diff options
author | Nicolai Haehnle <[email protected]> | 2007-03-19 19:46:25 +0100 |
---|---|---|
committer | Nicolai Haehnle <[email protected]> | 2007-03-19 19:49:06 +0100 |
commit | 7b992d024b20df111db007286e5a54afcb531fb1 (patch) | |
tree | ff5199e9cd4185c0ee8cd596d57cdbe8d9c2266a /src/mesa | |
parent | c4bf863f4cb48c2de284933bb1fc725b540ee810 (diff) |
r300: Whitespace cleanup (remove trailing spaces)
Diffstat (limited to 'src/mesa')
-rw-r--r-- | src/mesa/drivers/dri/r300/r300_fragprog.c | 218 |
1 files changed, 109 insertions, 109 deletions
diff --git a/src/mesa/drivers/dri/r300/r300_fragprog.c b/src/mesa/drivers/dri/r300/r300_fragprog.c index fb559e880ae..93b9c396354 100644 --- a/src/mesa/drivers/dri/r300/r300_fragprog.c +++ b/src/mesa/drivers/dri/r300/r300_fragprog.c @@ -307,17 +307,17 @@ static int get_hw_temp(struct r300_fragment_program *rp, int slot) { COMPILE_STATE; int r; - + for(r = 0; r < PFS_NUM_TEMP_REGS; ++r) { if (cs->hwtemps[r].free >= 0 && cs->hwtemps[r].free <= slot) break; } - + if (r >= PFS_NUM_TEMP_REGS) { ERROR("Out of hardware temps\n"); return 0; } - + // Reserved is used to avoid the following scenario: // R300 temporary X is first assigned to Mesa temporary Y during vector ops // R300 temporary X is then assigned to Mesa temporary Z for further vector ops @@ -326,17 +326,17 @@ static int get_hw_temp(struct r300_fragment_program *rp, int slot) // End scenario. cs->hwtemps[r].reserved = cs->hwtemps[r].free; cs->hwtemps[r].free = -1; - + // Reset to some value that won't mess things up when the user // tries to read from a temporary that hasn't been assigned a value yet. // In the normal case, vector_valid and scalar_valid should be set to // a sane value by the first emit that writes to this temporary. cs->hwtemps[r].vector_valid = 0; cs->hwtemps[r].scalar_valid = 0; - + if (r > rp->max_temp_idx) rp->max_temp_idx = r; - + return r; } @@ -351,25 +351,25 @@ static int get_hw_temp_tex(struct r300_fragment_program *rp) for(r = 0; r < PFS_NUM_TEMP_REGS; ++r) { if (cs->used_in_node & (1 << r)) continue; - + // Note: Be very careful here if (cs->hwtemps[r].free >= 0 && cs->hwtemps[r].free <= 0) break; } - + if (r >= PFS_NUM_TEMP_REGS) return get_hw_temp(rp, 0); /* Will cause an indirection */ cs->hwtemps[r].reserved = cs->hwtemps[r].free; cs->hwtemps[r].free = -1; - + // Reset to some value that won't mess things up when the user // tries to read from a temporary that hasn't been assigned a value yet. // In the normal case, vector_valid and scalar_valid should be set to // a sane value by the first emit that writes to this temporary. cs->hwtemps[r].vector_valid = cs->nrslots; cs->hwtemps[r].scalar_valid = cs->nrslots; - + if (r > rp->max_temp_idx) rp->max_temp_idx = r; @@ -382,7 +382,7 @@ static int get_hw_temp_tex(struct r300_fragment_program *rp) static void free_hw_temp(struct r300_fragment_program *rp, int idx) { COMPILE_STATE; - + // Be very careful here. Consider sequences like // MAD r0, r1,r2,r3 // TEX r4, ... @@ -457,7 +457,7 @@ static void free_temp(struct r300_fragment_program *rp, GLuint r) if (!(cs->temp_in_use & (1 << index))) return; - + if (REG_GET_TYPE(r) == REG_TYPE_TEMP) { free_hw_temp(rp, cs->temps[index].reg); cs->temps[index].reg = -1; @@ -493,7 +493,7 @@ static GLuint emit_param4fv(struct r300_fragment_program *rp, } static GLuint emit_const4fv(struct r300_fragment_program *rp, const GLfloat* cp) -{ +{ GLuint r = undef; GLuint index; @@ -691,7 +691,7 @@ static GLuint do_swizzle(struct r300_fragment_program *rp, GLuint offset; for(i=0; i < 4; ++i){ offset = GET_SWZ(arbswz, i); - + newswz |= (offset <= 3)?GET_SWZ(vsrcswz, offset) << i*3:offset << i*3; } @@ -800,7 +800,7 @@ static GLuint t_dst(struct r300_fragment_program *rp, struct prog_dst_register dest) { GLuint r = undef; - + switch (dest.File) { case PROGRAM_TEMPORARY: REG_SET_INDEX(r, dest.Index); @@ -910,19 +910,19 @@ static int t_hw_dst(struct r300_fragment_program *rp, ERROR("invalid dest reg type %d\n", REG_GET_TYPE(dest)); return 0; } - + return idx; } static void emit_nop(struct r300_fragment_program *rp) { COMPILE_STATE; - + if (cs->nrslots >= PFS_MAX_ALU_INST) { ERROR("Out of ALU instruction slots\n"); return; } - + rp->alu.inst[cs->nrslots].inst0 = NOP_INST0; rp->alu.inst[cs->nrslots].inst1 = NOP_INST1; rp->alu.inst[cs->nrslots].inst2 = NOP_INST2; @@ -940,7 +940,7 @@ static void emit_tex(struct r300_fragment_program *rp, GLuint din = cs->dest_in_node, uin = cs->used_in_node; int unit = fpi->TexSrcUnit; int hwsrc, hwdest; - + /* Resolve source/dest to hardware registers */ hwsrc = t_hw_src(rp, coord, GL_TRUE); if (opcode != R300_FPITX_OP_KIL) { @@ -952,7 +952,7 @@ static void emit_tex(struct r300_fragment_program *rp, dest = get_temp_reg_tex(rp); } hwdest = t_hw_dst(rp, dest, GL_TRUE, rp->node[rp->cur_node].alu_offset); - + /* Use a temp that hasn't been used in this node, rather * than causing an indirection */ @@ -965,17 +965,17 @@ static void emit_tex(struct r300_fragment_program *rp, hwdest = 0; unit = 0; } - + /* Indirection if source has been written in this node, or if the * dest has been read/written in this node */ if ((REG_GET_TYPE(coord) != REG_TYPE_CONST && (din & (1<<hwsrc))) || (uin & (1<<hwdest))) { - + /* Finish off current node */ if (rp->node[rp->cur_node].alu_offset == cs->nrslots) emit_nop(rp); - + rp->node[rp->cur_node].alu_end = cs->nrslots - rp->node[rp->cur_node].alu_offset - 1; assert(rp->node[rp->cur_node].alu_end >= 0); @@ -989,12 +989,12 @@ static void emit_tex(struct r300_fragment_program *rp, rp->node[rp->cur_node].tex_offset = rp->tex.length; rp->node[rp->cur_node].alu_offset = cs->nrslots; rp->node[rp->cur_node].tex_end = -1; - rp->node[rp->cur_node].alu_end = -1; + rp->node[rp->cur_node].alu_end = -1; rp->node[rp->cur_node].flags = 0; cs->used_in_node = 0; cs->dest_in_node = 0; } - + if (rp->cur_node == 0) rp->first_node_has_tex = 1; @@ -1005,7 +1005,7 @@ static void emit_tex(struct r300_fragment_program *rp, /* not entirely sure about this */ | (opcode << R300_FPITX_OPCODE_SHIFT); - cs->dest_in_node |= (1 << hwdest); + cs->dest_in_node |= (1 << hwdest); if (REG_GET_TYPE(coord) != REG_TYPE_CONST) cs->used_in_node |= (1 << hwsrc); @@ -1038,7 +1038,7 @@ static int get_earliest_allowed_write( case REG_TYPE_TEMP: if (cs->temps[index].reg == -1) return 0; - + idx = cs->temps[index].reg; break; case REG_TYPE_OUTPUT: @@ -1047,7 +1047,7 @@ static int get_earliest_allowed_write( ERROR("invalid dest reg type %d\n", REG_GET_TYPE(dest)); return 0; } - + pos = cs->hwtemps[idx].reserved; if (mask & WRITEMASK_XYZ) { if (pos < cs->hwtemps[idx].vector_lastread) @@ -1057,7 +1057,7 @@ static int get_earliest_allowed_write( if (pos < cs->hwtemps[idx].scalar_lastread) pos = cs->hwtemps[idx].scalar_lastread; } - + return pos; } @@ -1094,7 +1094,7 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, int pos; int regnr; int i,j; - + // Determine instruction slots, whether sources are required on // vector or scalar side, and the smallest slot number where // all source registers are available @@ -1103,9 +1103,9 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, used |= SLOT_OP_VECTOR; if (emit_sop) used |= SLOT_OP_SCALAR; - + pos = get_earliest_allowed_write(rp, dest, mask); - + if (rp->node[rp->cur_node].alu_offset > pos) pos = rp->node[rp->cur_node].alu_offset; for(i = 0; i < argc; ++i) { @@ -1115,10 +1115,10 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, if (emit_sop) used |= s_swiz[REG_GET_SSWZ(src[i])].flags << i; } - + hwsrc[i] = t_hw_src(rp, src[i], GL_FALSE); /* Note: sideeffects wrt refcounting! */ regnr = hwsrc[i] & 31; - + if (REG_GET_TYPE(src[i]) == REG_TYPE_TEMP) { if (used & (SLOT_SRC_VECTOR << i)) { if (cs->hwtemps[regnr].vector_valid > pos) @@ -1130,12 +1130,12 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, } } } - + // Find a slot that fits for(; ; ++pos) { if (cs->slot[pos].used & used & SLOT_OP_BOTH) continue; - + if (pos >= cs->nrslots) { if (cs->nrslots >= PFS_MAX_ALU_INST) { ERROR("Out of ALU instruction slots\n"); @@ -1147,7 +1147,7 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, cs->nrslots++; } - + // Note: When we need both parts (vector and scalar) of a source, // we always try to put them into the same position. This makes the // code easier to read, and it is optimal (i.e. one doesn't gain @@ -1158,32 +1158,32 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, tempvsrc[i] = cs->slot[pos].vsrc[i]; tempssrc[i] = cs->slot[pos].ssrc[i]; } - + for(i = 0; i < argc; ++i) { int flags = (used >> i) & SLOT_SRC_BOTH; - + if (!flags) { srcpos[i] = 0; continue; } - + for(j = 0; j < 3; ++j) { if ((tempused >> j) & flags & SLOT_SRC_VECTOR) { if (tempvsrc[j] != hwsrc[i]) continue; } - + if ((tempused >> j) & flags & SLOT_SRC_SCALAR) { if (tempssrc[j] != hwsrc[i]) continue; } - + break; } - + if (j == 3) break; - + srcpos[i] = j; tempused |= flags << j; if (flags & SLOT_SRC_VECTOR) @@ -1191,22 +1191,22 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, if (flags & SLOT_SRC_SCALAR) tempssrc[j] = hwsrc[i]; } - + if (i == argc) break; } - + // Found a slot, reserve it cs->slot[pos].used = tempused | (used & SLOT_OP_BOTH); for(i = 0; i < 3; ++i) { cs->slot[pos].vsrc[i] = tempvsrc[i]; cs->slot[pos].ssrc[i] = tempssrc[i]; } - + for(i = 0; i < argc; ++i) { if (REG_GET_TYPE(src[i]) == REG_TYPE_TEMP) { int regnr = hwsrc[i] & 31; - + if (used & (SLOT_SRC_VECTOR << i)) { if (cs->hwtemps[regnr].vector_lastread < pos) cs->hwtemps[regnr].vector_lastread = pos; @@ -1217,24 +1217,24 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, } } } - + // Emit the source fetch code rp->alu.inst[pos].inst1 &= ~R300_FPI1_SRC_MASK; rp->alu.inst[pos].inst1 |= ((cs->slot[pos].vsrc[0] << R300_FPI1_SRC0C_SHIFT) | (cs->slot[pos].vsrc[1] << R300_FPI1_SRC1C_SHIFT) | (cs->slot[pos].vsrc[2] << R300_FPI1_SRC2C_SHIFT)); - + rp->alu.inst[pos].inst3 &= ~R300_FPI3_SRC_MASK; rp->alu.inst[pos].inst3 |= ((cs->slot[pos].ssrc[0] << R300_FPI3_SRC0A_SHIFT) | (cs->slot[pos].ssrc[1] << R300_FPI3_SRC1A_SHIFT) | (cs->slot[pos].ssrc[2] << R300_FPI3_SRC2A_SHIFT)); - + // Emit the argument selection code if (emit_vop) { int swz[3]; - + for(i = 0; i < 3; ++i) { if (i < argc) { swz[i] = (v_swiz[REG_GET_VSWZ(src[i])].base + @@ -1245,7 +1245,7 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, swz[i] = R300_FPI0_ARGC_ZERO; } } - + rp->alu.inst[pos].inst0 &= ~(R300_FPI0_ARG0C_MASK|R300_FPI0_ARG1C_MASK|R300_FPI0_ARG2C_MASK); rp->alu.inst[pos].inst0 |= @@ -1253,10 +1253,10 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, (swz[1] << R300_FPI0_ARG1C_SHIFT) | (swz[2] << R300_FPI0_ARG2C_SHIFT); } - + if (emit_sop) { int swz[3]; - + for(i = 0; i < 3; ++i) { if (i < argc) { swz[i] = (s_swiz[REG_GET_SSWZ(src[i])].base + @@ -1267,7 +1267,7 @@ static int find_and_prepare_slot(struct r300_fragment_program* rp, swz[i] = R300_FPI2_ARGA_ZERO; } } - + rp->alu.inst[pos].inst2 &= ~(R300_FPI2_ARG0A_MASK|R300_FPI2_ARG1A_MASK|R300_FPI2_ARG2A_MASK); rp->alu.inst[pos].inst2 |= @@ -1322,9 +1322,9 @@ static void emit_arith(struct r300_fragment_program *rp, pos = find_and_prepare_slot(rp, emit_vop, emit_sop, argc, src, dest, mask); if (pos < 0) return; - + hwdest = t_hw_dst(rp, dest, GL_FALSE, pos); /* Note: Side effects wrt register allocation */ - + if (flags & PFS_FLAG_SAT) { vop |= R300_FPI0_OUTC_SAT; sop |= R300_FPI2_OUTA_SAT; @@ -1335,7 +1335,7 @@ static void emit_arith(struct r300_fragment_program *rp, rp->alu.inst[pos].inst0 |= vop; rp->alu.inst[pos].inst1 |= hwdest << R300_FPI1_DSTC_SHIFT; - + if (REG_GET_TYPE(dest) == REG_TYPE_OUTPUT) { if (REG_GET_INDEX(dest) == FRAG_RESULT_COLR) { rp->alu.inst[pos].inst1 |= @@ -1344,7 +1344,7 @@ static void emit_arith(struct r300_fragment_program *rp, } else { rp->alu.inst[pos].inst1 |= (mask & WRITEMASK_XYZ) << R300_FPI1_DSTC_REG_MASK_SHIFT; - + cs->hwtemps[hwdest].vector_valid = pos+1; } } @@ -1356,7 +1356,7 @@ static void emit_arith(struct r300_fragment_program *rp, if (mask & WRITEMASK_W) { if (REG_GET_TYPE(dest) == REG_TYPE_OUTPUT) { if (REG_GET_INDEX(dest) == FRAG_RESULT_COLR) { - rp->alu.inst[pos].inst3 |= + rp->alu.inst[pos].inst3 |= (hwdest << R300_FPI3_DSTA_SHIFT) | R300_FPI3_DSTA_OUTPUT; } else if (REG_GET_INDEX(dest) == FRAG_RESULT_DEPR) { rp->alu.inst[pos].inst3 |= R300_FPI3_DSTA_DEPTH; @@ -1364,12 +1364,12 @@ static void emit_arith(struct r300_fragment_program *rp, } else { rp->alu.inst[pos].inst3 |= (hwdest << R300_FPI3_DSTA_SHIFT) | R300_FPI3_DSTA_REG; - + cs->hwtemps[hwdest].scalar_valid = pos+1; } } } - + return; } @@ -1443,9 +1443,9 @@ static void emit_lit(struct r300_fragment_program *rp, GLuint cnst; int needTemporary; GLuint temp; - + cnst = emit_const4fv(rp, cnstv); - + needTemporary = 0; if ((mask & WRITEMASK_XYZW) != WRITEMASK_XYZW) { needTemporary = 1; @@ -1454,30 +1454,30 @@ static void emit_lit(struct r300_fragment_program *rp, // in creating special code for this case needTemporary = 1; } - + if (needTemporary) { temp = keep(get_temp_reg(rp)); } else { temp = keep(dest); } - + // Npte: The order of emit_arith inside the slots is relevant, // because emit_arith only looks at scalar vs. vector when resolving // dependencies, and it does not consider individual vector components, // so swizzling between the two parts can create fake dependencies. - + // First slot emit_arith(rp, PFS_OP_MAX, temp, WRITEMASK_XY, keep(src), pfs_zero, undef, 0); emit_arith(rp, PFS_OP_MAX, temp, WRITEMASK_W, src, cnst, undef, 0); - + // Second slot emit_arith(rp, PFS_OP_MIN, temp, WRITEMASK_Z, swizzle(temp, W, W, W, W), cnst, undef, 0); emit_arith(rp, PFS_OP_LG2, temp, WRITEMASK_W, swizzle(temp, Y, Y, Y, Y), undef, undef, 0); - + // Third slot // If desired, we saturate the y result here. // This does not affect the use as a condition variable in the CMP later @@ -1485,19 +1485,19 @@ static void emit_lit(struct r300_fragment_program *rp, temp, swizzle(temp, Z, Z, Z, Z), pfs_zero, 0); emit_arith(rp, PFS_OP_MAD, temp, WRITEMASK_Y, swizzle(temp, X, X, X, X), pfs_one, pfs_zero, flags); - + // Fourth slot emit_arith(rp, PFS_OP_MAD, temp, WRITEMASK_X, pfs_one, pfs_one, pfs_zero, 0); emit_arith(rp, PFS_OP_EX2, temp, WRITEMASK_W, temp, undef, undef, 0); - + // Fifth slot emit_arith(rp, PFS_OP_CMP, temp, WRITEMASK_Z, swizzle(temp, W, W, W, W), pfs_zero, swizzle(temp, Y, Y, Y, Y), flags); emit_arith(rp, PFS_OP_MAD, temp, WRITEMASK_W, pfs_one, pfs_one, pfs_zero, 0); - + if (needTemporary) { emit_arith(rp, PFS_OP_MAD, dest, mask, temp, pfs_one, pfs_zero, flags); @@ -1510,7 +1510,7 @@ static void emit_lit(struct r300_fragment_program *rp, static GLboolean parse_program(struct r300_fragment_program *rp) -{ +{ struct gl_fragment_program *mp = &rp->mesa_program; const struct prog_instruction *inst = mp->Base.Instructions; struct prog_instruction *fpi; @@ -1604,7 +1604,7 @@ static GLboolean parse_program(struct r300_fragment_program *rp) absolute(swizzle(temp[0], Z, Z, Z, Z)), swizzle(temp[0], X, X, X, X), 0); - + emit_arith(rp, PFS_OP_MAD, temp[0], WRITEMASK_Y, swizzle(temp[0], X, X, X, X), absolute(swizzle(temp[0], X, X, X, X)), @@ -1648,12 +1648,12 @@ static GLboolean parse_program(struct r300_fragment_program *rp) 0); emit_arith(rp, PFS_OP_DP4, dest, mask, temp[0], src[1], undef, - flags); + flags); free_temp(rp, temp[0]); #else emit_arith(rp, PFS_OP_DP4, dest, mask, swizzle(src[0], X, Y, Z, ONE), src[1], - undef, flags); + undef, flags); #endif break; case OPCODE_DST: @@ -1684,7 +1684,7 @@ static GLboolean parse_program(struct r300_fragment_program *rp) src[0], undef, undef, flags); break; - case OPCODE_FLR: + case OPCODE_FLR: src[0] = t_src(rp, fpi->SrcReg[0]); temp[0] = get_temp_reg(rp); /* FRC temp, src0 @@ -1734,7 +1734,7 @@ static GLboolean parse_program(struct r300_fragment_program *rp) src[0], src[1], temp[0], flags); free_temp(rp, temp[0]); - break; + break; case OPCODE_MAD: src[0] = t_src(rp, fpi->SrcReg[0]); src[1] = t_src(rp, fpi->SrcReg[1]); @@ -1761,7 +1761,7 @@ static GLboolean parse_program(struct r300_fragment_program *rp) case OPCODE_SWZ: src[0] = t_src(rp, fpi->SrcReg[0]); emit_arith(rp, PFS_OP_MAD, dest, mask, - src[0], pfs_one, pfs_zero, + src[0], pfs_one, pfs_zero, flags); break; case OPCODE_MUL: @@ -1774,7 +1774,7 @@ static GLboolean parse_program(struct r300_fragment_program *rp) case OPCODE_POW: src[0] = t_scalar_src(rp, fpi->SrcReg[0]); src[1] = t_scalar_src(rp, fpi->SrcReg[1]); - temp[0] = get_temp_reg(rp); + temp[0] = get_temp_reg(rp); emit_arith(rp, PFS_OP_LG2, temp[0], WRITEMASK_W, src[0], undef, undef, 0); @@ -1932,7 +1932,7 @@ static GLboolean parse_program(struct r300_fragment_program *rp) absolute(swizzle(temp[0], Z, Z, Z, Z)), swizzle(temp[0], X, X, X, X), 0); - + emit_arith(rp, PFS_OP_MAD, temp[0], WRITEMASK_Y, swizzle(temp[0], X, X, X, X), absolute(swizzle(temp[0], X, X, X, X)), @@ -1989,7 +1989,7 @@ static GLboolean parse_program(struct r300_fragment_program *rp) swizzle(keep(src[1]), Y, Z, X, W), pfs_zero, 0); - /* dest.xyz = src0.yzx * src1.zxy - temp + /* dest.xyz = src0.yzx * src1.zxy - temp * dest.w = undefined * */ emit_arith(rp, PFS_OP_MAD, dest, mask & WRITEMASK_XYZ, @@ -2089,7 +2089,7 @@ static void insert_wpos(struct gl_program *prog) fpi = &prog->Instructions[prog->NumInstructions-1]; assert(fpi->Opcode == OPCODE_END); - + for(fpi = &prog->Instructions[3]; fpi->Opcode != OPCODE_END; fpi++){ for(i=0; i<3; i++) if( fpi->SrcReg[i].File == PROGRAM_INPUT && @@ -2106,7 +2106,7 @@ static void insert_wpos(struct gl_program *prog) static void init_program(r300ContextPtr r300, struct r300_fragment_program *rp) { struct r300_pfs_compile_state *cs = NULL; - struct gl_fragment_program *mp = &rp->mesa_program; + struct gl_fragment_program *mp = &rp->mesa_program; struct prog_instruction *fpi; GLuint InputsRead = mp->Base.InputsRead; GLuint temps_used = 0; /* for rp->temps[] */ @@ -2127,7 +2127,7 @@ static void init_program(r300ContextPtr r300, struct r300_fragment_program *rp) rp->node[0].alu_end = -1; rp->node[0].tex_end = -1; rp->const_sin[0] = -1; - + _mesa_memset(cs, 0, sizeof(*rp->cs)); for (i=0;i<PFS_MAX_ALU_INST;i++) { for (j=0;j<3;j++) { @@ -2135,7 +2135,7 @@ static void init_program(r300ContextPtr r300, struct r300_fragment_program *rp) cs->slot[i].ssrc[j] = SRC_CONST; } } - + /* Work out what temps the Mesa inputs correspond to, this must match * what setup_rs_unit does, which shouldn't be a problem as rs_unit * configures itself based on the fragprog's InputsRead @@ -2167,7 +2167,7 @@ static void init_program(r300ContextPtr r300, struct r300_fragment_program *rp) cs->inputs[FRAG_ATTRIB_COL0].reg = get_hw_temp(rp, 0); } InputsRead &= ~FRAG_BIT_COL0; - + /* Secondary color */ if (InputsRead & FRAG_BIT_COL1) { cs->inputs[FRAG_ATTRIB_COL1].refcount = 0; @@ -2194,7 +2194,7 @@ static void init_program(r300ContextPtr r300, struct r300_fragment_program *rp) for (fpi=mp->Base.Instructions;fpi->Opcode != OPCODE_END; fpi++) { int idx; - + for (i=0;i<3;i++) { idx = fpi->SrcReg[i].Index; switch (fpi->SrcReg[i].File) { @@ -2246,7 +2246,7 @@ void r300_translate_fragment_shader(r300ContextPtr r300, struct r300_fragment_pr struct r300_pfs_compile_state *cs = NULL; if (!rp->translated) { - + init_program(r300, rp); cs = rp->cs; @@ -2254,7 +2254,7 @@ void r300_translate_fragment_shader(r300ContextPtr r300, struct r300_fragment_pr dump_program(rp); return; } - + /* Finish off */ rp->node[rp->cur_node].alu_end = cs->nrslots - rp->node[rp->cur_node].alu_offset - 1; @@ -2266,9 +2266,9 @@ void r300_translate_fragment_shader(r300ContextPtr r300, struct r300_fragment_pr rp->tex_end = rp->tex.length ? rp->tex.length - 1 : 0; assert(rp->node[rp->cur_node].alu_end >= 0); assert(rp->alu_end >= 0); - + rp->translated = GL_TRUE; - if (0) dump_program(rp); + if (1) dump_program(rp); r300UpdateStateParameters(rp->ctx, _NEW_PROGRAM); } @@ -2282,7 +2282,7 @@ static void dump_program(struct r300_fragment_program *rp) static int pc = 0; fprintf(stderr, "pc=%d*************************************\n", pc++); - + fprintf(stderr, "Mesa program:\n"); fprintf(stderr, "-------------\n"); _mesa_print_program(&rp->mesa_program.Base); @@ -2290,7 +2290,7 @@ static void dump_program(struct r300_fragment_program *rp) fprintf(stderr, "Hardware program\n"); fprintf(stderr, "----------------\n"); - + for (n = 0; n < (rp->cur_node+1); n++) { fprintf(stderr, "NODE %d: alu_offset: %d, tex_offset: %d, "\ "alu_end: %d, tex_end: %d\n", n, @@ -2298,12 +2298,12 @@ static void dump_program(struct r300_fragment_program *rp) rp->node[n].tex_offset, rp->node[n].alu_end, rp->node[n].tex_end); - + if (rp->tex.length) { fprintf(stderr, " TEX:\n"); for(i = rp->node[n].tex_offset; i <= rp->node[n].tex_offset+rp->node[n].tex_end; ++i) { const char* instr; - + switch((rp->tex.inst[i] >> R300_FPITX_OPCODE_SHIFT) & 15) { case R300_FPITX_OP_TEX: instr = "TEX"; @@ -2320,7 +2320,7 @@ static void dump_program(struct r300_fragment_program *rp) default: instr = "UNKNOWN"; } - + fprintf(stderr, " %s t%i, %c%i, texture[%i] (%08x)\n", instr, (rp->tex.inst[i] >> R300_FPITX_DST_SHIFT) & 31, @@ -2330,22 +2330,22 @@ static void dump_program(struct r300_fragment_program *rp) rp->tex.inst[i]); } } - + for(i = rp->node[n].alu_offset; i <= rp->node[n].alu_offset+rp->node[n].alu_end; ++i) { char srcc[3][10], dstc[20]; char srca[3][10], dsta[20]; char argc[3][20]; char arga[3][20]; char flags[5], tmp[10]; - + for(j = 0; j < 3; ++j) { int regc = rp->alu.inst[i].inst1 >> (j*6); int rega = rp->alu.inst[i].inst3 >> (j*6); - + sprintf(srcc[j], "%c%i", (regc & 32) ? 'c' : 't', regc & 31); sprintf(srca[j], "%c%i", (rega & 32) ? 'c' : 't', rega & 31); } - + dstc[0] = 0; sprintf(flags, "%s%s%s", (rp->alu.inst[i].inst1 & R300_FPI1_DSTC_REG_X) ? "x" : "", @@ -2366,7 +2366,7 @@ static void dump_program(struct r300_fragment_program *rp) flags); strcat(dstc, tmp); } - + dsta[0] = 0; if (rp->alu.inst[i].inst3 & R300_FPI3_DSTA_REG) { sprintf(dsta, "t%i.w ", (rp->alu.inst[i].inst3 >> R300_FPI3_DSTA_SHIFT) & 31); @@ -2378,13 +2378,13 @@ static void dump_program(struct r300_fragment_program *rp) if (rp->alu.inst[i].inst3 & R300_FPI3_DSTA_DEPTH) { strcat(dsta, "Z"); } - + fprintf(stderr, "%3i: xyz: %3s %3s %3s -> %-20s (%08x)\n" " w: %3s %3s %3s -> %-20s (%08x)\n", i, srcc[0], srcc[1], srcc[2], dstc, rp->alu.inst[i].inst1, srca[0], srca[1], srca[2], dsta, rp->alu.inst[i].inst3); - + for(j = 0; j < 3; ++j) { int regc = rp->alu.inst[i].inst0 >> (j*7); int rega = rp->alu.inst[i].inst2 >> (j*7); @@ -2431,13 +2431,13 @@ static void dump_program(struct r300_fragment_program *rp) } else { sprintf(buf, "%i", d); } - + sprintf(argc[j], "%s%s%s%s", (regc & 32) ? "-" : "", (regc & 64) ? "|" : "", buf, (regc & 64) ? "|" : ""); - + d = rega & 31; if (d < 9) { sprintf(buf, "%s.%c", srcc[d / 3], 'x' + (char)(d%3)); @@ -2452,14 +2452,14 @@ static void dump_program(struct r300_fragment_program *rp) } else { sprintf(buf, "%i", d); } - + sprintf(arga[j], "%s%s%s%s", (rega & 32) ? "-" : "", (rega & 64) ? "|" : "", buf, (rega & 64) ? "|" : ""); } - + fprintf(stderr, " xyz: %8s %8s %8s op: %08x\n" " w: %8s %8s %8s op: %08x\n", argc[0], argc[1], argc[2], rp->alu.inst[i].inst0, |