*/
-#include "glheader.h"
-#include "macros.h"
-#include "enums.h"
+#include "main/glheader.h"
+#include "main/macros.h"
+#include "main/enums.h"
#include "brw_context.h"
#include "brw_wm.h"
#include "brw_util.h"
return src_swizzle(reg, x, x, x, x);
}
+static struct prog_src_register src_swizzle4( struct prog_src_register reg, uint swizzle )
+{
+ reg.Swizzle = swizzle;
+ return reg;
+}
+
/***********************************************************************
* Dest regs
reg.File = file;
reg.Index = idx;
reg.WriteMask = WRITEMASK_XYZW;
+ reg.RelAddr = 0;
reg.CondMask = 0;
reg.CondSwizzle = 0;
- reg.pad = 0;
reg.CondSrc = 0;
+ reg.pad = 0;
return reg;
}
{
struct prog_instruction *inst = get_fp_inst(c);
*inst = *inst0;
- inst->Data = (void *)inst0;
return inst;
}
idx = _mesa_add_state_reference( paramList, tokens );
- /* Recalculate state dependency:
- */
- c->fp->param_state = paramList->StateFlags;
-
return src_reg(PROGRAM_STATE_VAR, idx);
}
}
}
+
+/**
+ * Some TEX instructions require extra code, cube map coordinate
+ * normalization, or coordinate scaling for RECT textures, etc.
+ * This function emits those extra instructions and the TEX
+ * instruction itself.
+ */
static void precalc_tex( struct brw_wm_compile *c,
const struct prog_instruction *inst )
{
struct prog_src_register coord;
struct prog_dst_register tmpcoord;
- GLuint unit = c->fp->program.Base.SamplerUnits[inst->TexSrcUnit];
+ const GLuint unit = c->fp->program.Base.SamplerUnits[inst->TexSrcUnit];
if (inst->TexSrcTarget == TEXTURE_CUBE_INDEX) {
struct prog_instruction *out;
struct prog_src_register tmp1src = src_reg_from_dst(tmp1);
struct prog_src_register src0 = inst->SrcReg[0];
+ /* find longest component of coord vector and normalize it */
tmpcoord = get_temp(c);
coord = src_reg_from_dst(tmpcoord);
+ /* tmpcoord = src0 (i.e.: coord = src0) */
out = emit_op(c, OPCODE_MOV,
tmpcoord,
0, 0, 0,
out->SrcReg[0].NegateBase = 0;
out->SrcReg[0].Abs = 1;
+ /* tmp0 = MAX(coord.X, coord.Y) */
emit_op(c, OPCODE_MAX,
tmp0,
0, 0, 0,
src_swizzle1(coord, Y),
src_undef());
+ /* tmp1 = MAX(tmp0, coord.Z) */
emit_op(c, OPCODE_MAX,
tmp1,
0, 0, 0,
src_swizzle1(coord, Z),
src_undef());
+ /* tmp0 = 1 / tmp1 */
emit_op(c, OPCODE_RCP,
tmp0,
0, 0, 0,
src_undef(),
src_undef());
+ /* tmpCoord = src0 * tmp0 */
emit_op(c, OPCODE_MUL,
tmpcoord,
0, 0, 0,
release_temp(c, tmp0);
release_temp(c, tmp1);
- } else if (inst->TexSrcTarget == TEXTURE_RECT_INDEX) {
+ }
+ else if (inst->TexSrcTarget == TEXTURE_RECT_INDEX) {
struct prog_src_register scale =
search_or_add_param5( c,
STATE_INTERNAL,
* conversion requires allocating a temporary variable which we
* don't have the facility to do that late in the compilation.
*/
- if (!(c->key.yuvtex_mask & (1<<unit))) {
- emit_op(c,
- OPCODE_TEX,
- inst->DstReg,
- inst->SaturateMode,
- unit,
- inst->TexSrcTarget,
- coord,
- src_undef(),
- src_undef());
- }
- else {
- GLboolean swap_uv = c->key.yuvtex_swap_mask & (1<<unit);
+ if (c->key.yuvtex_mask & (1 << unit)) {
+ /* convert ycbcr to RGBA */
+ GLboolean swap_uv = c->key.yuvtex_swap_mask & (1<<unit);
/*
CONST C0 = { -.5, -.0625, -.5, 1.164 }
release_temp(c, tmp);
}
+ else {
+ /* ordinary RGBA tex instruction */
+ emit_op(c,
+ OPCODE_TEX,
+ inst->DstReg,
+ inst->SaturateMode,
+ unit,
+ inst->TexSrcTarget,
+ coord,
+ src_undef(),
+ src_undef());
+ }
+
+ /* For GL_EXT_texture_swizzle: */
+ if (c->key.tex_swizzles[unit] != SWIZZLE_NOOP) {
+ /* swizzle the result of the TEX instruction */
+ struct prog_src_register tmpsrc = src_reg_from_dst(inst->DstReg);
+ emit_op(c, OPCODE_SWZ,
+ inst->DstReg,
+ SATURATE_OFF, /* saturate already done above */
+ 0, 0, /* tex unit, target N/A */
+ src_swizzle4(tmpsrc, c->key.tex_swizzles[unit]),
+ src_undef(),
+ src_undef());
+ }
if ((inst->TexSrcTarget == TEXTURE_RECT_INDEX) ||
(inst->TexSrcTarget == TEXTURE_CUBE_INDEX))
-
-
-/***********************************************************************
- * Add instructions to perform fog blending
- */
-
-static void fog_blend( struct brw_wm_compile *c,
- struct prog_src_register fog_factor )
-{
- struct prog_dst_register outcolor = dst_reg(PROGRAM_OUTPUT, FRAG_RESULT_COLR);
- struct prog_src_register fogcolor = search_or_add_param5( c, STATE_FOG_COLOR, 0,0,0,0 );
-
- /* color.xyz = LRP fog_factor.xxxx, output_color, fog_color */
-
- emit_op(c,
- OPCODE_LRP,
- dst_mask(outcolor, WRITEMASK_XYZ),
- 0, 0, 0,
- fog_factor,
- src_reg_from_dst(outcolor),
- fogcolor);
-}
-
-
-
-/* This one is simple - just take the interpolated fog coordinate and
- * use it as the fog blend factor.
- */
-static void fog_interpolated( struct brw_wm_compile *c )
-{
- struct prog_src_register fogc = src_reg(PROGRAM_INPUT, FRAG_ATTRIB_FOGC);
-
- if (!(c->fp_interp_emitted & (1<<FRAG_ATTRIB_FOGC)))
- emit_interp(c, FRAG_ATTRIB_FOGC);
-
- fog_blend( c, src_swizzle1(fogc, GET_SWZ(fogc.Swizzle,X)));
-}
-
-static void emit_fog( struct brw_wm_compile *c )
-{
- if (!c->fp->program.FogOption)
- return;
-
- if (1)
- fog_interpolated( c );
- else {
- /* TODO: per-pixel fog */
- assert(0);
- }
-}
-
static void emit_fb_write( struct brw_wm_compile *c )
{
- struct prog_src_register outcolor = src_reg(PROGRAM_OUTPUT, FRAG_RESULT_COLR);
struct prog_src_register payload_r0_depth = src_reg(PROGRAM_PAYLOAD, PAYLOAD_DEPTH);
struct prog_src_register outdepth = src_reg(PROGRAM_OUTPUT, FRAG_RESULT_DEPR);
+ struct prog_src_register outcolor;
GLuint i;
struct prog_instruction *inst, *last_inst;
}
}
last_inst->Sampler |= 1; //eot
- }else {
+ }
+ else {
+ /* if gl_FragData[0] is written, use it, else use gl_FragColor */
+ if (c->fp->program.Base.OutputsWritten & (1 << FRAG_RESULT_DATA0))
+ outcolor = src_reg(PROGRAM_OUTPUT, FRAG_RESULT_DATA0);
+ else
+ outcolor = src_reg(PROGRAM_OUTPUT, FRAG_RESULT_COLR);
+
inst = emit_op(c, WM_FB_WRITE, dst_mask(dst_undef(),0),
0, 0, 0, outcolor, payload_r0_depth, outdepth);
inst->Sampler = 1|(0<<1);
}
}
+
+/**
+ * Initial pass for fragment program code generation.
+ * This function is used by both the GLSL and non-GLSL paths.
+ */
void brw_wm_pass_fp( struct brw_wm_compile *c )
{
struct brw_fragment_program *fp = c->fp;
GLuint insn;
if (INTEL_DEBUG & DEBUG_WM) {
- _mesa_printf("\n\n\npre-fp:\n");
+ _mesa_printf("pre-fp:\n");
_mesa_print_program(&fp->program.Base);
_mesa_printf("\n");
}
c->pixel_w = src_undef();
c->nr_fp_insns = 0;
- /* Emit preamble instructions:
+ /* Emit preamble instructions. This is where special instructions such as
+ * WM_CINTERP, WM_LINTERP, WM_PINTERP and WM_WPOSXY are emitted to
+ * compute shader inputs from varying vars.
*/
-
-
for (insn = 0; insn < fp->program.Base.NumInstructions; insn++) {
const struct prog_instruction *inst = &fp->program.Base.Instructions[insn];
validate_src_regs(c, inst);
validate_dst_regs(c, inst);
}
+
+ /* Loop over all instructions doing assorted simplifications and
+ * transformations.
+ */
for (insn = 0; insn < fp->program.Base.NumInstructions; insn++) {
const struct prog_instruction *inst = &fp->program.Base.Instructions[insn];
struct prog_instruction *out;
* necessary:
*/
-
switch (inst->Opcode) {
case OPCODE_SWZ:
out = emit_insn(c, inst);
emit_ddy(c, inst);
break;
case OPCODE_END:
- emit_fog(c);
emit_fb_write(c);
break;
case OPCODE_PRINT:
}
if (INTEL_DEBUG & DEBUG_WM) {
- _mesa_printf("\n\n\npass_fp:\n");
+ _mesa_printf("pass_fp:\n");
print_insns( c->prog_instructions, c->nr_fp_insns );
_mesa_printf("\n");
}