aboutsummaryrefslogtreecommitdiffstats
path: root/src/mesa/drivers/dri/r300
diff options
context:
space:
mode:
Diffstat (limited to 'src/mesa/drivers/dri/r300')
-rw-r--r--src/mesa/drivers/dri/r300/Makefile1
-rw-r--r--src/mesa/drivers/dri/r300/r500_fragprog.c2476
-rw-r--r--src/mesa/drivers/dri/r300/r500_fragprog.h104
3 files changed, 2581 insertions, 0 deletions
diff --git a/src/mesa/drivers/dri/r300/Makefile b/src/mesa/drivers/dri/r300/Makefile
index 44248964fdb..5b2bd0bc2b0 100644
--- a/src/mesa/drivers/dri/r300/Makefile
+++ b/src/mesa/drivers/dri/r300/Makefile
@@ -39,6 +39,7 @@ DRIVER_SOURCES = \
r300_texstate.c \
r300_vertprog.c \
r300_fragprog.c \
+ r500_fragprog.c \
r300_shader.c \
r300_emit.c \
r300_swtcl.c \
diff --git a/src/mesa/drivers/dri/r300/r500_fragprog.c b/src/mesa/drivers/dri/r300/r500_fragprog.c
new file mode 100644
index 00000000000..3638a943802
--- /dev/null
+++ b/src/mesa/drivers/dri/r300/r500_fragprog.c
@@ -0,0 +1,2476 @@
+/*
+ * Copyright (C) 2005 Ben Skeggs.
+ *
+ * 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 (including the
+ * next paragraph) 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 COPYRIGHT OWNER(S) AND/OR ITS SUPPLIERS 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.
+ *
+ */
+
+/**
+ * \file
+ *
+ * \author Ben Skeggs <[email protected]>
+ *
+ * \author Jerome Glisse <[email protected]>
+ *
+ * \todo Depth write, WPOS/FOGC inputs
+ *
+ * \todo FogOption
+ *
+ * \todo Verify results of opcodes for accuracy, I've only checked them in
+ * specific cases.
+ */
+
+#include "glheader.h"
+#include "macros.h"
+#include "enums.h"
+#include "shader/prog_instruction.h"
+#include "shader/prog_parameter.h"
+#include "shader/prog_print.h"
+
+#include "r300_context.h"
+#include "r300_fragprog.h"
+#include "r300_reg.h"
+#include "r300_state.h"
+
+/*
+ * Usefull macros and values
+ */
+#define ERROR(fmt, args...) do { \
+ fprintf(stderr, "%s::%s(): " fmt "\n", \
+ __FILE__, __FUNCTION__, ##args); \
+ fp->error = GL_TRUE; \
+ } while(0)
+
+#define PFS_INVAL 0xFFFFFFFF
+#define COMPILE_STATE struct r300_pfs_compile_state *cs = fp->cs
+
+#define SWIZZLE_XYZ 0
+#define SWIZZLE_XXX 1
+#define SWIZZLE_YYY 2
+#define SWIZZLE_ZZZ 3
+#define SWIZZLE_WWW 4
+#define SWIZZLE_YZX 5
+#define SWIZZLE_ZXY 6
+#define SWIZZLE_WZY 7
+#define SWIZZLE_111 8
+#define SWIZZLE_000 9
+#define SWIZZLE_HHH 10
+
+#define swizzle(r, x, y, z, w) do_swizzle(fp, r, \
+ ((SWIZZLE_##x<<0)| \
+ (SWIZZLE_##y<<3)| \
+ (SWIZZLE_##z<<6)| \
+ (SWIZZLE_##w<<9)), \
+ 0)
+
+#define REG_TYPE_INPUT 0
+#define REG_TYPE_OUTPUT 1
+#define REG_TYPE_TEMP 2
+#define REG_TYPE_CONST 3
+
+#define REG_TYPE_SHIFT 0
+#define REG_INDEX_SHIFT 2
+#define REG_VSWZ_SHIFT 8
+#define REG_SSWZ_SHIFT 13
+#define REG_NEGV_SHIFT 18
+#define REG_NEGS_SHIFT 19
+#define REG_ABS_SHIFT 20
+#define REG_NO_USE_SHIFT 21 // Hack for refcounting
+#define REG_VALID_SHIFT 22 // Does the register contain a defined value?
+#define REG_BUILTIN_SHIFT 23 // Is it a builtin (like all zero/all one)?
+
+#define REG_TYPE_MASK (0x03 << REG_TYPE_SHIFT)
+#define REG_INDEX_MASK (0x3F << REG_INDEX_SHIFT)
+#define REG_VSWZ_MASK (0x1F << REG_VSWZ_SHIFT)
+#define REG_SSWZ_MASK (0x1F << REG_SSWZ_SHIFT)
+#define REG_NEGV_MASK (0x01 << REG_NEGV_SHIFT)
+#define REG_NEGS_MASK (0x01 << REG_NEGS_SHIFT)
+#define REG_ABS_MASK (0x01 << REG_ABS_SHIFT)
+#define REG_NO_USE_MASK (0x01 << REG_NO_USE_SHIFT)
+#define REG_VALID_MASK (0x01 << REG_VALID_SHIFT)
+#define REG_BUILTIN_MASK (0x01 << REG_BUILTIN_SHIFT)
+
+#define REG(type, index, vswz, sswz, nouse, valid, builtin) \
+ (((type << REG_TYPE_SHIFT) & REG_TYPE_MASK) | \
+ ((index << REG_INDEX_SHIFT) & REG_INDEX_MASK) | \
+ ((nouse << REG_NO_USE_SHIFT) & REG_NO_USE_MASK) | \
+ ((valid << REG_VALID_SHIFT) & REG_VALID_MASK) | \
+ ((builtin << REG_BUILTIN_SHIFT) & REG_BUILTIN_MASK) | \
+ ((vswz << REG_VSWZ_SHIFT) & REG_VSWZ_MASK) | \
+ ((sswz << REG_SSWZ_SHIFT) & REG_SSWZ_MASK))
+#define REG_GET_TYPE(reg) \
+ ((reg & REG_TYPE_MASK) >> REG_TYPE_SHIFT)
+#define REG_GET_INDEX(reg) \
+ ((reg & REG_INDEX_MASK) >> REG_INDEX_SHIFT)
+#define REG_GET_VSWZ(reg) \
+ ((reg & REG_VSWZ_MASK) >> REG_VSWZ_SHIFT)
+#define REG_GET_SSWZ(reg) \
+ ((reg & REG_SSWZ_MASK) >> REG_SSWZ_SHIFT)
+#define REG_GET_NO_USE(reg) \
+ ((reg & REG_NO_USE_MASK) >> REG_NO_USE_SHIFT)
+#define REG_GET_VALID(reg) \
+ ((reg & REG_VALID_MASK) >> REG_VALID_SHIFT)
+#define REG_GET_BUILTIN(reg) \
+ ((reg & REG_BUILTIN_MASK) >> REG_BUILTIN_SHIFT)
+#define REG_SET_TYPE(reg, type) \
+ reg = ((reg & ~REG_TYPE_MASK) | \
+ ((type << REG_TYPE_SHIFT) & REG_TYPE_MASK))
+#define REG_SET_INDEX(reg, index) \
+ reg = ((reg & ~REG_INDEX_MASK) | \
+ ((index << REG_INDEX_SHIFT) & REG_INDEX_MASK))
+#define REG_SET_VSWZ(reg, vswz) \
+ reg = ((reg & ~REG_VSWZ_MASK) | \
+ ((vswz << REG_VSWZ_SHIFT) & REG_VSWZ_MASK))
+#define REG_SET_SSWZ(reg, sswz) \
+ reg = ((reg & ~REG_SSWZ_MASK) | \
+ ((sswz << REG_SSWZ_SHIFT) & REG_SSWZ_MASK))
+#define REG_SET_NO_USE(reg, nouse) \
+ reg = ((reg & ~REG_NO_USE_MASK) | \
+ ((nouse << REG_NO_USE_SHIFT) & REG_NO_USE_MASK))
+#define REG_SET_VALID(reg, valid) \
+ reg = ((reg & ~REG_VALID_MASK) | \
+ ((valid << REG_VALID_SHIFT) & REG_VALID_MASK))
+#define REG_SET_BUILTIN(reg, builtin) \
+ reg = ((reg & ~REG_BUILTIN_MASK) | \
+ ((builtin << REG_BUILTIN_SHIFT) & REG_BUILTIN_MASK))
+#define REG_ABS(reg) \
+ reg = (reg | REG_ABS_MASK)
+#define REG_NEGV(reg) \
+ reg = (reg | REG_NEGV_MASK)
+#define REG_NEGS(reg) \
+ reg = (reg | REG_NEGS_MASK)
+
+/*
+ * Datas structures for fragment program generation
+ */
+
+/* description of r300 native hw instructions */
+static const struct {
+ const char *name;
+ int argc;
+ int v_op;
+ int s_op;
+} r300_fpop[] = {
+ /* *INDENT-OFF* */
+ {"MAD", 3, R300_FPI0_OUTC_MAD, R300_FPI2_OUTA_MAD},
+ {"DP3", 2, R300_FPI0_OUTC_DP3, R300_FPI2_OUTA_DP4},
+ {"DP4", 2, R300_FPI0_OUTC_DP4, R300_FPI2_OUTA_DP4},
+ {"MIN", 2, R300_FPI0_OUTC_MIN, R300_FPI2_OUTA_MIN},
+ {"MAX", 2, R300_FPI0_OUTC_MAX, R300_FPI2_OUTA_MAX},
+ {"CMP", 3, R300_FPI0_OUTC_CMP, R300_FPI2_OUTA_CMP},
+ {"FRC", 1, R300_FPI0_OUTC_FRC, R300_FPI2_OUTA_FRC},
+ {"EX2", 1, R300_FPI0_OUTC_REPL_ALPHA, R300_FPI2_OUTA_EX2},
+ {"LG2", 1, R300_FPI0_OUTC_REPL_ALPHA, R300_FPI2_OUTA_LG2},
+ {"RCP", 1, R300_FPI0_OUTC_REPL_ALPHA, R300_FPI2_OUTA_RCP},
+ {"RSQ", 1, R300_FPI0_OUTC_REPL_ALPHA, R300_FPI2_OUTA_RSQ},
+ {"REPL_ALPHA", 1, R300_FPI0_OUTC_REPL_ALPHA, PFS_INVAL},
+ {"CMPH", 3, R300_FPI0_OUTC_CMPH, PFS_INVAL},
+ /* *INDENT-ON* */
+};
+
+/* vector swizzles r300 can support natively, with a couple of
+ * cases we handle specially
+ *
+ * REG_VSWZ/REG_SSWZ is an index into this table
+ */
+
+/* mapping from SWIZZLE_* to r300 native values for scalar insns */
+#define SWIZZLE_HALF 6
+
+#define MAKE_SWZ3(x, y, z) (MAKE_SWIZZLE4(SWIZZLE_##x, \
+ SWIZZLE_##y, \
+ SWIZZLE_##z, \
+ SWIZZLE_ZERO))
+/* native swizzles */
+static const struct r300_pfs_swizzle {
+ GLuint hash; /* swizzle value this matches */
+ GLuint base; /* base value for hw swizzle */
+ GLuint stride; /* difference in base between arg0/1/2 */
+ GLuint flags;
+} v_swiz[] = {
+ /* *INDENT-OFF* */
+ {MAKE_SWZ3(X, Y, Z), R300_FPI0_ARGC_SRC0C_XYZ, 4, SLOT_SRC_VECTOR},
+ {MAKE_SWZ3(X, X, X), R300_FPI0_ARGC_SRC0C_XXX, 4, SLOT_SRC_VECTOR},
+ {MAKE_SWZ3(Y, Y, Y), R300_FPI0_ARGC_SRC0C_YYY, 4, SLOT_SRC_VECTOR},
+ {MAKE_SWZ3(Z, Z, Z), R300_FPI0_ARGC_SRC0C_ZZZ, 4, SLOT_SRC_VECTOR},
+ {MAKE_SWZ3(W, W, W), R300_FPI0_ARGC_SRC0A, 1, SLOT_SRC_SCALAR},
+ {MAKE_SWZ3(Y, Z, X), R300_FPI0_ARGC_SRC0C_YZX, 1, SLOT_SRC_VECTOR},
+ {MAKE_SWZ3(Z, X, Y), R300_FPI0_ARGC_SRC0C_ZXY, 1, SLOT_SRC_VECTOR},
+ {MAKE_SWZ3(W, Z, Y), R300_FPI0_ARGC_SRC0CA_WZY, 1, SLOT_SRC_BOTH},
+ {MAKE_SWZ3(ONE, ONE, ONE), R300_FPI0_ARGC_ONE, 0, 0},
+ {MAKE_SWZ3(ZERO, ZERO, ZERO), R300_FPI0_ARGC_ZERO, 0, 0},
+ {MAKE_SWZ3(HALF, HALF, HALF), R300_FPI0_ARGC_HALF, 0, 0},
+ {PFS_INVAL, 0, 0, 0},
+ /* *INDENT-ON* */
+};
+
+/* used during matching of non-native swizzles */
+#define SWZ_X_MASK (7 << 0)
+#define SWZ_Y_MASK (7 << 3)
+#define SWZ_Z_MASK (7 << 6)
+#define SWZ_W_MASK (7 << 9)
+static const struct {
+ GLuint hash; /* used to mask matching swizzle components */
+ int mask; /* actual outmask */
+ int count; /* count of components matched */
+} s_mask[] = {
+ /* *INDENT-OFF* */
+ {SWZ_X_MASK | SWZ_Y_MASK | SWZ_Z_MASK, 1 | 2 | 4, 3},
+ {SWZ_X_MASK | SWZ_Y_MASK, 1 | 2, 2},
+ {SWZ_X_MASK | SWZ_Z_MASK, 1 | 4, 2},
+ {SWZ_Y_MASK | SWZ_Z_MASK, 2 | 4, 2},
+ {SWZ_X_MASK, 1, 1},
+ {SWZ_Y_MASK, 2, 1},
+ {SWZ_Z_MASK, 4, 1},
+ {PFS_INVAL, PFS_INVAL, PFS_INVAL}
+ /* *INDENT-ON* */
+};
+
+static const struct {
+ int base; /* hw value of swizzle */
+ int stride; /* difference between SRC0/1/2 */
+ GLuint flags;
+} s_swiz[] = {
+ /* *INDENT-OFF* */
+ {R300_FPI2_ARGA_SRC0C_X, 3, SLOT_SRC_VECTOR},
+ {R300_FPI2_ARGA_SRC0C_Y, 3, SLOT_SRC_VECTOR},
+ {R300_FPI2_ARGA_SRC0C_Z, 3, SLOT_SRC_VECTOR},
+ {R300_FPI2_ARGA_SRC0A, 1, SLOT_SRC_SCALAR},
+ {R300_FPI2_ARGA_ZERO, 0, 0},
+ {R300_FPI2_ARGA_ONE, 0, 0},
+ {R300_FPI2_ARGA_HALF, 0, 0}
+ /* *INDENT-ON* */
+};
+
+/* boiler-plate reg, for convenience */
+static const GLuint undef = REG(REG_TYPE_TEMP,
+ 0,
+ SWIZZLE_XYZ,
+ SWIZZLE_W,
+ GL_FALSE,
+ GL_FALSE,
+ GL_FALSE);
+
+/* constant one source */
+static const GLuint pfs_one = REG(REG_TYPE_CONST,
+ 0,
+ SWIZZLE_111,
+ SWIZZLE_ONE,
+ GL_FALSE,
+ GL_TRUE,
+ GL_TRUE);
+
+/* constant half source */
+static const GLuint pfs_half = REG(REG_TYPE_CONST,
+ 0,
+ SWIZZLE_HHH,
+ SWIZZLE_HALF,
+ GL_FALSE,
+ GL_TRUE,
+ GL_TRUE);
+
+/* constant zero source */
+static const GLuint pfs_zero = REG(REG_TYPE_CONST,
+ 0,
+ SWIZZLE_000,
+ SWIZZLE_ZERO,
+ GL_FALSE,
+ GL_TRUE,
+ GL_TRUE);
+
+/*
+ * Common functions prototypes
+ */
+static void dump_program(struct r300_fragment_program *fp);
+static void emit_arith(struct r300_fragment_program *fp, int op,
+ GLuint dest, int mask,
+ GLuint src0, GLuint src1, GLuint src2, int flags);
+
+/**
+ * Get an R300 temporary that can be written to in the given slot.
+ */
+static int get_hw_temp(struct r300_fragment_program *fp, 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
+ // Then scalar ops on Mesa temporary Z are emitted and move back in time
+ // to overwrite the value of temporary Y.
+ // 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 > fp->max_temp_idx)
+ fp->max_temp_idx = r;
+
+ return r;
+}
+
+/**
+ * Get an R300 temporary that will act as a TEX destination register.
+ */
+static int get_hw_temp_tex(struct r300_fragment_program *fp)
+{
+ COMPILE_STATE;
+ int r;
+
+ 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(fp, 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 > fp->max_temp_idx)
+ fp->max_temp_idx = r;
+
+ return r;
+}
+
+/**
+ * Mark the given hardware register as free.
+ */
+static void free_hw_temp(struct r300_fragment_program *fp, int idx)
+{
+ COMPILE_STATE;
+
+ // Be very careful here. Consider sequences like
+ // MAD r0, r1,r2,r3
+ // TEX r4, ...
+ // The TEX instruction may be moved in front of the MAD instruction
+ // due to the way nodes work. We don't want to alias r1 and r4 in
+ // this case.
+ // I'm certain the register allocation could be further sanitized,
+ // but it's tricky because of stuff that can happen inside emit_tex
+ // and emit_arith.
+ cs->hwtemps[idx].free = cs->nrslots + 1;
+}
+
+/**
+ * Create a new Mesa temporary register.
+ */
+static GLuint get_temp_reg(struct r300_fragment_program *fp)
+{
+ COMPILE_STATE;
+ GLuint r = undef;
+ GLuint index;
+
+ index = ffs(~cs->temp_in_use);
+ if (!index) {
+ ERROR("Out of program temps\n");
+ return r;
+ }
+
+ cs->temp_in_use |= (1 << --index);
+ cs->temps[index].refcount = 0xFFFFFFFF;
+ cs->temps[index].reg = -1;
+
+ REG_SET_TYPE(r, REG_TYPE_TEMP);
+ REG_SET_INDEX(r, index);
+ REG_SET_VALID(r, GL_TRUE);
+ return r;
+}
+
+/**
+ * Create a new Mesa temporary register that will act as the destination
+ * register for a texture read.
+ */
+static GLuint get_temp_reg_tex(struct r300_fragment_program *fp)
+{
+ COMPILE_STATE;
+ GLuint r = undef;
+ GLuint index;
+
+ index = ffs(~cs->temp_in_use);
+ if (!index) {
+ ERROR("Out of program temps\n");
+ return r;
+ }
+
+ cs->temp_in_use |= (1 << --index);
+ cs->temps[index].refcount = 0xFFFFFFFF;
+ cs->temps[index].reg = get_hw_temp_tex(fp);
+
+ REG_SET_TYPE(r, REG_TYPE_TEMP);
+ REG_SET_INDEX(r, index);
+ REG_SET_VALID(r, GL_TRUE);
+ return r;
+}
+
+/**
+ * Free a Mesa temporary and the associated R300 temporary.
+ */
+static void free_temp(struct r300_fragment_program *fp, GLuint r)
+{
+ COMPILE_STATE;
+ GLuint index = REG_GET_INDEX(r);
+
+ if (!(cs->temp_in_use & (1 << index)))
+ return;
+
+ if (REG_GET_TYPE(r) == REG_TYPE_TEMP) {
+ free_hw_temp(fp, cs->temps[index].reg);
+ cs->temps[index].reg = -1;
+ cs->temp_in_use &= ~(1 << index);
+ } else if (REG_GET_TYPE(r) == REG_TYPE_INPUT) {
+ free_hw_temp(fp, cs->inputs[index].reg);
+ cs->inputs[index].reg = -1;
+ }
+}
+
+/**
+ * Emit a hardware constant/parameter.
+ *
+ * \p cp Stable pointer to an array of 4 floats.
+ * The pointer must be stable in the sense that it remains to be valid
+ * and hold the contents of the constant/parameter throughout the lifetime
+ * of the fragment program (actually, up until the next time the fragment
+ * program is translated).
+ */
+static GLuint emit_const4fv(struct r300_fragment_program *fp,
+ const GLfloat * cp)
+{
+ GLuint reg = undef;
+ int index;
+
+ for (index = 0; index < fp->const_nr; ++index) {
+ if (fp->constant[index] == cp)
+ break;
+ }
+
+ if (index >= fp->const_nr) {
+ if (index >= PFS_NUM_CONST_REGS) {
+ ERROR("Out of hw constants!\n");
+ return reg;
+ }
+
+ fp->const_nr++;
+ fp->constant[index] = cp;
+ }
+
+ REG_SET_TYPE(reg, REG_TYPE_CONST);
+ REG_SET_INDEX(reg, index);
+ REG_SET_VALID(reg, GL_TRUE);
+ return reg;
+}
+
+static inline GLuint negate(GLuint r)
+{
+ REG_NEGS(r);
+ REG_NEGV(r);
+ return r;
+}
+
+/* Hack, to prevent clobbering sources used multiple times when
+ * emulating non-native instructions
+ */
+static inline GLuint keep(GLuint r)
+{
+ REG_SET_NO_USE(r, GL_TRUE);
+ return r;
+}
+
+static inline GLuint absolute(GLuint r)
+{
+ REG_ABS(r);
+ return r;
+}
+
+static int swz_native(struct r300_fragment_program *fp,
+ GLuint src, GLuint * r, GLuint arbneg)
+{
+ /* Native swizzle, handle negation */
+ src = (src & ~REG_NEGS_MASK) | (((arbneg >> 3) & 1) << REG_NEGS_SHIFT);
+
+ if ((arbneg & 0x7) == 0x0) {
+ src = src & ~REG_NEGV_MASK;
+ *r = src;
+ } else if ((arbneg & 0x7) == 0x7) {
+ src |= REG_NEGV_MASK;
+ *r = src;
+ } else {
+ if (!REG_GET_VALID(*r))
+ *r = get_temp_reg(fp);
+ src |= REG_NEGV_MASK;
+ emit_arith(fp,
+ PFS_OP_MAD,
+ *r, arbneg & 0x7, keep(src), pfs_one, pfs_zero, 0);
+ src = src & ~REG_NEGV_MASK;
+ emit_arith(fp,
+ PFS_OP_MAD,
+ *r,
+ (arbneg ^ 0x7) | WRITEMASK_W,
+ src, pfs_one, pfs_zero, 0);
+ }
+
+ return 3;
+}
+
+static int swz_emit_partial(struct r300_fragment_program *fp,
+ GLuint src,
+ GLuint * r, int mask, int mc, GLuint arbneg)
+{
+ GLuint tmp;
+ GLuint wmask = 0;
+
+ if (!REG_GET_VALID(*r))
+ *r = get_temp_reg(fp);
+
+ /* A partial match, VSWZ/mask define what parts of the
+ * desired swizzle we match
+ */
+ if (mc + s_mask[mask].count == 3) {
+ wmask = WRITEMASK_W;
+ src |= ((arbneg >> 3) & 1) << REG_NEGS_SHIFT;
+ }
+
+ tmp = arbneg & s_mask[mask].mask;
+ if (tmp) {
+ tmp = tmp ^ s_mask[mask].mask;
+ if (tmp) {
+ emit_arith(fp,
+ PFS_OP_MAD,
+ *r,
+ arbneg & s_mask[mask].mask,
+ keep(src) | REG_NEGV_MASK,
+ pfs_one, pfs_zero, 0);
+ if (!wmask) {
+ REG_SET_NO_USE(src, GL_TRUE);
+ } else {
+ REG_SET_NO_USE(src, GL_FALSE);
+ }
+ emit_arith(fp,
+ PFS_OP_MAD,
+ *r, tmp | wmask, src, pfs_one, pfs_zero, 0);
+ } else {
+ if (!wmask) {
+ REG_SET_NO_USE(src, GL_TRUE);
+ } else {
+ REG_SET_NO_USE(src, GL_FALSE);
+ }
+ emit_arith(fp,
+ PFS_OP_MAD,
+ *r,
+ (arbneg & s_mask[mask].mask) | wmask,
+ src | REG_NEGV_MASK, pfs_one, pfs_zero, 0);
+ }
+ } else {
+ if (!wmask) {
+ REG_SET_NO_USE(src, GL_TRUE);
+ } else {
+ REG_SET_NO_USE(src, GL_FALSE);
+ }
+ emit_arith(fp, PFS_OP_MAD,
+ *r,
+ s_mask[mask].mask | wmask,
+ src, pfs_one, pfs_zero, 0);
+ }
+
+ return s_mask[mask].count;
+}
+
+static GLuint do_swizzle(struct r300_fragment_program *fp,
+ GLuint src, GLuint arbswz, GLuint arbneg)
+{
+ GLuint r = undef;
+ GLuint vswz;
+ int c_mask = 0;
+ int v_match = 0;
+
+ /* If swizzling from something without an XYZW native swizzle,
+ * emit result to a temp, and do new swizzle from the temp.
+ */
+#if 0
+ if (REG_GET_VSWZ(src) != SWIZZLE_XYZ || REG_GET_SSWZ(src) != SWIZZLE_W) {
+ GLuint temp = get_temp_reg(fp);
+ emit_arith(fp,
+ PFS_OP_MAD,
+ temp, WRITEMASK_XYZW, src, pfs_one, pfs_zero, 0);
+ src = temp;
+ }
+#endif
+
+ if (REG_GET_VSWZ(src) != SWIZZLE_XYZ || REG_GET_SSWZ(src) != SWIZZLE_W) {
+ GLuint vsrcswz =
+ (v_swiz[REG_GET_VSWZ(src)].
+ hash & (SWZ_X_MASK | SWZ_Y_MASK | SWZ_Z_MASK)) |
+ REG_GET_SSWZ(src) << 9;
+ GLint i;
+
+ GLuint newswz = 0;
+ 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;
+ }
+
+ arbswz = newswz & (SWZ_X_MASK | SWZ_Y_MASK | SWZ_Z_MASK);
+ REG_SET_SSWZ(src, GET_SWZ(newswz, 3));
+ } else {
+ /* set scalar swizzling */
+ REG_SET_SSWZ(src, GET_SWZ(arbswz, 3));
+
+ }
+ do {
+ vswz = REG_GET_VSWZ(src);
+ do {
+ int chash;
+
+ REG_SET_VSWZ(src, vswz);
+ chash = v_swiz[REG_GET_VSWZ(src)].hash &
+ s_mask[c_mask].hash;
+
+ if (chash == (arbswz & s_mask[c_mask].hash)) {
+ if (s_mask[c_mask].count == 3) {
+ v_match += swz_native(fp,
+ src, &r, arbneg);
+ } else {
+ v_match += swz_emit_partial(fp,
+ src,
+ &r,
+ c_mask,
+ v_match,
+ arbneg);
+ }
+
+ if (v_match == 3)
+ return r;
+
+ /* Fill with something invalid.. all 0's was
+ * wrong before, matched SWIZZLE_X. So all
+ * 1's will be okay for now
+ */
+ arbswz |= (PFS_INVAL & s_mask[c_mask].hash);
+ }
+ } while (v_swiz[++vswz].hash != PFS_INVAL);
+ REG_SET_VSWZ(src, SWIZZLE_XYZ);
+ } while (s_mask[++c_mask].hash != PFS_INVAL);
+
+ ERROR("should NEVER get here\n");
+ return r;
+}
+
+static GLuint t_src(struct r300_fragment_program *fp,
+ struct prog_src_register fpsrc)
+{
+ GLuint r = undef;
+
+ switch (fpsrc.File) {
+ case PROGRAM_TEMPORARY:
+ REG_SET_INDEX(r, fpsrc.Index);
+ REG_SET_VALID(r, GL_TRUE);
+ REG_SET_TYPE(r, REG_TYPE_TEMP);
+ break;
+ case PROGRAM_INPUT:
+ REG_SET_INDEX(r, fpsrc.Index);
+ REG_SET_VALID(r, GL_TRUE);
+ REG_SET_TYPE(r, REG_TYPE_INPUT);
+ break;
+ case PROGRAM_LOCAL_PARAM:
+ r = emit_const4fv(fp,
+ fp->mesa_program.Base.LocalParams[fpsrc.
+ Index]);
+ break;
+ case PROGRAM_ENV_PARAM:
+ r = emit_const4fv(fp,
+ fp->ctx->FragmentProgram.Parameters[fpsrc.
+ Index]);
+ break;
+ case PROGRAM_STATE_VAR:
+ case PROGRAM_NAMED_PARAM:
+ r = emit_const4fv(fp,
+ fp->mesa_program.Base.Parameters->
+ ParameterValues[fpsrc.Index]);
+ break;
+ default:
+ ERROR("unknown SrcReg->File %x\n", fpsrc.File);
+ return r;
+ }
+
+ /* no point swizzling ONE/ZERO/HALF constants... */
+ if (REG_GET_VSWZ(r) < SWIZZLE_111 || REG_GET_SSWZ(r) < SWIZZLE_ZERO)
+ r = do_swizzle(fp, r, fpsrc.Swizzle, fpsrc.NegateBase);
+ return r;
+}
+
+static GLuint t_scalar_src(struct r300_fragment_program *fp,
+ struct prog_src_register fpsrc)
+{
+ struct prog_src_register src = fpsrc;
+ int sc = GET_SWZ(fpsrc.Swizzle, 0); /* X */
+
+ src.Swizzle = ((sc << 0) | (sc << 3) | (sc << 6) | (sc << 9));
+
+ return t_src(fp, src);
+}
+
+static GLuint t_dst(struct r300_fragment_program *fp,
+ struct prog_dst_register dest)
+{
+ GLuint r = undef;
+
+ switch (dest.File) {
+ case PROGRAM_TEMPORARY:
+ REG_SET_INDEX(r, dest.Index);
+ REG_SET_VALID(r, GL_TRUE);
+ REG_SET_TYPE(r, REG_TYPE_TEMP);
+ return r;
+ case PROGRAM_OUTPUT:
+ REG_SET_TYPE(r, REG_TYPE_OUTPUT);
+ switch (dest.Index) {
+ case FRAG_RESULT_COLR:
+ case FRAG_RESULT_DEPR:
+ REG_SET_INDEX(r, dest.Index);
+ REG_SET_VALID(r, GL_TRUE);
+ return r;
+ default:
+ ERROR("Bad DstReg->Index 0x%x\n", dest.Index);
+ return r;
+ }
+ default:
+ ERROR("Bad DstReg->File 0x%x\n", dest.File);
+ return r;
+ }
+}
+
+static int t_hw_src(struct r300_fragment_program *fp, GLuint src, GLboolean tex)
+{
+ COMPILE_STATE;
+ int idx;
+ int index = REG_GET_INDEX(src);
+
+ switch (REG_GET_TYPE(src)) {
+ case REG_TYPE_TEMP:
+ /* NOTE: if reg==-1 here, a source is being read that
+ * hasn't been written to. Undefined results.
+ */
+ if (cs->temps[index].reg == -1)
+ cs->temps[index].reg = get_hw_temp(fp, cs->nrslots);
+
+ idx = cs->temps[index].reg;
+
+ if (!REG_GET_NO_USE(src) && (--cs->temps[index].refcount == 0))
+ free_temp(fp, src);
+ break;
+ case REG_TYPE_INPUT:
+ idx = cs->inputs[index].reg;
+
+ if (!REG_GET_NO_USE(src) && (--cs->inputs[index].refcount == 0))
+ free_hw_temp(fp, cs->inputs[index].reg);
+ break;
+ case REG_TYPE_CONST:
+ return (index | SRC_CONST);
+ default:
+ ERROR("Invalid type for source reg\n");
+ return (0 | SRC_CONST);
+ }
+
+ if (!tex)
+ cs->used_in_node |= (1 << idx);
+
+ return idx;
+}
+
+static int t_hw_dst(struct r300_fragment_program *fp,
+ GLuint dest, GLboolean tex, int slot)
+{
+ COMPILE_STATE;
+ int idx;
+ GLuint index = REG_GET_INDEX(dest);
+ assert(REG_GET_VALID(dest));
+
+ switch (REG_GET_TYPE(dest)) {
+ case REG_TYPE_TEMP:
+ if (cs->temps[REG_GET_INDEX(dest)].reg == -1) {
+ if (!tex) {
+ cs->temps[index].reg = get_hw_temp(fp, slot);
+ } else {
+ cs->temps[index].reg = get_hw_temp_tex(fp);
+ }
+ }
+ idx = cs->temps[index].reg;
+
+ if (!REG_GET_NO_USE(dest) && (--cs->temps[index].refcount == 0))
+ free_temp(fp, dest);
+
+ cs->dest_in_node |= (1 << idx);
+ cs->used_in_node |= (1 << idx);
+ break;
+ case REG_TYPE_OUTPUT:
+ switch (index) {
+ case FRAG_RESULT_COLR:
+ fp->node[fp->cur_node].flags |=
+ R300_PFS_NODE_OUTPUT_COLOR;
+ break;
+ case FRAG_RESULT_DEPR:
+ fp->node[fp->cur_node].flags |=
+ R300_PFS_NODE_OUTPUT_DEPTH;
+ break;
+ }
+ return index;
+ break;
+ default:
+ ERROR("invalid dest reg type %d\n", REG_GET_TYPE(dest));
+ return 0;
+ }
+
+ return idx;
+}
+
+static void emit_nop(struct r300_fragment_program *fp)
+{
+ COMPILE_STATE;
+
+ if (cs->nrslots >= PFS_MAX_ALU_INST) {
+ ERROR("Out of ALU instruction slots\n");
+ return;
+ }
+
+ fp->alu.inst[cs->nrslots].inst0 = NOP_INST0;
+ fp->alu.inst[cs->nrslots].inst1 = NOP_INST1;
+ fp->alu.inst[cs->nrslots].inst2 = NOP_INST2;
+ fp->alu.inst[cs->nrslots].inst3 = NOP_INST3;
+ cs->nrslots++;
+}
+
+static void emit_tex(struct r300_fragment_program *fp,
+ struct prog_instruction *fpi, int opcode)
+{
+ COMPILE_STATE;
+ GLuint coord = t_src(fp, fpi->SrcReg[0]);
+ GLuint dest = undef, rdest = undef;
+ GLuint din, uin;
+ int unit = fpi->TexSrcUnit;
+ int hwsrc, hwdest;
+ GLuint tempreg = 0;
+
+ uin = cs->used_in_node;
+ din = cs->dest_in_node;
+
+ /* Resolve source/dest to hardware registers */
+ if (opcode != R300_FPITX_OP_KIL) {
+ if (fpi->TexSrcTarget == TEXTURE_RECT_INDEX) {
+ /**
+ * Hardware uses [0..1]x[0..1] range for rectangle textures
+ * instead of [0..Width]x[0..Height].
+ * Add a scaling instruction.
+ *
+ * \todo Refactor this once we have proper rewriting/optimization
+ * support for programs.
+ */
+ gl_state_index tokens[STATE_LENGTH] = {
+ STATE_INTERNAL, STATE_R300_TEXRECT_FACTOR, 0, 0,
+ 0
+ };
+ int factor_index;
+ GLuint factorreg;
+
+ tokens[2] = unit;
+ factor_index =
+ _mesa_add_state_reference(fp->mesa_program.Base.
+ Parameters, tokens);
+ factorreg =
+ emit_const4fv(fp,
+ fp->mesa_program.Base.Parameters->
+ ParameterValues[factor_index]);
+ tempreg = keep(get_temp_reg(fp));
+
+ emit_arith(fp, PFS_OP_MAD, tempreg, WRITEMASK_XYZW,
+ coord, factorreg, pfs_zero, 0);
+
+ /* Ensure correct node indirection */
+ uin = cs->used_in_node;
+ din = cs->dest_in_node;
+
+ hwsrc = t_hw_src(fp, tempreg, GL_TRUE);
+ } else {
+ hwsrc = t_hw_src(fp, coord, GL_TRUE);
+ }
+
+ dest = t_dst(fp, fpi->DstReg);
+
+ /* r300 doesn't seem to be able to do TEX->output reg */
+ if (REG_GET_TYPE(dest) == REG_TYPE_OUTPUT) {
+ rdest = dest;
+ dest = get_temp_reg_tex(fp);
+ } else if (fpi->DstReg.WriteMask != WRITEMASK_XYZW) {
+ /* in case write mask isn't XYZW */
+ rdest = dest;
+ dest = get_temp_reg_tex(fp);
+ }
+ hwdest =
+ t_hw_dst(fp, dest, GL_TRUE,
+ fp->node[fp->cur_node].alu_offset);
+
+ /* Use a temp that hasn't been used in this node, rather
+ * than causing an indirection
+ */
+ if (uin & (1 << hwdest)) {
+ free_hw_temp(fp, hwdest);
+ hwdest = get_hw_temp_tex(fp);
+ cs->temps[REG_GET_INDEX(dest)].reg = hwdest;
+ }
+ } else {
+ hwdest = 0;
+ unit = 0;
+ hwsrc = t_hw_src(fp, coord, GL_TRUE);
+ }
+
+ /* 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 (fp->node[fp->cur_node].alu_offset == cs->nrslots)
+ emit_nop(fp);
+
+ fp->node[fp->cur_node].alu_end =
+ cs->nrslots - fp->node[fp->cur_node].alu_offset - 1;
+ assert(fp->node[fp->cur_node].alu_end >= 0);
+
+ if (++fp->cur_node >= PFS_MAX_TEX_INDIRECT) {
+ ERROR("too many levels of texture indirection\n");
+ return;
+ }
+
+ /* Start new node */
+ fp->node[fp->cur_node].tex_offset = fp->tex.length;
+ fp->node[fp->cur_node].alu_offset = cs->nrslots;
+ fp->node[fp->cur_node].tex_end = -1;
+ fp->node[fp->cur_node].alu_end = -1;
+ fp->node[fp->cur_node].flags = 0;
+ cs->used_in_node = 0;
+ cs->dest_in_node = 0;
+ }
+
+ if (fp->cur_node == 0)
+ fp->first_node_has_tex = 1;
+
+ fp->tex.inst[fp->tex.length++] = 0 | (hwsrc << R300_FPITX_SRC_SHIFT)
+ | (hwdest << R300_FPITX_DST_SHIFT)
+ | (unit << R300_FPITX_IMAGE_SHIFT)
+ /* not entirely sure about this */
+ | (opcode << R300_FPITX_OPCODE_SHIFT);
+
+ cs->dest_in_node |= (1 << hwdest);
+ if (REG_GET_TYPE(coord) != REG_TYPE_CONST)
+ cs->used_in_node |= (1 << hwsrc);
+
+ fp->node[fp->cur_node].tex_end++;
+
+ /* Copy from temp to output if needed */
+ if (REG_GET_VALID(rdest)) {
+ emit_arith(fp, PFS_OP_MAD, rdest, fpi->DstReg.WriteMask, dest,
+ pfs_one, pfs_zero, 0);
+ free_temp(fp, dest);
+ }
+
+ /* Free temp register */
+ if (tempreg != 0)
+ free_temp(fp, tempreg);
+}
+
+/**
+ * Returns the first slot where we could possibly allow writing to dest,
+ * according to register allocation.
+ */
+static int get_earliest_allowed_write(struct r300_fragment_program *fp,
+ GLuint dest, int mask)
+{
+ COMPILE_STATE;
+ int idx;
+ int pos;
+ GLuint index = REG_GET_INDEX(dest);
+ assert(REG_GET_VALID(dest));
+
+ switch (REG_GET_TYPE(dest)) {
+ case REG_TYPE_TEMP:
+ if (cs->temps[index].reg == -1)
+ return 0;
+
+ idx = cs->temps[index].reg;
+ break;
+ case REG_TYPE_OUTPUT:
+ return 0;
+ default:
+ 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)
+ pos = cs->hwtemps[idx].vector_lastread;
+ }
+ if (mask & WRITEMASK_W) {
+ if (pos < cs->hwtemps[idx].scalar_lastread)
+ pos = cs->hwtemps[idx].scalar_lastread;
+ }
+
+ return pos;
+}
+
+/**
+ * Allocates a slot for an ALU instruction that can consist of
+ * a vertex part or a scalar part or both.
+ *
+ * Sources from src (src[0] to src[argc-1]) are added to the slot in the
+ * appropriate position (vector and/or scalar), and their positions are
+ * recorded in the srcpos array.
+ *
+ * This function emits instruction code for the source fetch and the
+ * argument selection. It does not emit instruction code for the
+ * opcode or the destination selection.
+ *
+ * @return the index of the slot
+ */
+static int find_and_prepare_slot(struct r300_fragment_program *fp,
+ GLboolean emit_vop,
+ GLboolean emit_sop,
+ int argc, GLuint * src, GLuint dest, int mask)
+{
+ COMPILE_STATE;
+ int hwsrc[3];
+ int srcpos[3];
+ unsigned int used;
+ int tempused;
+ int tempvsrc[3];
+ int tempssrc[3];
+ 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
+ used = 0;
+ if (emit_vop)
+ used |= SLOT_OP_VECTOR;
+ if (emit_sop)
+ used |= SLOT_OP_SCALAR;
+
+ pos = get_earliest_allowed_write(fp, dest, mask);
+
+ if (fp->node[fp->cur_node].alu_offset > pos)
+ pos = fp->node[fp->cur_node].alu_offset;
+ for (i = 0; i < argc; ++i) {
+ if (!REG_GET_BUILTIN(src[i])) {
+ if (emit_vop)
+ used |= v_swiz[REG_GET_VSWZ(src[i])].flags << i;
+ if (emit_sop)
+ used |= s_swiz[REG_GET_SSWZ(src[i])].flags << i;
+ }
+
+ hwsrc[i] = t_hw_src(fp, 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)
+ pos = cs->hwtemps[regnr].vector_valid;
+ }
+ if (used & (SLOT_SRC_SCALAR << i)) {
+ if (cs->hwtemps[regnr].scalar_valid > pos)
+ pos = cs->hwtemps[regnr].scalar_valid;
+ }
+ }
+ }
+
+ // 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");
+ return -1;
+ }
+
+ fp->alu.inst[pos].inst0 = NOP_INST0;
+ fp->alu.inst[pos].inst1 = NOP_INST1;
+ fp->alu.inst[pos].inst2 = NOP_INST2;
+ fp->alu.inst[pos].inst3 = NOP_INST3;
+
+ 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
+ // anything by splitting the parts).
+ // It also avoids headaches with swizzles that access both parts (i.e WXY)
+ tempused = cs->slot[pos].used;
+ for (i = 0; i < 3; ++i) {
+ 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)
+ tempvsrc[j] = hwsrc[i];
+ 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;
+ }
+ if (used & (SLOT_SRC_SCALAR << i)) {
+ if (cs->hwtemps[regnr].scalar_lastread < pos)
+ cs->hwtemps[regnr].scalar_lastread =
+ pos;
+ }
+ }
+ }
+
+ // Emit the source fetch code
+ fp->alu.inst[pos].inst1 &= ~R300_FPI1_SRC_MASK;
+ fp->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));
+
+ fp->alu.inst[pos].inst3 &= ~R300_FPI3_SRC_MASK;
+ fp->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 +
+ (srcpos[i] *
+ v_swiz[REG_GET_VSWZ(src[i])].
+ stride)) | ((src[i] & REG_NEGV_MASK)
+ ? ARG_NEG : 0) | ((src[i]
+ &
+ REG_ABS_MASK)
+ ?
+ ARG_ABS
+ : 0);
+ } else {
+ swz[i] = R300_FPI0_ARGC_ZERO;
+ }
+ }
+
+ fp->alu.inst[pos].inst0 &=
+ ~(R300_FPI0_ARG0C_MASK | R300_FPI0_ARG1C_MASK |
+ R300_FPI0_ARG2C_MASK);
+ fp->alu.inst[pos].inst0 |=
+ (swz[0] << R300_FPI0_ARG0C_SHIFT) | (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 +
+ (srcpos[i] *
+ s_swiz[REG_GET_SSWZ(src[i])].
+ stride)) | ((src[i] & REG_NEGV_MASK)
+ ? ARG_NEG : 0) | ((src[i]
+ &
+ REG_ABS_MASK)
+ ?
+ ARG_ABS
+ : 0);
+ } else {
+ swz[i] = R300_FPI2_ARGA_ZERO;
+ }
+ }
+
+ fp->alu.inst[pos].inst2 &=
+ ~(R300_FPI2_ARG0A_MASK | R300_FPI2_ARG1A_MASK |
+ R300_FPI2_ARG2A_MASK);
+ fp->alu.inst[pos].inst2 |=
+ (swz[0] << R300_FPI2_ARG0A_SHIFT) | (swz[1] <<
+ R300_FPI2_ARG1A_SHIFT)
+ | (swz[2] << R300_FPI2_ARG2A_SHIFT);
+ }
+
+ return pos;
+}
+
+/**
+ * Append an ALU instruction to the instruction list.
+ */
+static void emit_arith(struct r300_fragment_program *fp,
+ int op,
+ GLuint dest,
+ int mask,
+ GLuint src0, GLuint src1, GLuint src2, int flags)
+{
+ COMPILE_STATE;
+ GLuint src[3] = { src0, src1, src2 };
+ int hwdest;
+ GLboolean emit_vop, emit_sop;
+ int vop, sop, argc;
+ int pos;
+
+ vop = r300_fpop[op].v_op;
+ sop = r300_fpop[op].s_op;
+ argc = r300_fpop[op].argc;
+
+ if (REG_GET_TYPE(dest) == REG_TYPE_OUTPUT &&
+ REG_GET_INDEX(dest) == FRAG_RESULT_DEPR) {
+ if (mask & WRITEMASK_Z) {
+ mask = WRITEMASK_W;
+ } else {
+ return;
+ }
+ }
+
+ emit_vop = GL_FALSE;
+ emit_sop = GL_FALSE;
+ if ((mask & WRITEMASK_XYZ) || vop == R300_FPI0_OUTC_DP3)
+ emit_vop = GL_TRUE;
+ if ((mask & WRITEMASK_W) || vop == R300_FPI0_OUTC_REPL_ALPHA)
+ emit_sop = GL_TRUE;
+
+ pos =
+ find_and_prepare_slot(fp, emit_vop, emit_sop, argc, src, dest,
+ mask);
+ if (pos < 0)
+ return;
+
+ hwdest = t_hw_dst(fp, 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;
+ }
+
+ /* Throw the pieces together and get FPI0/1 */
+ if (emit_vop) {
+ fp->alu.inst[pos].inst0 |= vop;
+
+ fp->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) {
+ fp->alu.inst[pos].inst1 |=
+ (mask & WRITEMASK_XYZ) <<
+ R300_FPI1_DSTC_OUTPUT_MASK_SHIFT;
+ } else
+ assert(0);
+ } else {
+ fp->alu.inst[pos].inst1 |=
+ (mask & WRITEMASK_XYZ) <<
+ R300_FPI1_DSTC_REG_MASK_SHIFT;
+
+ cs->hwtemps[hwdest].vector_valid = pos + 1;
+ }
+ }
+
+ /* And now FPI2/3 */
+ if (emit_sop) {
+ fp->alu.inst[pos].inst2 |= sop;
+
+ if (mask & WRITEMASK_W) {
+ if (REG_GET_TYPE(dest) == REG_TYPE_OUTPUT) {
+ if (REG_GET_INDEX(dest) == FRAG_RESULT_COLR) {
+ fp->alu.inst[pos].inst3 |=
+ (hwdest << R300_FPI3_DSTA_SHIFT) |
+ R300_FPI3_DSTA_OUTPUT;
+ } else if (REG_GET_INDEX(dest) ==
+ FRAG_RESULT_DEPR) {
+ fp->alu.inst[pos].inst3 |=
+ R300_FPI3_DSTA_DEPTH;
+ } else
+ assert(0);
+ } else {
+ fp->alu.inst[pos].inst3 |=
+ (hwdest << R300_FPI3_DSTA_SHIFT) |
+ R300_FPI3_DSTA_REG;
+
+ cs->hwtemps[hwdest].scalar_valid = pos + 1;
+ }
+ }
+ }
+
+ return;
+}
+
+#if 0
+static GLuint get_attrib(struct r300_fragment_program *fp, GLuint attr)
+{
+ struct gl_fragment_program *mp = &fp->mesa_program;
+ GLuint r = undef;
+
+ if (!(mp->Base.InputsRead & (1 << attr))) {
+ ERROR("Attribute %d was not provided!\n", attr);
+ return undef;
+ }
+
+ REG_SET_TYPE(r, REG_TYPE_INPUT);
+ REG_SET_INDEX(r, attr);
+ REG_SET_VALID(r, GL_TRUE);
+ return r;
+}
+#endif
+
+static GLfloat SinCosConsts[2][4] = {
+ {
+ 1.273239545, // 4/PI
+ -0.405284735, // -4/(PI*PI)
+ 3.141592654, // PI
+ 0.2225 // weight
+ },
+ {
+ 0.75,
+ 0.0,
+ 0.159154943, // 1/(2*PI)
+ 6.283185307 // 2*PI
+ }
+};
+
+/**
+ * Emit a LIT instruction.
+ * \p flags may be PFS_FLAG_SAT
+ *
+ * Definition of LIT (from ARB_fragment_program):
+ * tmp = VectorLoad(op0);
+ * if (tmp.x < 0) tmp.x = 0;
+ * if (tmp.y < 0) tmp.y = 0;
+ * if (tmp.w < -(128.0-epsilon)) tmp.w = -(128.0-epsilon);
+ * else if (tmp.w > 128-epsilon) tmp.w = 128-epsilon;
+ * result.x = 1.0;
+ * result.y = tmp.x;
+ * result.z = (tmp.x > 0) ? RoughApproxPower(tmp.y, tmp.w) : 0.0;
+ * result.w = 1.0;
+ *
+ * The longest path of computation is the one leading to result.z,
+ * consisting of 5 operations. This implementation of LIT takes
+ * 5 slots. So unless there's some special undocumented opcode,
+ * this implementation is potentially optimal. Unfortunately,
+ * emit_arith is a bit too conservative because it doesn't understand
+ * partial writes to the vector component.
+ */
+static const GLfloat LitConst[4] =
+ { 127.999999, 127.999999, 127.999999, -127.999999 };
+
+static void emit_lit(struct r300_fragment_program *fp,
+ GLuint dest, int mask, GLuint src, int flags)
+{
+ COMPILE_STATE;
+ GLuint cnst;
+ int needTemporary;
+ GLuint temp;
+
+ cnst = emit_const4fv(fp, LitConst);
+
+ needTemporary = 0;
+ if ((mask & WRITEMASK_XYZW) != WRITEMASK_XYZW) {
+ needTemporary = 1;
+ } else if (REG_GET_TYPE(dest) == REG_TYPE_OUTPUT) {
+ // LIT is typically followed by DP3/DP4, so there's no point
+ // in creating special code for this case
+ needTemporary = 1;
+ }
+
+ if (needTemporary) {
+ temp = keep(get_temp_reg(fp));
+ } else {
+ temp = keep(dest);
+ }
+
+ // Note: 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(fp, PFS_OP_MAX, temp, WRITEMASK_XY,
+ keep(src), pfs_zero, undef, 0);
+ emit_arith(fp, PFS_OP_MAX, temp, WRITEMASK_W, src, cnst, undef, 0);
+
+ // Second slot
+ emit_arith(fp, PFS_OP_MIN, temp, WRITEMASK_Z,
+ swizzle(temp, W, W, W, W), cnst, undef, 0);
+ emit_arith(fp, 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
+ emit_arith(fp, PFS_OP_MAD, temp, WRITEMASK_W,
+ temp, swizzle(temp, Z, Z, Z, Z), pfs_zero, 0);
+ emit_arith(fp, PFS_OP_MAD, temp, WRITEMASK_Y,
+ swizzle(temp, X, X, X, X), pfs_one, pfs_zero, flags);
+
+ // Fourth slot
+ emit_arith(fp, PFS_OP_MAD, temp, WRITEMASK_X,
+ pfs_one, pfs_one, pfs_zero, 0);
+ emit_arith(fp, PFS_OP_EX2, temp, WRITEMASK_W, temp, undef, undef, 0);
+
+ // Fifth slot
+ emit_arith(fp, PFS_OP_CMP, temp, WRITEMASK_Z,
+ pfs_zero, swizzle(temp, W, W, W, W),
+ negate(swizzle(temp, Y, Y, Y, Y)), flags);
+ emit_arith(fp, PFS_OP_MAD, temp, WRITEMASK_W, pfs_one, pfs_one,
+ pfs_zero, 0);
+
+ if (needTemporary) {
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ temp, pfs_one, pfs_zero, flags);
+ free_temp(fp, temp);
+ } else {
+ // Decrease refcount of the destination
+ t_hw_dst(fp, dest, GL_FALSE, cs->nrslots);
+ }
+}
+
+static GLboolean parse_program(struct r300_fragment_program *fp)
+{
+ struct gl_fragment_program *mp = &fp->mesa_program;
+ const struct prog_instruction *inst = mp->Base.Instructions;
+ struct prog_instruction *fpi;
+ GLuint src[3], dest, temp[2];
+ int flags, mask = 0;
+ int const_sin[2];
+
+ if (!inst || inst[0].Opcode == OPCODE_END) {
+ ERROR("empty program?\n");
+ return GL_FALSE;
+ }
+
+ for (fpi = mp->Base.Instructions; fpi->Opcode != OPCODE_END; fpi++) {
+ if (fpi->SaturateMode == SATURATE_ZERO_ONE)
+ flags = PFS_FLAG_SAT;
+ else
+ flags = 0;
+
+ if (fpi->Opcode != OPCODE_KIL) {
+ dest = t_dst(fp, fpi->DstReg);
+ mask = fpi->DstReg.WriteMask;
+ }
+
+ switch (fpi->Opcode) {
+ case OPCODE_ABS:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ absolute(src[0]), pfs_one, pfs_zero, flags);
+ break;
+ case OPCODE_ADD:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ src[0], pfs_one, src[1], flags);
+ break;
+ case OPCODE_CMP:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ src[2] = t_src(fp, fpi->SrcReg[2]);
+ /* ARB_f_p - if src0.c < 0.0 ? src1.c : src2.c
+ * r300 - if src2.c < 0.0 ? src1.c : src0.c
+ */
+ emit_arith(fp, PFS_OP_CMP, dest, mask,
+ src[2], src[1], src[0], flags);
+ break;
+ case OPCODE_COS:
+ /*
+ * cos using a parabola (see SIN):
+ * cos(x):
+ * x = (x/(2*PI))+0.75
+ * x = frac(x)
+ * x = (x*2*PI)-PI
+ * result = sin(x)
+ */
+ temp[0] = get_temp_reg(fp);
+ const_sin[0] = emit_const4fv(fp, SinCosConsts[0]);
+ const_sin[1] = emit_const4fv(fp, SinCosConsts[1]);
+ src[0] = t_scalar_src(fp, fpi->SrcReg[0]);
+
+ /* add 0.5*PI and do range reduction */
+
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_X,
+ swizzle(src[0], X, X, X, X),
+ swizzle(const_sin[1], Z, Z, Z, Z),
+ swizzle(const_sin[1], X, X, X, X), 0);
+
+ emit_arith(fp, PFS_OP_FRC, temp[0], WRITEMASK_X,
+ swizzle(temp[0], X, X, X, X),
+ undef, undef, 0);
+
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_Z, swizzle(temp[0], X, X, X, X), swizzle(const_sin[1], W, W, W, W), //2*PI
+ negate(swizzle(const_sin[0], Z, Z, Z, Z)), //-PI
+ 0);
+
+ /* SIN */
+
+ emit_arith(fp, PFS_OP_MAD, temp[0],
+ WRITEMASK_X | WRITEMASK_Y, swizzle(temp[0],
+ Z, Z, Z,
+ Z),
+ const_sin[0], pfs_zero, 0);
+
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_X,
+ swizzle(temp[0], Y, Y, Y, Y),
+ absolute(swizzle(temp[0], Z, Z, Z, Z)),
+ swizzle(temp[0], X, X, X, X), 0);
+
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_Y,
+ swizzle(temp[0], X, X, X, X),
+ absolute(swizzle(temp[0], X, X, X, X)),
+ negate(swizzle(temp[0], X, X, X, X)), 0);
+
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ swizzle(temp[0], Y, Y, Y, Y),
+ swizzle(const_sin[0], W, W, W, W),
+ swizzle(temp[0], X, X, X, X), flags);
+
+ free_temp(fp, temp[0]);
+ break;
+ case OPCODE_DP3:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ emit_arith(fp, PFS_OP_DP3, dest, mask,
+ src[0], src[1], undef, flags);
+ break;
+ case OPCODE_DP4:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ emit_arith(fp, PFS_OP_DP4, dest, mask,
+ src[0], src[1], undef, flags);
+ break;
+ case OPCODE_DPH:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ /* src0.xyz1 -> temp
+ * DP4 dest, temp, src1
+ */
+#if 0
+ temp[0] = get_temp_reg(fp);
+ src[0].s_swz = SWIZZLE_ONE;
+ emit_arith(fp, PFS_OP_MAD, temp[0], mask,
+ src[0], pfs_one, pfs_zero, 0);
+ emit_arith(fp, PFS_OP_DP4, dest, mask,
+ temp[0], src[1], undef, flags);
+ free_temp(fp, temp[0]);
+#else
+ emit_arith(fp, PFS_OP_DP4, dest, mask,
+ swizzle(src[0], X, Y, Z, ONE), src[1],
+ undef, flags);
+#endif
+ break;
+ case OPCODE_DST:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ /* dest.y = src0.y * src1.y */
+ if (mask & WRITEMASK_Y)
+ emit_arith(fp, PFS_OP_MAD, dest, WRITEMASK_Y,
+ keep(src[0]), keep(src[1]),
+ pfs_zero, flags);
+ /* dest.z = src0.z */
+ if (mask & WRITEMASK_Z)
+ emit_arith(fp, PFS_OP_MAD, dest, WRITEMASK_Z,
+ src[0], pfs_one, pfs_zero, flags);
+ /* result.x = 1.0
+ * result.w = src1.w */
+ if (mask & WRITEMASK_XW) {
+ REG_SET_VSWZ(src[1], SWIZZLE_111); /*Cheat */
+ emit_arith(fp, PFS_OP_MAD, dest,
+ mask & WRITEMASK_XW,
+ src[1], pfs_one, pfs_zero, flags);
+ }
+ break;
+ case OPCODE_EX2:
+ src[0] = t_scalar_src(fp, fpi->SrcReg[0]);
+ emit_arith(fp, PFS_OP_EX2, dest, mask,
+ src[0], undef, undef, flags);
+ break;
+ case OPCODE_FLR:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ temp[0] = get_temp_reg(fp);
+ /* FRC temp, src0
+ * MAD dest, src0, 1.0, -temp
+ */
+ emit_arith(fp, PFS_OP_FRC, temp[0], mask,
+ keep(src[0]), undef, undef, 0);
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ src[0], pfs_one, negate(temp[0]), flags);
+ free_temp(fp, temp[0]);
+ break;
+ case OPCODE_FRC:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ emit_arith(fp, PFS_OP_FRC, dest, mask,
+ src[0], undef, undef, flags);
+ break;
+ case OPCODE_KIL:
+ emit_tex(fp, fpi, R300_FPITX_OP_KIL);
+ break;
+ case OPCODE_LG2:
+ src[0] = t_scalar_src(fp, fpi->SrcReg[0]);
+ emit_arith(fp, PFS_OP_LG2, dest, mask,
+ src[0], undef, undef, flags);
+ break;
+ case OPCODE_LIT:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ emit_lit(fp, dest, mask, src[0], flags);
+ break;
+ case OPCODE_LRP:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ src[2] = t_src(fp, fpi->SrcReg[2]);
+ /* result = tmp0tmp1 + (1 - tmp0)tmp2
+ * = tmp0tmp1 + tmp2 + (-tmp0)tmp2
+ * MAD temp, -tmp0, tmp2, tmp2
+ * MAD result, tmp0, tmp1, temp
+ */
+ temp[0] = get_temp_reg(fp);
+ emit_arith(fp, PFS_OP_MAD, temp[0], mask,
+ negate(keep(src[0])), keep(src[2]), src[2],
+ 0);
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ src[0], src[1], temp[0], flags);
+ free_temp(fp, temp[0]);
+ break;
+ case OPCODE_MAD:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ src[2] = t_src(fp, fpi->SrcReg[2]);
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ src[0], src[1], src[2], flags);
+ break;
+ case OPCODE_MAX:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ emit_arith(fp, PFS_OP_MAX, dest, mask,
+ src[0], src[1], undef, flags);
+ break;
+ case OPCODE_MIN:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ emit_arith(fp, PFS_OP_MIN, dest, mask,
+ src[0], src[1], undef, flags);
+ break;
+ case OPCODE_MOV:
+ case OPCODE_SWZ:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ src[0], pfs_one, pfs_zero, flags);
+ break;
+ case OPCODE_MUL:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ src[0], src[1], pfs_zero, flags);
+ break;
+ case OPCODE_POW:
+ src[0] = t_scalar_src(fp, fpi->SrcReg[0]);
+ src[1] = t_scalar_src(fp, fpi->SrcReg[1]);
+ temp[0] = get_temp_reg(fp);
+ emit_arith(fp, PFS_OP_LG2, temp[0], WRITEMASK_W,
+ src[0], undef, undef, 0);
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_W,
+ temp[0], src[1], pfs_zero, 0);
+ emit_arith(fp, PFS_OP_EX2, dest, fpi->DstReg.WriteMask,
+ temp[0], undef, undef, 0);
+ free_temp(fp, temp[0]);
+ break;
+ case OPCODE_RCP:
+ src[0] = t_scalar_src(fp, fpi->SrcReg[0]);
+ emit_arith(fp, PFS_OP_RCP, dest, mask,
+ src[0], undef, undef, flags);
+ break;
+ case OPCODE_RSQ:
+ src[0] = t_scalar_src(fp, fpi->SrcReg[0]);
+ emit_arith(fp, PFS_OP_RSQ, dest, mask,
+ absolute(src[0]), pfs_zero, pfs_zero, flags);
+ break;
+ case OPCODE_SCS:
+ /*
+ * scs using a parabola :
+ * scs(x):
+ * result.x = sin(-abs(x)+0.5*PI) (cos)
+ * result.y = sin(x) (sin)
+ *
+ */
+ temp[0] = get_temp_reg(fp);
+ temp[1] = get_temp_reg(fp);
+ const_sin[0] = emit_const4fv(fp, SinCosConsts[0]);
+ const_sin[1] = emit_const4fv(fp, SinCosConsts[1]);
+ src[0] = t_scalar_src(fp, fpi->SrcReg[0]);
+
+ /* x = -abs(x)+0.5*PI */
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_Z, swizzle(const_sin[0], Z, Z, Z, Z), //PI
+ pfs_half,
+ negate(abs
+ (swizzle(keep(src[0]), X, X, X, X))),
+ 0);
+
+ /* C*x (sin) */
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_W,
+ swizzle(const_sin[0], Y, Y, Y, Y),
+ swizzle(keep(src[0]), X, X, X, X),
+ pfs_zero, 0);
+
+ /* B*x, C*x (cos) */
+ emit_arith(fp, PFS_OP_MAD, temp[0],
+ WRITEMASK_X | WRITEMASK_Y, swizzle(temp[0],
+ Z, Z, Z,
+ Z),
+ const_sin[0], pfs_zero, 0);
+
+ /* B*x (sin) */
+ emit_arith(fp, PFS_OP_MAD, temp[1], WRITEMASK_W,
+ swizzle(const_sin[0], X, X, X, X),
+ keep(src[0]), pfs_zero, 0);
+
+ /* y = B*x + C*x*abs(x) (sin) */
+ emit_arith(fp, PFS_OP_MAD, temp[1], WRITEMASK_Z,
+ absolute(src[0]),
+ swizzle(temp[0], W, W, W, W),
+ swizzle(temp[1], W, W, W, W), 0);
+
+ /* y = B*x + C*x*abs(x) (cos) */
+ emit_arith(fp, PFS_OP_MAD, temp[1], WRITEMASK_W,
+ swizzle(temp[0], Y, Y, Y, Y),
+ absolute(swizzle(temp[0], Z, Z, Z, Z)),
+ swizzle(temp[0], X, X, X, X), 0);
+
+ /* y*abs(y) - y (cos), y*abs(y) - y (sin) */
+ emit_arith(fp, PFS_OP_MAD, temp[0],
+ WRITEMASK_X | WRITEMASK_Y, swizzle(temp[1],
+ W, Z, Y,
+ X),
+ absolute(swizzle(temp[1], W, Z, Y, X)),
+ negate(swizzle(temp[1], W, Z, Y, X)), 0);
+
+ /* dest.xy = mad(temp.xy, P, temp2.wz) */
+ emit_arith(fp, PFS_OP_MAD, dest,
+ mask & (WRITEMASK_X | WRITEMASK_Y), temp[0],
+ swizzle(const_sin[0], W, W, W, W),
+ swizzle(temp[1], W, Z, Y, X), flags);
+
+ free_temp(fp, temp[0]);
+ free_temp(fp, temp[1]);
+ break;
+ case OPCODE_SGE:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ temp[0] = get_temp_reg(fp);
+ /* temp = src0 - src1
+ * dest.c = (temp.c < 0.0) ? 0 : 1
+ */
+ emit_arith(fp, PFS_OP_MAD, temp[0], mask,
+ src[0], pfs_one, negate(src[1]), 0);
+ emit_arith(fp, PFS_OP_CMP, dest, mask,
+ pfs_one, pfs_zero, temp[0], 0);
+ free_temp(fp, temp[0]);
+ break;
+ case OPCODE_SIN:
+ /*
+ * using a parabola:
+ * sin(x) = 4/pi * x + -4/(pi*pi) * x * abs(x)
+ * extra precision is obtained by weighting against
+ * itself squared.
+ */
+
+ temp[0] = get_temp_reg(fp);
+ const_sin[0] = emit_const4fv(fp, SinCosConsts[0]);
+ const_sin[1] = emit_const4fv(fp, SinCosConsts[1]);
+ src[0] = t_scalar_src(fp, fpi->SrcReg[0]);
+
+ /* do range reduction */
+
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_X,
+ swizzle(keep(src[0]), X, X, X, X),
+ swizzle(const_sin[1], Z, Z, Z, Z),
+ pfs_half, 0);
+
+ emit_arith(fp, PFS_OP_FRC, temp[0], WRITEMASK_X,
+ swizzle(temp[0], X, X, X, X),
+ undef, undef, 0);
+
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_Z, swizzle(temp[0], X, X, X, X), swizzle(const_sin[1], W, W, W, W), //2*PI
+ negate(swizzle(const_sin[0], Z, Z, Z, Z)), //PI
+ 0);
+
+ /* SIN */
+
+ emit_arith(fp, PFS_OP_MAD, temp[0],
+ WRITEMASK_X | WRITEMASK_Y, swizzle(temp[0],
+ Z, Z, Z,
+ Z),
+ const_sin[0], pfs_zero, 0);
+
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_X,
+ swizzle(temp[0], Y, Y, Y, Y),
+ absolute(swizzle(temp[0], Z, Z, Z, Z)),
+ swizzle(temp[0], X, X, X, X), 0);
+
+ emit_arith(fp, PFS_OP_MAD, temp[0], WRITEMASK_Y,
+ swizzle(temp[0], X, X, X, X),
+ absolute(swizzle(temp[0], X, X, X, X)),
+ negate(swizzle(temp[0], X, X, X, X)), 0);
+
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ swizzle(temp[0], Y, Y, Y, Y),
+ swizzle(const_sin[0], W, W, W, W),
+ swizzle(temp[0], X, X, X, X), flags);
+
+ free_temp(fp, temp[0]);
+ break;
+ case OPCODE_SLT:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ temp[0] = get_temp_reg(fp);
+ /* temp = src0 - src1
+ * dest.c = (temp.c < 0.0) ? 1 : 0
+ */
+ emit_arith(fp, PFS_OP_MAD, temp[0], mask,
+ src[0], pfs_one, negate(src[1]), 0);
+ emit_arith(fp, PFS_OP_CMP, dest, mask,
+ pfs_zero, pfs_one, temp[0], 0);
+ free_temp(fp, temp[0]);
+ break;
+ case OPCODE_SUB:
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ emit_arith(fp, PFS_OP_MAD, dest, mask,
+ src[0], pfs_one, negate(src[1]), flags);
+ break;
+ case OPCODE_TEX:
+ emit_tex(fp, fpi, R300_FPITX_OP_TEX);
+ break;
+ case OPCODE_TXB:
+ emit_tex(fp, fpi, R300_FPITX_OP_TXB);
+ break;
+ case OPCODE_TXP:
+ emit_tex(fp, fpi, R300_FPITX_OP_TXP);
+ break;
+ case OPCODE_XPD:{
+ src[0] = t_src(fp, fpi->SrcReg[0]);
+ src[1] = t_src(fp, fpi->SrcReg[1]);
+ temp[0] = get_temp_reg(fp);
+ /* temp = src0.zxy * src1.yzx */
+ emit_arith(fp, PFS_OP_MAD, temp[0],
+ WRITEMASK_XYZ, swizzle(keep(src[0]),
+ Z, X, Y, W),
+ swizzle(keep(src[1]), Y, Z, X, W),
+ pfs_zero, 0);
+ /* dest.xyz = src0.yzx * src1.zxy - temp
+ * dest.w = undefined
+ * */
+ emit_arith(fp, PFS_OP_MAD, dest,
+ mask & WRITEMASK_XYZ, swizzle(src[0],
+ Y, Z,
+ X, W),
+ swizzle(src[1], Z, X, Y, W),
+ negate(temp[0]), flags);
+ /* cleanup */
+ free_temp(fp, temp[0]);
+ break;
+ }
+ default:
+ ERROR("unknown fpi->Opcode %d\n", fpi->Opcode);
+ break;
+ }
+
+ if (fp->error)
+ return GL_FALSE;
+
+ }
+
+ return GL_TRUE;
+}
+
+static void insert_wpos(struct gl_program *prog)
+{
+ static gl_state_index tokens[STATE_LENGTH] = {
+ STATE_INTERNAL, STATE_R300_WINDOW_DIMENSION, 0, 0, 0
+ };
+ struct prog_instruction *fpi;
+ GLuint window_index;
+ int i = 0;
+ GLuint tempregi = prog->NumTemporaries;
+ /* should do something else if no temps left... */
+ prog->NumTemporaries++;
+
+ fpi = _mesa_alloc_instructions(prog->NumInstructions + 3);
+ _mesa_init_instructions(fpi, prog->NumInstructions + 3);
+
+ /* perspective divide */
+ fpi[i].Opcode = OPCODE_RCP;
+
+ fpi[i].DstReg.File = PROGRAM_TEMPORARY;
+ fpi[i].DstReg.Index = tempregi;
+ fpi[i].DstReg.WriteMask = WRITEMASK_W;
+ fpi[i].DstReg.CondMask = COND_TR;
+
+ fpi[i].SrcReg[0].File = PROGRAM_INPUT;
+ fpi[i].SrcReg[0].Index = FRAG_ATTRIB_WPOS;
+ fpi[i].SrcReg[0].Swizzle = SWIZZLE_WWWW;
+ i++;
+
+ fpi[i].Opcode = OPCODE_MUL;
+
+ fpi[i].DstReg.File = PROGRAM_TEMPORARY;
+ fpi[i].DstReg.Index = tempregi;
+ fpi[i].DstReg.WriteMask = WRITEMASK_XYZ;
+ fpi[i].DstReg.CondMask = COND_TR;
+
+ fpi[i].SrcReg[0].File = PROGRAM_INPUT;
+ fpi[i].SrcReg[0].Index = FRAG_ATTRIB_WPOS;
+ fpi[i].SrcReg[0].Swizzle = SWIZZLE_XYZW;
+
+ fpi[i].SrcReg[1].File = PROGRAM_TEMPORARY;
+ fpi[i].SrcReg[1].Index = tempregi;
+ fpi[i].SrcReg[1].Swizzle = SWIZZLE_WWWW;
+ i++;
+
+ /* viewport transformation */
+ window_index = _mesa_add_state_reference(prog->Parameters, tokens);
+
+ fpi[i].Opcode = OPCODE_MAD;
+
+ fpi[i].DstReg.File = PROGRAM_TEMPORARY;
+ fpi[i].DstReg.Index = tempregi;
+ fpi[i].DstReg.WriteMask = WRITEMASK_XYZ;
+ fpi[i].DstReg.CondMask = COND_TR;
+
+ fpi[i].SrcReg[0].File = PROGRAM_TEMPORARY;
+ fpi[i].SrcReg[0].Index = tempregi;
+ fpi[i].SrcReg[0].Swizzle =
+ MAKE_SWIZZLE4(SWIZZLE_X, SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_ZERO);
+
+ fpi[i].SrcReg[1].File = PROGRAM_STATE_VAR;
+ fpi[i].SrcReg[1].Index = window_index;
+ fpi[i].SrcReg[1].Swizzle =
+ MAKE_SWIZZLE4(SWIZZLE_X, SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_ZERO);
+
+ fpi[i].SrcReg[2].File = PROGRAM_STATE_VAR;
+ fpi[i].SrcReg[2].Index = window_index;
+ fpi[i].SrcReg[2].Swizzle =
+ MAKE_SWIZZLE4(SWIZZLE_X, SWIZZLE_Y, SWIZZLE_Z, SWIZZLE_ZERO);
+ i++;
+
+ _mesa_copy_instructions(&fpi[i], prog->Instructions,
+ prog->NumInstructions);
+
+ free(prog->Instructions);
+
+ prog->Instructions = fpi;
+
+ prog->NumInstructions += i;
+ 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 &&
+ fpi->SrcReg[i].Index == FRAG_ATTRIB_WPOS) {
+ fpi->SrcReg[i].File = PROGRAM_TEMPORARY;
+ fpi->SrcReg[i].Index = tempregi;
+ }
+ }
+}
+
+/* - Init structures
+ * - Determine what hwregs each input corresponds to
+ */
+static void init_program(r300ContextPtr r300, struct r300_fragment_program *fp)
+{
+ struct r300_pfs_compile_state *cs = NULL;
+ struct gl_fragment_program *mp = &fp->mesa_program;
+ struct prog_instruction *fpi;
+ GLuint InputsRead = mp->Base.InputsRead;
+ GLuint temps_used = 0; /* for fp->temps[] */
+ int i, j;
+
+ /* New compile, reset tracking data */
+ fp->optimization =
+ driQueryOptioni(&r300->radeon.optionCache, "fp_optimization");
+ fp->translated = GL_FALSE;
+ fp->error = GL_FALSE;
+ fp->cs = cs = &(R300_CONTEXT(fp->ctx)->state.pfs_compile);
+ fp->tex.length = 0;
+ fp->cur_node = 0;
+ fp->first_node_has_tex = 0;
+ fp->const_nr = 0;
+ fp->max_temp_idx = 0;
+ fp->node[0].alu_end = -1;
+ fp->node[0].tex_end = -1;
+
+ _mesa_memset(cs, 0, sizeof(*fp->cs));
+ for (i = 0; i < PFS_MAX_ALU_INST; i++) {
+ for (j = 0; j < 3; j++) {
+ cs->slot[i].vsrc[j] = SRC_CONST;
+ 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
+ *
+ * NOTE: this depends on get_hw_temp() allocating registers in order,
+ * starting from register 0.
+ */
+
+ /* Texcoords come first */
+ for (i = 0; i < fp->ctx->Const.MaxTextureUnits; i++) {
+ if (InputsRead & (FRAG_BIT_TEX0 << i)) {
+ cs->inputs[FRAG_ATTRIB_TEX0 + i].refcount = 0;
+ cs->inputs[FRAG_ATTRIB_TEX0 + i].reg =
+ get_hw_temp(fp, 0);
+ }
+ }
+ InputsRead &= ~FRAG_BITS_TEX_ANY;
+
+ /* fragment position treated as a texcoord */
+ if (InputsRead & FRAG_BIT_WPOS) {
+ cs->inputs[FRAG_ATTRIB_WPOS].refcount = 0;
+ cs->inputs[FRAG_ATTRIB_WPOS].reg = get_hw_temp(fp, 0);
+ insert_wpos(&mp->Base);
+ }
+ InputsRead &= ~FRAG_BIT_WPOS;
+
+ /* Then primary colour */
+ if (InputsRead & FRAG_BIT_COL0) {
+ cs->inputs[FRAG_ATTRIB_COL0].refcount = 0;
+ cs->inputs[FRAG_ATTRIB_COL0].reg = get_hw_temp(fp, 0);
+ }
+ InputsRead &= ~FRAG_BIT_COL0;
+
+ /* Secondary color */
+ if (InputsRead & FRAG_BIT_COL1) {
+ cs->inputs[FRAG_ATTRIB_COL1].refcount = 0;
+ cs->inputs[FRAG_ATTRIB_COL1].reg = get_hw_temp(fp, 0);
+ }
+ InputsRead &= ~FRAG_BIT_COL1;
+
+ /* Anything else */
+ if (InputsRead) {
+ WARN_ONCE("Don't know how to handle inputs 0x%x\n", InputsRead);
+ /* force read from hwreg 0 for now */
+ for (i = 0; i < 32; i++)
+ if (InputsRead & (1 << i))
+ cs->inputs[i].reg = 0;
+ }
+
+ /* Pre-parse the mesa program, grabbing refcounts on input/temp regs.
+ * That way, we can free up the reg when it's no longer needed
+ */
+ if (!mp->Base.Instructions) {
+ ERROR("No instructions found in program\n");
+ return;
+ }
+
+ 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) {
+ case PROGRAM_TEMPORARY:
+ if (!(temps_used & (1 << idx))) {
+ cs->temps[idx].reg = -1;
+ cs->temps[idx].refcount = 1;
+ temps_used |= (1 << idx);
+ } else
+ cs->temps[idx].refcount++;
+ break;
+ case PROGRAM_INPUT:
+ cs->inputs[idx].refcount++;
+ break;
+ default:
+ break;
+ }
+ }
+
+ idx = fpi->DstReg.Index;
+ if (fpi->DstReg.File == PROGRAM_TEMPORARY) {
+ if (!(temps_used & (1 << idx))) {
+ cs->temps[idx].reg = -1;
+ cs->temps[idx].refcount = 1;
+ temps_used |= (1 << idx);
+ } else
+ cs->temps[idx].refcount++;
+ }
+ }
+ cs->temp_in_use = temps_used;
+}
+
+static void update_params(struct r300_fragment_program *fp)
+{
+ struct gl_fragment_program *mp = &fp->mesa_program;
+
+ /* Ask Mesa nicely to fill in ParameterValues for us */
+ if (mp->Base.Parameters)
+ _mesa_load_state_parameters(fp->ctx, mp->Base.Parameters);
+}
+
+void r500TranslateFragmentShader(r300ContextPtr r300,
+ struct r300_fragment_program *fp)
+{
+ struct r300_pfs_compile_state *cs = NULL;
+
+ if (!fp->translated) {
+
+ init_program(r300, fp);
+ cs = fp->cs;
+
+ if (parse_program(fp) == GL_FALSE) {
+ dump_program(fp);
+ return;
+ }
+
+ /* Finish off */
+ fp->node[fp->cur_node].alu_end =
+ cs->nrslots - fp->node[fp->cur_node].alu_offset - 1;
+ if (fp->node[fp->cur_node].tex_end < 0)
+ fp->node[fp->cur_node].tex_end = 0;
+ fp->alu_offset = 0;
+ fp->alu_end = cs->nrslots - 1;
+ fp->tex_offset = 0;
+ fp->tex_end = fp->tex.length ? fp->tex.length - 1 : 0;
+ assert(fp->node[fp->cur_node].alu_end >= 0);
+ assert(fp->alu_end >= 0);
+
+ fp->translated = GL_TRUE;
+ if (RADEON_DEBUG & DEBUG_PIXEL)
+ dump_program(fp);
+ r300UpdateStateParameters(fp->ctx, _NEW_PROGRAM);
+ }
+
+ update_params(fp);
+}
+
+/* just some random things... */
+static void dump_program(struct r300_fragment_program *fp)
+{
+ int n, i, j;
+ static int pc = 0;
+
+ fprintf(stderr, "pc=%d*************************************\n", pc++);
+
+ fprintf(stderr, "Mesa program:\n");
+ fprintf(stderr, "-------------\n");
+ _mesa_print_program(&fp->mesa_program.Base);
+ fflush(stdout);
+
+ fprintf(stderr, "Hardware program\n");
+ fprintf(stderr, "----------------\n");
+
+ for (n = 0; n < (fp->cur_node + 1); n++) {
+ fprintf(stderr, "NODE %d: alu_offset: %d, tex_offset: %d, "
+ "alu_end: %d, tex_end: %d\n", n,
+ fp->node[n].alu_offset,
+ fp->node[n].tex_offset,
+ fp->node[n].alu_end, fp->node[n].tex_end);
+
+ if (fp->tex.length) {
+ fprintf(stderr, " TEX:\n");
+ for (i = fp->node[n].tex_offset;
+ i <= fp->node[n].tex_offset + fp->node[n].tex_end;
+ ++i) {
+ const char *instr;
+
+ switch ((fp->tex.
+ inst[i] >> R300_FPITX_OPCODE_SHIFT) &
+ 15) {
+ case R300_FPITX_OP_TEX:
+ instr = "TEX";
+ break;
+ case R300_FPITX_OP_KIL:
+ instr = "KIL";
+ break;
+ case R300_FPITX_OP_TXP:
+ instr = "TXP";
+ break;
+ case R300_FPITX_OP_TXB:
+ instr = "TXB";
+ break;
+ default:
+ instr = "UNKNOWN";
+ }
+
+ fprintf(stderr,
+ " %s t%i, %c%i, texture[%i] (%08x)\n",
+ instr,
+ (fp->tex.
+ inst[i] >> R300_FPITX_DST_SHIFT) & 31,
+ (fp->tex.
+ inst[i] & R300_FPITX_SRC_CONST) ? 'c' :
+ 't',
+ (fp->tex.
+ inst[i] >> R300_FPITX_SRC_SHIFT) & 31,
+ (fp->tex.
+ inst[i] & R300_FPITX_IMAGE_MASK) >>
+ R300_FPITX_IMAGE_SHIFT,
+ fp->tex.inst[i]);
+ }
+ }
+
+ for (i = fp->node[n].alu_offset;
+ i <= fp->node[n].alu_offset + fp->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 = fp->alu.inst[i].inst1 >> (j * 6);
+ int rega = fp->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",
+ (fp->alu.inst[i].
+ inst1 & R300_FPI1_DSTC_REG_X) ? "x" : "",
+ (fp->alu.inst[i].
+ inst1 & R300_FPI1_DSTC_REG_Y) ? "y" : "",
+ (fp->alu.inst[i].
+ inst1 & R300_FPI1_DSTC_REG_Z) ? "z" : "");
+ if (flags[0] != 0) {
+ sprintf(dstc, "t%i.%s ",
+ (fp->alu.inst[i].
+ inst1 >> R300_FPI1_DSTC_SHIFT) & 31,
+ flags);
+ }
+ sprintf(flags, "%s%s%s",
+ (fp->alu.inst[i].
+ inst1 & R300_FPI1_DSTC_OUTPUT_X) ? "x" : "",
+ (fp->alu.inst[i].
+ inst1 & R300_FPI1_DSTC_OUTPUT_Y) ? "y" : "",
+ (fp->alu.inst[i].
+ inst1 & R300_FPI1_DSTC_OUTPUT_Z) ? "z" : "");
+ if (flags[0] != 0) {
+ sprintf(tmp, "o%i.%s",
+ (fp->alu.inst[i].
+ inst1 >> R300_FPI1_DSTC_SHIFT) & 31,
+ flags);
+ strcat(dstc, tmp);
+ }
+
+ dsta[0] = 0;
+ if (fp->alu.inst[i].inst3 & R300_FPI3_DSTA_REG) {
+ sprintf(dsta, "t%i.w ",
+ (fp->alu.inst[i].
+ inst3 >> R300_FPI3_DSTA_SHIFT) & 31);
+ }
+ if (fp->alu.inst[i].inst3 & R300_FPI3_DSTA_OUTPUT) {
+ sprintf(tmp, "o%i.w ",
+ (fp->alu.inst[i].
+ inst3 >> R300_FPI3_DSTA_SHIFT) & 31);
+ strcat(dsta, tmp);
+ }
+ if (fp->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,
+ fp->alu.inst[i].inst1, srca[0], srca[1],
+ srca[2], dsta, fp->alu.inst[i].inst3);
+
+ for (j = 0; j < 3; ++j) {
+ int regc = fp->alu.inst[i].inst0 >> (j * 7);
+ int rega = fp->alu.inst[i].inst2 >> (j * 7);
+ int d;
+ char buf[20];
+
+ d = regc & 31;
+ if (d < 12) {
+ switch (d % 4) {
+ case R300_FPI0_ARGC_SRC0C_XYZ:
+ sprintf(buf, "%s.xyz",
+ srcc[d / 4]);
+ break;
+ case R300_FPI0_ARGC_SRC0C_XXX:
+ sprintf(buf, "%s.xxx",
+ srcc[d / 4]);
+ break;
+ case R300_FPI0_ARGC_SRC0C_YYY:
+ sprintf(buf, "%s.yyy",
+ srcc[d / 4]);
+ break;
+ case R300_FPI0_ARGC_SRC0C_ZZZ:
+ sprintf(buf, "%s.zzz",
+ srcc[d / 4]);
+ break;
+ }
+ } else if (d < 15) {
+ sprintf(buf, "%s.www", srca[d - 12]);
+ } else if (d == 20) {
+ sprintf(buf, "0.0");
+ } else if (d == 21) {
+ sprintf(buf, "1.0");
+ } else if (d == 22) {
+ sprintf(buf, "0.5");
+ } else if (d >= 23 && d < 32) {
+ d -= 23;
+ switch (d / 3) {
+ case 0:
+ sprintf(buf, "%s.yzx",
+ srcc[d % 3]);
+ break;
+ case 1:
+ sprintf(buf, "%s.zxy",
+ srcc[d % 3]);
+ break;
+ case 2:
+ sprintf(buf, "%s.Wzy",
+ srcc[d % 3]);
+ break;
+ }
+ } 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));
+ } else if (d < 12) {
+ sprintf(buf, "%s.w", srca[d - 9]);
+ } else if (d == 16) {
+ sprintf(buf, "0.0");
+ } else if (d == 17) {
+ sprintf(buf, "1.0");
+ } else if (d == 18) {
+ sprintf(buf, "0.5");
+ } 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],
+ fp->alu.inst[i].inst0, arga[0], arga[1],
+ arga[2], fp->alu.inst[i].inst2);
+ }
+ }
+}
diff --git a/src/mesa/drivers/dri/r300/r500_fragprog.h b/src/mesa/drivers/dri/r300/r500_fragprog.h
new file mode 100644
index 00000000000..72fca778455
--- /dev/null
+++ b/src/mesa/drivers/dri/r300/r500_fragprog.h
@@ -0,0 +1,104 @@
+/*
+ * Copyright (C) 2005 Ben Skeggs.
+ *
+ * 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 (including the
+ * next paragraph) 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 COPYRIGHT OWNER(S) AND/OR ITS SUPPLIERS 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:
+ * Ben Skeggs <[email protected]>
+ * Jerome Glisse <[email protected]>
+ */
+#ifndef __R300_FRAGPROG_H_
+#define __R300_FRAGPROG_H_
+
+#include "glheader.h"
+#include "macros.h"
+#include "enums.h"
+#include "shader/program.h"
+#include "shader/prog_instruction.h"
+
+#include "r300_context.h"
+
+typedef struct r300_fragment_program_swizzle {
+ GLuint length;
+ GLuint src[4];
+ GLuint inst[8];
+} r300_fragment_program_swizzle_t;
+
+/* supported hw opcodes */
+#define PFS_OP_MAD 0
+#define PFS_OP_DP3 1
+#define PFS_OP_DP4 2
+#define PFS_OP_MIN 3
+#define PFS_OP_MAX 4
+#define PFS_OP_CMP 5
+#define PFS_OP_FRC 6
+#define PFS_OP_EX2 7
+#define PFS_OP_LG2 8
+#define PFS_OP_RCP 9
+#define PFS_OP_RSQ 10
+#define PFS_OP_REPL_ALPHA 11
+#define PFS_OP_CMPH 12
+#define MAX_PFS_OP 12
+
+#define PFS_FLAG_SAT (1 << 0)
+#define PFS_FLAG_ABS (1 << 1)
+
+#define ARG_NEG (1 << 5)
+#define ARG_ABS (1 << 6)
+#define ARG_MASK (127 << 0)
+#define ARG_STRIDE 7
+#define SRC_CONST (1 << 5)
+#define SRC_MASK (63 << 0)
+#define SRC_STRIDE 6
+
+#define NOP_INST0 ( \
+ (R300_FPI0_OUTC_MAD) | \
+ (R300_FPI0_ARGC_ZERO << R300_FPI0_ARG0C_SHIFT) | \
+ (R300_FPI0_ARGC_ZERO << R300_FPI0_ARG1C_SHIFT) | \
+ (R300_FPI0_ARGC_ZERO << R300_FPI0_ARG2C_SHIFT))
+#define NOP_INST1 ( \
+ ((0 | SRC_CONST) << R300_FPI1_SRC0C_SHIFT) | \
+ ((0 | SRC_CONST) << R300_FPI1_SRC1C_SHIFT) | \
+ ((0 | SRC_CONST) << R300_FPI1_SRC2C_SHIFT))
+#define NOP_INST2 ( \
+ (R300_FPI2_OUTA_MAD) | \
+ (R300_FPI2_ARGA_ZERO << R300_FPI2_ARG0A_SHIFT) | \
+ (R300_FPI2_ARGA_ZERO << R300_FPI2_ARG1A_SHIFT) | \
+ (R300_FPI2_ARGA_ZERO << R300_FPI2_ARG2A_SHIFT))
+#define NOP_INST3 ( \
+ ((0 | SRC_CONST) << R300_FPI3_SRC0A_SHIFT) | \
+ ((0 | SRC_CONST) << R300_FPI3_SRC1A_SHIFT) | \
+ ((0 | SRC_CONST) << R300_FPI3_SRC2A_SHIFT))
+
+#define DRI_CONF_FP_OPTIMIZATION_SPEED 0
+#define DRI_CONF_FP_OPTIMIZATION_QUALITY 1
+
+struct r300_fragment_program;
+
+extern void r300TranslateFragmentShader(r300ContextPtr r300,
+ struct r300_fragment_program *fp);
+
+#endif