precision, sname, i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
ctx->shadow_samp_mask |= (1 << i); ctx->shadow_samp_mask |= (1 << i);
} }
return true;
} }
const char *get_internalformat_string(int virgl_format, enum tgsi_return_type *stype) const char *get_internalformat_string(int virgl_format, enum tgsi_return_type *stype)
@ -4404,7 +4394,7 @@ const char *get_internalformat_string(int virgl_format, enum tgsi_return_type *s
} }
} }
static bool emit_image_decl(struct dump_ctx *ctx, static void emit_image_decl(struct dump_ctx *ctx,
uint32_t i, uint32_t range, uint32_t i, uint32_t range,
const struct vrend_shader_image *image) const struct vrend_shader_image *image)
{ {
@ -4432,10 +4422,10 @@ static bool emit_image_decl(struct dump_ctx *ctx,
if (ctx->cfg->use_gles) { /* TODO: enable on OpenGL 4.2 and up also */ if (ctx->cfg->use_gles) { /* TODO: enable on OpenGL 4.2 and up also */
snprintf(buf, 255, "layout(binding=%d%s%s) ", snprintf(buf, 255, "layout(binding=%d%s%s) ",
i, formatstr[0] != '\0' ? ", " : "", formatstr); i, formatstr[0] != '\0' ? ", " : "", formatstr);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} else if (formatstr[0] != '\0') { } else if (formatstr[0] != '\0') {
snprintf(buf, 255, "layout(%s) ", formatstr); snprintf(buf, 255, "layout(%s) ", formatstr);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (range) if (range)
@ -4445,11 +4435,10 @@ static bool emit_image_decl(struct dump_ctx *ctx,
snprintf(buf, 255, "%s%suniform %s%cimage%s %simg%d;\n", snprintf(buf, 255, "%s%suniform %s%cimage%s %simg%d;\n",
access, volatile_str, precision, ptc, stc, sname, i); access, volatile_str, precision, ptc, stc, sname, i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
return true;
} }
static bool emit_ios(struct dump_ctx *ctx) static void emit_ios(struct dump_ctx *ctx)
{ {
uint32_t i; uint32_t i;
char buf[255]; char buf[255];
@ -4462,7 +4451,8 @@ static bool emit_ios(struct dump_ctx *ctx)
if (ctx->so && ctx->so->num_outputs >= PIPE_MAX_SO_OUTPUTS) { if (ctx->so && ctx->so->num_outputs >= PIPE_MAX_SO_OUTPUTS) {
fprintf(stderr, "Num outputs exceeded, max is %u\n", PIPE_MAX_SO_OUTPUTS); fprintf(stderr, "Num outputs exceeded, max is %u\n", PIPE_MAX_SO_OUTPUTS);
return false; set_hdr_error(ctx);
return;
} }
if (ctx->key->color_two_side) { if (ctx->key->color_two_side) {
@ -4478,22 +4468,22 @@ static bool emit_ios(struct dump_ctx *ctx)
upper_left ? "origin_upper_left" : "", upper_left ? "origin_upper_left" : "",
comma, comma,
ctx->fs_pixel_center ? "pixel_center_integer" : ""); ctx->fs_pixel_center ? "pixel_center_integer" : "");
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->early_depth_stencil) { if (ctx->early_depth_stencil) {
EMIT_HDR_WITH_RET(ctx, "layout(early_fragment_tests) in;\n"); emit_hdr(ctx, "layout(early_fragment_tests) in;\n");
} }
} }
if (ctx->prog_type == TGSI_PROCESSOR_COMPUTE) { if (ctx->prog_type == TGSI_PROCESSOR_COMPUTE) {
snprintf(buf, 255, "layout (local_size_x = %d, local_size_y = %d, local_size_z = %d) in;\n", snprintf(buf, 255, "layout (local_size_x = %d, local_size_y = %d, local_size_z = %d) in;\n",
ctx->local_cs_block_size[0], ctx->local_cs_block_size[1], ctx->local_cs_block_size[2]); ctx->local_cs_block_size[0], ctx->local_cs_block_size[1], ctx->local_cs_block_size[2]);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
if (ctx->req_local_mem) { if (ctx->req_local_mem) {
enum vrend_type_qualifier type = ctx->integer_memory ? INT : UINT; enum vrend_type_qualifier type = ctx->integer_memory ? INT : UINT;
snprintf(buf, 255, "shared %s values[%d];\n", get_string(type), ctx->req_local_mem / 4); snprintf(buf, 255, "shared %s values[%d];\n", get_string(type), ctx->req_local_mem / 4);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
@ -4505,9 +4495,9 @@ static bool emit_ios(struct dump_ctx *ctx)
snprintf(buf, 255, "layout(%s%s) in;\n", prim_to_name(ctx->gs_in_prim), snprintf(buf, 255, "layout(%s%s) in;\n", prim_to_name(ctx->gs_in_prim),
ctx->gs_num_invocations > 1 ? invocbuf : ""); ctx->gs_num_invocations > 1 ? invocbuf : "");
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
snprintf(buf, 255, "layout(%s, max_vertices = %d) out;\n", prim_to_name(ctx->gs_out_prim), ctx->gs_max_out_verts); snprintf(buf, 255, "layout(%s, max_vertices = %d) out;\n", prim_to_name(ctx->gs_out_prim), ctx->gs_max_out_verts);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx_indirect_inputs(ctx)) { if (ctx_indirect_inputs(ctx)) {
@ -4518,7 +4508,7 @@ static bool emit_ios(struct dump_ctx *ctx)
if (size < ctx->key->num_indirect_patch_inputs) if (size < ctx->key->num_indirect_patch_inputs)
size = ctx->key->num_indirect_patch_inputs; size = ctx->key->num_indirect_patch_inputs;
snprintf(buf, 255, "patch in vec4 %sp%d[%d];\n", name_prefix, ctx->patch_input_range.first, size); snprintf(buf, 255, "patch in vec4 %sp%d[%d];\n", name_prefix, ctx->patch_input_range.first, size);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
@ -4529,7 +4519,7 @@ static bool emit_ios(struct dump_ctx *ctx)
if (size < ctx->key->num_indirect_generic_inputs) if (size < ctx->key->num_indirect_generic_inputs)
size = ctx->key->num_indirect_generic_inputs; size = ctx->key->num_indirect_generic_inputs;
snprintf(buf, 255, "in block { vec4 %s%d[%d]; } blk[];\n", name_prefix, ctx->generic_input_range.first, size); snprintf(buf, 255, "in block { vec4 %s%d[%d]; } blk[];\n", name_prefix, ctx->generic_input_range.first, size);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
} }
@ -4537,7 +4527,7 @@ static bool emit_ios(struct dump_ctx *ctx)
if (!ctx->inputs[i].glsl_predefined_no_emit) { if (!ctx->inputs[i].glsl_predefined_no_emit) {
if (ctx->prog_type == TGSI_PROCESSOR_VERTEX && ctx->cfg->use_explicit_locations) { if (ctx->prog_type == TGSI_PROCESSOR_VERTEX && ctx->cfg->use_explicit_locations) {
snprintf(buf, 255, "layout(location=%d) ", ctx->inputs[i].first); snprintf(buf, 255, "layout(location=%d) ", ctx->inputs[i].first);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
prefix = ""; prefix = "";
auxprefix = ""; auxprefix = "";
@ -4562,19 +4552,19 @@ static bool emit_ios(struct dump_ctx *ctx)
} else } else
postfix[0] = 0; postfix[0] = 0;
snprintf(buf, 255, "%s%sin vec4 %s%s;\n", prefix, auxprefix, ctx->inputs[i].glsl_name, postfix); snprintf(buf, 255, "%s%sin vec4 %s%s;\n", prefix, auxprefix, ctx->inputs[i].glsl_name, postfix);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT && ctx->cfg->use_gles && if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT && ctx->cfg->use_gles &&
!ctx->key->winsys_adjust_y_emitted && !ctx->key->winsys_adjust_y_emitted &&
(ctx->key->coord_replace & (1 << ctx->inputs[i].sid))) { (ctx->key->coord_replace & (1 << ctx->inputs[i].sid))) {
ctx->key->winsys_adjust_y_emitted = true; ctx->key->winsys_adjust_y_emitted = true;
EMIT_HDR_WITH_RET(ctx, "uniform float winsys_adjust_y;\n"); emit_hdr(ctx, "uniform float winsys_adjust_y;\n");
} }
} }
if (ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL) { if (ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL) {
snprintf(buf, 255, "layout(vertices = %d) out;\n", ctx->tcs_vertices_out); snprintf(buf, 255, "layout(vertices = %d) out;\n", ctx->tcs_vertices_out);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL) { if (ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL) {
snprintf(buf, 255, "layout(%s, %s, %s%s) in;\n", snprintf(buf, 255, "layout(%s, %s, %s%s) in;\n",
@ -4582,7 +4572,7 @@ static bool emit_ios(struct dump_ctx *ctx)
get_spacing_string(ctx->tes_spacing), get_spacing_string(ctx->tes_spacing),
ctx->tes_vertex_order ? "cw" : "ccw", ctx->tes_vertex_order ? "cw" : "ccw",
ctx->tes_point_mode ? ", point_mode" : ""); ctx->tes_point_mode ? ", point_mode" : "");
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx_indirect_outputs(ctx)) { if (ctx_indirect_outputs(ctx)) {
@ -4590,17 +4580,17 @@ static bool emit_ios(struct dump_ctx *ctx)
if (ctx->prog_type == TGSI_PROCESSOR_VERTEX) { if (ctx->prog_type == TGSI_PROCESSOR_VERTEX) {
if (ctx->generic_output_range.used) { if (ctx->generic_output_range.used) {
snprintf(buf, 255, "out block { vec4 %s%d[%d]; } oblk;\n", name_prefix, ctx->generic_output_range.first, ctx->generic_output_range.last - ctx->generic_output_range.first + 1); snprintf(buf, 255, "out block { vec4 %s%d[%d]; } oblk;\n", name_prefix, ctx->generic_output_range.first, ctx->generic_output_range.last - ctx->generic_output_range.first + 1);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
if (ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL) { if (ctx->prog_type == TGSI_PROCESSOR_TESS_CTRL) {
if (ctx->generic_output_range.used) { if (ctx->generic_output_range.used) {
snprintf(buf, 255, "out block { vec4 %s%d[%d]; } oblk[];\n", name_prefix, ctx->generic_output_range.first, ctx->generic_output_range.last - ctx->generic_output_range.first + 1); snprintf(buf, 255, "out block { vec4 %s%d[%d]; } oblk[];\n", name_prefix, ctx->generic_output_range.first, ctx->generic_output_range.last - ctx->generic_output_range.first + 1);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->patch_output_range.used) { if (ctx->patch_output_range.used) {
snprintf(buf, 255, "patch out vec4 %sp%d[%d];\n", name_prefix, ctx->patch_output_range.first, ctx->patch_output_range.last - ctx->patch_output_range.first + 1); snprintf(buf, 255, "patch out vec4 %sp%d[%d];\n", name_prefix, ctx->patch_output_range.first, ctx->patch_output_range.last - ctx->patch_output_range.first + 1);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
} }
@ -4611,7 +4601,7 @@ static bool emit_ios(struct dump_ctx *ctx)
snprintf(buf, 255, "layout (location=%d) out vec4 fsout_c%d;\n", i, i); snprintf(buf, 255, "layout (location=%d) out vec4 fsout_c%d;\n", i, i);
else else
snprintf(buf, 255, "out vec4 fsout_c%d;\n", i); snprintf(buf, 255, "out vec4 fsout_c%d;\n", i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} else { } else {
for (i = 0; i < ctx->num_outputs; i++) { for (i = 0; i < ctx->num_outputs; i++) {
@ -4650,13 +4640,13 @@ static bool emit_ios(struct dump_ctx *ctx)
ctx->outputs[i].invariant ? "invariant " : "", ctx->outputs[i].invariant ? "invariant " : "",
ctx->outputs[i].fbfetch_used ? "inout" : "out", ctx->outputs[i].fbfetch_used ? "inout" : "out",
ctx->outputs[i].glsl_name); ctx->outputs[i].glsl_name);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} else if (ctx->outputs[i].invariant || ctx->outputs[i].precise) { } else if (ctx->outputs[i].invariant || ctx->outputs[i].precise) {
snprintf(buf, 255, "%s%s;\n", snprintf(buf, 255, "%s%s;\n",
ctx->outputs[i].precise ? "precise " : ctx->outputs[i].precise ? "precise " :
(ctx->outputs[i].invariant ? "invariant " : ""), (ctx->outputs[i].invariant ? "invariant " : ""),
ctx->outputs[i].glsl_name); ctx->outputs[i].glsl_name);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
} }
@ -4665,11 +4655,11 @@ static bool emit_ios(struct dump_ctx *ctx)
for (i = 0; i < 2; i++) { for (i = 0; i < 2; i++) {
if (fcolor_emitted[i] && !bcolor_emitted[i]) { if (fcolor_emitted[i] && !bcolor_emitted[i]) {
snprintf(buf, 255, "%sout vec4 ex_bc%d;\n", INTERP_PREFIX, i); snprintf(buf, 255, "%sout vec4 ex_bc%d;\n", INTERP_PREFIX, i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (bcolor_emitted[i] && !fcolor_emitted[i]) { if (bcolor_emitted[i] && !fcolor_emitted[i]) {
snprintf(buf, 255, "%sout vec4 ex_c%d;\n", INTERP_PREFIX, i); snprintf(buf, 255, "%sout vec4 ex_c%d;\n", INTERP_PREFIX, i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
} }
@ -4677,13 +4667,13 @@ static bool emit_ios(struct dump_ctx *ctx)
if (ctx->prog_type == TGSI_PROCESSOR_VERTEX || if (ctx->prog_type == TGSI_PROCESSOR_VERTEX ||
ctx->prog_type == TGSI_PROCESSOR_GEOMETRY || ctx->prog_type == TGSI_PROCESSOR_GEOMETRY ||
ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL) { ctx->prog_type == TGSI_PROCESSOR_TESS_EVAL) {
EMIT_HDR_WITH_RET(ctx, "uniform float winsys_adjust_y;\n"); emit_hdr(ctx, "uniform float winsys_adjust_y;\n");
} }
if (ctx->prog_type == TGSI_PROCESSOR_VERTEX) { if (ctx->prog_type == TGSI_PROCESSOR_VERTEX) {
if (ctx->has_clipvertex) { if (ctx->has_clipvertex) {
snprintf(buf, 255, "%svec4 clipv_tmp;\n", ctx->has_clipvertex_so ? "out " : ""); snprintf(buf, 255, "%svec4 clipv_tmp;\n", ctx->has_clipvertex_so ? "out " : "");
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->num_clip_dist || ctx->key->clip_plane_enable) { if (ctx->num_clip_dist || ctx->key->clip_plane_enable) {
bool has_prop = (ctx->num_clip_dist_prop + ctx->num_cull_dist_prop) > 0; bool has_prop = (ctx->num_clip_dist_prop + ctx->num_cull_dist_prop) > 0;
@ -4701,17 +4691,17 @@ static bool emit_ios(struct dump_ctx *ctx)
} else } else
snprintf(clip_buf, 64, "out float gl_ClipDistance[%d];\n", num_clip_dists); snprintf(clip_buf, 64, "out float gl_ClipDistance[%d];\n", num_clip_dists);
if (ctx->key->clip_plane_enable) { if (ctx->key->clip_plane_enable) {
EMIT_HDR_WITH_RET(ctx, "uniform vec4 clipp[8];\n"); emit_hdr(ctx, "uniform vec4 clipp[8];\n");
} }
if (ctx->key->gs_present || ctx->key->tes_present) { if (ctx->key->gs_present || ctx->key->tes_present) {
ctx->vs_has_pervertex = true; ctx->vs_has_pervertex = true;
snprintf(buf, 255, "out gl_PerVertex {\n vec4 gl_Position;\n float gl_PointSize;\n%s%s};\n", clip_buf, cull_buf); snprintf(buf, 255, "out gl_PerVertex {\n vec4 gl_Position;\n float gl_PointSize;\n%s%s};\n", clip_buf, cull_buf);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} else { } else {
snprintf(buf, 255, "%s%s", clip_buf, cull_buf); snprintf(buf, 255, "%s%s", clip_buf, cull_buf);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
EMIT_HDR_WITH_RET(ctx, "vec4 clip_dist_temp[2];\n"); emit_hdr(ctx, "vec4 clip_dist_temp[2];\n");
} }
} }
@ -4729,7 +4719,7 @@ static bool emit_ios(struct dump_ctx *ctx)
snprintf(cull_var, 64, "float gl_CullDistance[%d];\n", cull_dist); snprintf(cull_var, 64, "float gl_CullDistance[%d];\n", cull_dist);
snprintf(buf, 255, "in gl_PerVertex {\n vec4 gl_Position;\n float gl_PointSize; \n %s%s\n} gl_in[];\n", clip_var, cull_var); snprintf(buf, 255, "in gl_PerVertex {\n vec4 gl_Position;\n float gl_PointSize; \n %s%s\n} gl_in[];\n", clip_var, cull_var);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->num_clip_dist) { if (ctx->num_clip_dist) {
bool has_prop = (ctx->num_clip_dist_prop + ctx->num_cull_dist_prop) > 0; bool has_prop = (ctx->num_clip_dist_prop + ctx->num_cull_dist_prop) > 0;
@ -4747,20 +4737,20 @@ static bool emit_ios(struct dump_ctx *ctx)
} else } else
snprintf(clip_buf, 64, "out float gl_ClipDistance[%d];\n", num_clip_dists); snprintf(clip_buf, 64, "out float gl_ClipDistance[%d];\n", num_clip_dists);
snprintf(buf, 255, "%s%s\n", clip_buf, cull_buf); snprintf(buf, 255, "%s%s\n", clip_buf, cull_buf);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
snprintf(buf, 255, "vec4 clip_dist_temp[2];\n"); snprintf(buf, 255, "vec4 clip_dist_temp[2];\n");
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT && ctx->num_in_clip_dist) { if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT && ctx->num_in_clip_dist) {
if (ctx->key->prev_stage_num_clip_out) { if (ctx->key->prev_stage_num_clip_out) {
snprintf(buf, 255, "in float gl_ClipDistance[%d];\n", ctx->key->prev_stage_num_clip_out); snprintf(buf, 255, "in float gl_ClipDistance[%d];\n", ctx->key->prev_stage_num_clip_out);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->key->prev_stage_num_cull_out) { if (ctx->key->prev_stage_num_cull_out) {
snprintf(buf, 255, "in float gl_CullDistance[%d];\n", ctx->key->prev_stage_num_cull_out); snprintf(buf, 255, "in float gl_CullDistance[%d];\n", ctx->key->prev_stage_num_cull_out);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
@ -4778,13 +4768,13 @@ static bool emit_ios(struct dump_ctx *ctx)
snprintf(cull_var, 64, "float gl_CullDistance[%d];\n", cull_dist); snprintf(cull_var, 64, "float gl_CullDistance[%d];\n", cull_dist);
snprintf(buf, 255, "in gl_PerVertex {\n vec4 gl_Position;\n float gl_PointSize; \n %s%s} gl_in[];\n", clip_var, cull_var); snprintf(buf, 255, "in gl_PerVertex {\n vec4 gl_Position;\n float gl_PointSize; \n %s%s} gl_in[];\n", clip_var, cull_var);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->num_clip_dist) { if (ctx->num_clip_dist) {
snprintf(buf, 255, "out gl_PerVertex {\n vec4 gl_Position;\n float gl_PointSize;\n float gl_ClipDistance[%d];\n} gl_out[];\n", ctx->num_clip_dist ? ctx->num_clip_dist : 8); snprintf(buf, 255, "out gl_PerVertex {\n vec4 gl_Position;\n float gl_PointSize;\n float gl_ClipDistance[%d];\n} gl_out[];\n", ctx->num_clip_dist ? ctx->num_clip_dist : 8);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
snprintf(buf, 255, "vec4 clip_dist_temp[2];\n"); snprintf(buf, 255, "vec4 clip_dist_temp[2];\n");
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
@ -4803,48 +4793,48 @@ static bool emit_ios(struct dump_ctx *ctx)
snprintf(buf, 255, "layout (stream=%d) out %s tfout%d;\n", ctx->so->output[i].stream, outtype, i); snprintf(buf, 255, "layout (stream=%d) out %s tfout%d;\n", ctx->so->output[i].stream, outtype, i);
else else
snprintf(buf, 255, "out %s tfout%d;\n", outtype, i); snprintf(buf, 255, "out %s tfout%d;\n", outtype, i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
for (i = 0; i < ctx->num_temp_ranges; i++) { for (i = 0; i < ctx->num_temp_ranges; i++) {
snprintf(buf, 255, "vec4 temp%d[%d];\n", ctx->temp_ranges[i].first, ctx->temp_ranges[i].last - ctx->temp_ranges[i].first + 1); snprintf(buf, 255, "vec4 temp%d[%d];\n", ctx->temp_ranges[i].first, ctx->temp_ranges[i].last - ctx->temp_ranges[i].first + 1);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->write_mul_utemp) { if (ctx->write_mul_utemp) {
EMIT_HDR_WITH_RET(ctx, "uvec4 mul_utemp;\n"); emit_hdr(ctx, "uvec4 mul_utemp;\n");
EMIT_HDR_WITH_RET(ctx, "uvec4 umul_temp;\n"); emit_hdr(ctx, "uvec4 umul_temp;\n");
} }
if (ctx->write_mul_itemp) { if (ctx->write_mul_itemp) {
EMIT_HDR_WITH_RET(ctx, "ivec4 mul_itemp;\n"); emit_hdr(ctx, "ivec4 mul_itemp;\n");
EMIT_HDR_WITH_RET(ctx, "ivec4 imul_temp;\n"); emit_hdr(ctx, "ivec4 imul_temp;\n");
} }
if (ctx->ssbo_used_mask || ctx->has_file_memory) { if (ctx->ssbo_used_mask || ctx->has_file_memory) {
EMIT_HDR_WITH_RET(ctx, "uint ssbo_addr_temp;\n"); emit_hdr(ctx, "uint ssbo_addr_temp;\n");
} }
if (ctx->shader_req_bits & SHADER_REQ_FP64) { if (ctx->shader_req_bits & SHADER_REQ_FP64) {
EMIT_HDR_WITH_RET(ctx, "dvec2 fp64_dst[3];\n"); emit_hdr(ctx, "dvec2 fp64_dst[3];\n");
EMIT_HDR_WITH_RET(ctx, "dvec2 fp64_src[4];\n"); emit_hdr(ctx, "dvec2 fp64_src[4];\n");
} }
for (i = 0; i < ctx->num_address; i++) { for (i = 0; i < ctx->num_address; i++) {
snprintf(buf, 255, "int addr%d;\n", i); snprintf(buf, 255, "int addr%d;\n", i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->num_consts) { if (ctx->num_consts) {
const char *cname = tgsi_proc_to_prefix(ctx->prog_type); const char *cname = tgsi_proc_to_prefix(ctx->prog_type);
snprintf(buf, 255, "uniform uvec4 %sconst0[%d];\n", cname, ctx->num_consts); snprintf(buf, 255, "uniform uvec4 %sconst0[%d];\n", cname, ctx->num_consts);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->key->color_two_side) { if (ctx->key->color_two_side) {
if (ctx->color_in_mask & 1) if (ctx->color_in_mask & 1)
EMIT_HDR_WITH_RET(ctx, "vec4 realcolor0;\n"); emit_hdr(ctx, "vec4 realcolor0;\n");
if (ctx->color_in_mask & 2) if (ctx->color_in_mask & 2)
EMIT_HDR_WITH_RET(ctx, "vec4 realcolor1;\n"); emit_hdr(ctx, "vec4 realcolor1;\n");
} }
if (ctx->num_ubo) { if (ctx->num_ubo) {
const char *cname = tgsi_proc_to_prefix(ctx->prog_type); const char *cname = tgsi_proc_to_prefix(ctx->prog_type);
@ -4852,11 +4842,11 @@ static bool emit_ios(struct dump_ctx *ctx)
if (ctx->info.dimension_indirect_files & (1 << TGSI_FILE_CONSTANT)) { if (ctx->info.dimension_indirect_files & (1 << TGSI_FILE_CONSTANT)) {
require_glsl_ver(ctx, 150); require_glsl_ver(ctx, 150);
snprintf(buf, 255, "uniform %subo { vec4 ubocontents[%d]; } %suboarr[%d];\n", cname, ctx->ubo_sizes[0], cname, ctx->num_ubo); snprintf(buf, 255, "uniform %subo { vec4 ubocontents[%d]; } %suboarr[%d];\n", cname, ctx->ubo_sizes[0], cname, ctx->num_ubo);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} else { } else {
for (i = 0; i < ctx->num_ubo; i++) { for (i = 0; i < ctx->num_ubo; i++) {
snprintf(buf, 255, "uniform %subo%d { vec4 %subo%dcontents[%d]; };\n", cname, ctx->ubo_idx[i], cname, ctx->ubo_idx[i], ctx->ubo_sizes[i]); snprintf(buf, 255, "uniform %subo%d { vec4 %subo%dcontents[%d]; };\n", cname, ctx->ubo_idx[i], cname, ctx->ubo_idx[i], ctx->ubo_sizes[i]);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
} }
@ -4865,8 +4855,7 @@ static bool emit_ios(struct dump_ctx *ctx)
for (i = 0; i < ctx->num_sampler_arrays; i++) { for (i = 0; i < ctx->num_sampler_arrays; i++) {
uint32_t first = ctx->sampler_arrays[i].first; uint32_t first = ctx->sampler_arrays[i].first;
uint32_t range = ctx->sampler_arrays[i].array_size; uint32_t range = ctx->sampler_arrays[i].array_size;
if (!emit_sampler_decl(ctx, first, range, ctx->samplers + first)) emit_sampler_decl(ctx, first, range, ctx->samplers + first);
return false;
} }
} else { } else {
nsamp = util_last_bit(ctx->samplers_used); nsamp = util_last_bit(ctx->samplers_used);
@ -4875,8 +4864,7 @@ static bool emit_ios(struct dump_ctx *ctx)
if ((ctx->samplers_used & (1 << i)) == 0) if ((ctx->samplers_used & (1 << i)) == 0)
continue; continue;
if (!emit_sampler_decl(ctx, i, 0, ctx->samplers + i)) emit_sampler_decl(ctx, i, 0, ctx->samplers + i);
return false;
} }
} }
@ -4884,15 +4872,13 @@ static bool emit_ios(struct dump_ctx *ctx)
for (i = 0; i < ctx->num_image_arrays; i++) { for (i = 0; i < ctx->num_image_arrays; i++) {
uint32_t first = ctx->image_arrays[i].first; uint32_t first = ctx->image_arrays[i].first;
uint32_t range = ctx->image_arrays[i].array_size; uint32_t range = ctx->image_arrays[i].array_size;
if (!emit_image_decl(ctx, first, range, ctx->images + first)) emit_image_decl(ctx, first, range, ctx->images + first);
return false;
} }
} else { } else {
uint32_t mask = ctx->images_used_mask; uint32_t mask = ctx->images_used_mask;
while (mask) { while (mask) {
i = u_bit_scan(&mask); i = u_bit_scan(&mask);
if (!emit_image_decl(ctx, i, 0, ctx->images + i)) emit_image_decl(ctx, i, 0, ctx->images + i);
return false;
} }
} }
@ -4901,7 +4887,7 @@ static bool emit_ios(struct dump_ctx *ctx)
snprintf(buf, 255, "layout (binding = %d, offset = %d) uniform atomic_uint ac%d[%d];\n", ctx->abo_idx[i], ctx->abo_offsets[i] * 4, i, ctx->abo_sizes[i]); snprintf(buf, 255, "layout (binding = %d, offset = %d) uniform atomic_uint ac%d[%d];\n", ctx->abo_idx[i], ctx->abo_offsets[i] * 4, i, ctx->abo_sizes[i]);
else else
snprintf(buf, 255, "layout (binding = %d, offset = %d) uniform atomic_uint ac%d;\n", ctx->abo_idx[i], ctx->abo_offsets[i] * 4, i); snprintf(buf, 255, "layout (binding = %d, offset = %d) uniform atomic_uint ac%d;\n", ctx->abo_idx[i], ctx->abo_offsets[i] * 4, i);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
if (ctx->info.indirect_files & (1 << TGSI_FILE_BUFFER)) { if (ctx->info.indirect_files & (1 << TGSI_FILE_BUFFER)) {
@ -4911,7 +4897,7 @@ static bool emit_ios(struct dump_ctx *ctx)
u_bit_scan_consecutive_range(&mask, &start, &count); u_bit_scan_consecutive_range(&mask, &start, &count);
const char *atomic = (ctx->ssbo_atomic_mask & (1 << start)) ? "atomic" : ""; const char *atomic = (ctx->ssbo_atomic_mask & (1 << start)) ? "atomic" : "";
snprintf(buf, 255, "layout (binding = %d, std430) buffer %sssbo%d { uint %sssbocontents%d[]; } %sssboarr%s[%d];\n", start, sname, start, sname, start, sname, atomic, count); snprintf(buf, 255, "layout (binding = %d, std430) buffer %sssbo%d { uint %sssbocontents%d[]; } %sssboarr%s[%d];\n", start, sname, start, sname, start, sname, atomic, count);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} else { } else {
uint32_t mask = ctx->ssbo_used_mask; uint32_t mask = ctx->ssbo_used_mask;
@ -4921,15 +4907,14 @@ static bool emit_ios(struct dump_ctx *ctx)
enum vrend_type_qualifier type = (ctx->ssbo_integer_mask & (1 << id)) ? INT : UINT; enum vrend_type_qualifier type = (ctx->ssbo_integer_mask & (1 << id)) ? INT : UINT;
snprintf(buf, 255, "layout (binding = %d, std430) buffer %sssbo%d { %s %sssbocontents%d[]; };\n", id, sname, id, snprintf(buf, 255, "layout (binding = %d, std430) buffer %sssbo%d { %s %sssbocontents%d[]; };\n", id, sname, id,
get_string(type), sname, id); get_string(type), sname, id);
EMIT_HDR_WITH_RET(ctx, buf); emit_hdr(ctx, buf);
} }
} }
if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT && if (ctx->prog_type == TGSI_PROCESSOR_FRAGMENT &&
ctx->key->pstipple_tex == true) { ctx->key->pstipple_tex == true) {
EMIT_HDR_WITH_RET(ctx, "uniform sampler2D pstipple_sampler;\nfloat stip_temp;\n"); emit_hdr(ctx, "uniform sampler2D pstipple_sampler;\nfloat stip_temp;\n");
} }
return true;
} }
static boolean fill_fragment_interpolants(struct dump_ctx *ctx, struct vrend_shader_info *sinfo) static boolean fill_fragment_interpolants(struct dump_ctx *ctx, struct vrend_shader_info *sinfo)
@ -5070,11 +5055,8 @@ char *vrend_convert_shader(struct vrend_context *rctx,
if (!strbuf_alloc(&ctx.glsl_hdr, 1024)) if (!strbuf_alloc(&ctx.glsl_hdr, 1024))
goto fail; goto fail;
if (!emit_header(&ctx)) emit_header(&ctx);
goto fail; emit_ios(&ctx);
if (!emit_ios(&ctx))
goto fail;
if (strbuf_get_error(&ctx.glsl_hdr)) if (strbuf_get_error(&ctx.glsl_hdr))
goto fail; goto fail;

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