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/* $Id: vpexec.c,v 1.1 2003-02-28 11:42:06 pj Exp $ */
/*
* Mesa 3-D graphics library
* Version: 4.1
*
* Copyright (C) 1999-2002 Brian Paul All Rights Reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* BRIAN PAUL 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.
*/
/*
* -------- Regarding NV_vertex_program --------
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* o Redistribution of the source code must contain a copyright notice
* and this list of conditions;
*
* o Redistribution in binary and source code form must contain the
* following Notice in the software and any documentation and/or other
* materials provided with the distribution; and
*
* o The name of Nvidia may not be used to promote or endorse software
* derived from the software.
*
* NOTICE: Nvidia hereby grants to each recipient a non-exclusive worldwide
* royalty free patent license under patent claims that are licensable by
* Nvidia and which are necessarily required and for which no commercially
* viable non infringing alternative exists to make, use, sell, offer to sell,
* import and otherwise transfer the vertex extension for the Mesa 3D Graphics
* Library as distributed in source code and object code form. No hardware or
* hardware implementation (including a semiconductor implementation and chips)
* are licensed hereunder. If a recipient makes a patent claim or institutes
* patent litigation against Nvidia or Nvidia's customers for use or sale of
* Nvidia products, then this license grant as to such recipient shall
* immediately terminate and recipient immediately agrees to cease use and
* distribution of the Mesa Program and derivatives thereof.
*
* THE MESA 3D GRAPHICS LIBRARY IS PROVIDED ON AN "AS IS BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED INCLUDING,
* WITHOUT LIMITATION, ANY WARRANTIES OR CONDITIONS OF TITLE, NON-NFRINGEMENT
* MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
*
* NVIDIA SHALL NOT HAVE ANY LIABILITY FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING WITHOUT LIMITATION
* LOST PROFITS), HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OR DISTRIBUTION OF THE MESA 3D GRAPHICS
* LIBRARY OR EVIDENCE OR THE EXERCISE OF ANY RIGHTS GRANTED HEREUNDR, EVEN
* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* If you do not comply with this agreement, then Nvidia may cancel the license
* and rights granted herein.
* ---------------------------------------------
*/
/**
* \file vpexec.c
* \brief Code to execute vertex programs.
* \author Brian Paul
*/
#include "glheader.h"
#include "context.h"
#include "imports.h"
#include "macros.h"
#include "mtypes.h"
#include "vpexec.h"
#include "mmath.h"
#include "math/m_matrix.h"
/**
* Load/initialize the vertex program registers.
* This needs to be done per vertex.
*/
void
_mesa_init_vp_registers
(GLcontext
*ctx
)
{
struct vp_machine
*machine
= &(ctx
->VertexProgram.
Machine);
GLuint i
;
/* Input registers get initialized from the current vertex attribs */
MEMCPY
(machine
->Registers
[VP_INPUT_REG_START
],
ctx
->Current.
Attrib,
16 * 4 * sizeof(GLfloat
));
/* Output and temp regs are initialized to [0,0,0,1] */
for (i
= VP_OUTPUT_REG_START
; i
<= VP_OUTPUT_REG_END
; i
++) {
machine
->Registers
[i
][0] = 0.0F;
machine
->Registers
[i
][1] = 0.0F;
machine
->Registers
[i
][2] = 0.0F;
machine
->Registers
[i
][3] = 1.0F;
}
for (i
= VP_TEMP_REG_START
; i
<= VP_TEMP_REG_END
; i
++) {
machine
->Registers
[i
][0] = 0.0F;
machine
->Registers
[i
][1] = 0.0F;
machine
->Registers
[i
][2] = 0.0F;
machine
->Registers
[i
][3] = 1.0F;
}
/* The program regs aren't touched */
}
/**
* Copy the 16 elements of a matrix into four consecutive program
* registers starting at 'pos'.
*/
static void
load_matrix
(GLfloat registers
[][4], GLuint pos
, const GLfloat mat
[16])
{
GLuint i
;
pos
+= VP_PROG_REG_START
;
for (i
= 0; i
< 4; i
++) {
registers
[pos
+ i
][0] = mat
[0 + i
];
registers
[pos
+ i
][1] = mat
[4 + i
];
registers
[pos
+ i
][2] = mat
[8 + i
];
registers
[pos
+ i
][3] = mat
[12 + i
];
}
}
/**
* As above, but transpose the matrix.
*/
static void
load_transpose_matrix
(GLfloat registers
[][4], GLuint pos
,
const GLfloat mat
[16])
{
pos
+= VP_PROG_REG_START
;
MEMCPY
(registers
[pos
], mat
, 16 * sizeof(GLfloat
));
}
/**
* Load all currently tracked matrices into the program registers.
* This needs to be done per glBegin/glEnd.
*/
void
_mesa_init_tracked_matrices
(GLcontext
*ctx
)
{
GLuint i
;
for (i
= 0; i
< VP_NUM_PROG_REGS
/ 4; i
++) {
/* point 'mat' at source matrix */
GLmatrix
*mat
;
if (ctx
->VertexProgram.
TrackMatrix[i
] == GL_MODELVIEW
) {
mat
= ctx
->ModelviewMatrixStack.
Top;
}
else if (ctx
->VertexProgram.
TrackMatrix[i
] == GL_PROJECTION
) {
mat
= ctx
->ProjectionMatrixStack.
Top;
}
else if (ctx
->VertexProgram.
TrackMatrix[i
] == GL_TEXTURE
) {
mat
= ctx
->TextureMatrixStack
[ctx
->Texture.
CurrentUnit].
Top;
}
else if (ctx
->VertexProgram.
TrackMatrix[i
] == GL_COLOR
) {
mat
= ctx
->ColorMatrixStack.
Top;
}
else if (ctx
->VertexProgram.
TrackMatrix[i
]==GL_MODELVIEW_PROJECTION_NV
) {
/* XXX verify the combined matrix is up to date */
mat
= &ctx
->_ModelProjectMatrix
;
}
else if (ctx
->VertexProgram.
TrackMatrix[i
] >= GL_MATRIX0_NV
&&
ctx
->VertexProgram.
TrackMatrix[i
] <= GL_MATRIX7_NV
) {
GLuint n
= ctx
->VertexProgram.
TrackMatrix[i
] - GL_MATRIX0_NV
;
ASSERT
(n
< MAX_PROGRAM_MATRICES
);
mat
= ctx
->ProgramMatrixStack
[n
].
Top;
}
else {
/* no matrix is tracked, but we leave the register values as-is */
assert(ctx
->VertexProgram.
TrackMatrix[i
] == GL_NONE
);
continue;
}
/* load the matrix */
if (ctx
->VertexProgram.
TrackMatrixTransform[i
] == GL_IDENTITY_NV
) {
load_matrix
(ctx
->VertexProgram.
Machine.
Registers, i
*4, mat
->m
);
}
else if (ctx
->VertexProgram.
TrackMatrixTransform[i
] == GL_INVERSE_NV
) {
_math_matrix_analyse
(mat
); /* update the inverse */
assert((mat
->flags
& MAT_DIRTY_INVERSE
) == 0);
load_matrix
(ctx
->VertexProgram.
Machine.
Registers, i
*4, mat
->inv
);
}
else if (ctx
->VertexProgram.
TrackMatrixTransform[i
] == GL_TRANSPOSE_NV
) {
load_transpose_matrix
(ctx
->VertexProgram.
Machine.
Registers, i
*4, mat
->m
);
}
else {
assert(ctx
->VertexProgram.
TrackMatrixTransform[i
]
== GL_INVERSE_TRANSPOSE_NV
);
_math_matrix_analyse
(mat
); /* update the inverse */
assert((mat
->flags
& MAT_DIRTY_INVERSE
) == 0);
load_transpose_matrix
(ctx
->VertexProgram.
Machine.
Registers,
i
*4, mat
->inv
);
}
}
}
/**
* For debugging. Dump the current vertex program machine registers.
*/
void
_mesa_dump_vp_machine
( const struct vp_machine
*machine
)
{
int i
;
_mesa_printf
("VertexIn:\n");
for (i
= 0; i
< VP_NUM_INPUT_REGS
; i
++) {
_mesa_printf
("%d: %f %f %f %f ", i
,
machine
->Registers
[i
+ VP_INPUT_REG_START
][0],
machine
->Registers
[i
+ VP_INPUT_REG_START
][1],
machine
->Registers
[i
+ VP_INPUT_REG_START
][2],
machine
->Registers
[i
+ VP_INPUT_REG_START
][3]);
}
_mesa_printf
("\n");
_mesa_printf
("VertexOut:\n");
for (i
= 0; i
< VP_NUM_OUTPUT_REGS
; i
++) {
_mesa_printf
("%d: %f %f %f %f ", i
,
machine
->Registers
[i
+ VP_OUTPUT_REG_START
][0],
machine
->Registers
[i
+ VP_OUTPUT_REG_START
][1],
machine
->Registers
[i
+ VP_OUTPUT_REG_START
][2],
machine
->Registers
[i
+ VP_OUTPUT_REG_START
][3]);
}
_mesa_printf
("\n");
_mesa_printf
("Registers:\n");
for (i
= 0; i
< VP_NUM_TEMP_REGS
; i
++) {
_mesa_printf
("%d: %f %f %f %f ", i
,
machine
->Registers
[i
+ VP_TEMP_REG_START
][0],
machine
->Registers
[i
+ VP_TEMP_REG_START
][1],
machine
->Registers
[i
+ VP_TEMP_REG_START
][2],
machine
->Registers
[i
+ VP_TEMP_REG_START
][3]);
}
_mesa_printf
("\n");
_mesa_printf
("Parameters:\n");
for (i
= 0; i
< VP_NUM_PROG_REGS
; i
++) {
_mesa_printf
("%d: %f %f %f %f ", i
,
machine
->Registers
[i
+ VP_PROG_REG_START
][0],
machine
->Registers
[i
+ VP_PROG_REG_START
][1],
machine
->Registers
[i
+ VP_PROG_REG_START
][2],
machine
->Registers
[i
+ VP_PROG_REG_START
][3]);
}
_mesa_printf
("\n");
}
/**
* Fetch a 4-element float vector from the given source register.
* Apply swizzling and negating as needed.
*/
static void
fetch_vector4
( const struct vp_src_register
*source
,
const struct vp_machine
*machine
,
GLfloat result
[4] )
{
static const GLfloat zero
[4] = { 0, 0, 0, 0 };
const GLfloat
*src
;
if (source
->RelAddr
) {
GLint reg
= source
->Register
+ machine
->AddressReg
;
if (reg
< VP_PROG_REG_START
|| reg
> VP_PROG_REG_END
)
src
= zero
;
else
src
= machine
->Registers
[reg
];
}
else {
src
= machine
->Registers
[source
->Register
];
}
if (source
->Negate
) {
result
[0] = -src
[source
->Swizzle
[0]];
result
[1] = -src
[source
->Swizzle
[1]];
result
[2] = -src
[source
->Swizzle
[2]];
result
[3] = -src
[source
->Swizzle
[3]];
}
else {
result
[0] = src
[source
->Swizzle
[0]];
result
[1] = src
[source
->Swizzle
[1]];
result
[2] = src
[source
->Swizzle
[2]];
result
[3] = src
[source
->Swizzle
[3]];
}
}
/**
* As above, but only return result[0] element.
*/
static void
fetch_vector1
( const struct vp_src_register
*source
,
const struct vp_machine
*machine
,
GLfloat result
[4] )
{
static const GLfloat zero
[4] = { 0, 0, 0, 0 };
const GLfloat
*src
;
if (source
->RelAddr
) {
GLint reg
= source
->Register
+ machine
->AddressReg
;
if (reg
< VP_PROG_REG_START
|| reg
> VP_PROG_REG_END
)
src
= zero
;
else
src
= machine
->Registers
[reg
];
}
else {
src
= machine
->Registers
[source
->Register
];
}
if (source
->Negate
) {
result
[0] = -src
[source
->Swizzle
[0]];
}
else {
result
[0] = src
[source
->Swizzle
[0]];
}
}
/**
* Store 4 floats into a register.
*/
static void
store_vector4
( const struct vp_dst_register
*dest
, struct vp_machine
*machine
,
const GLfloat value
[4] )
{
GLfloat
*dst
= machine
->Registers
[dest
->Register
];
if (dest
->WriteMask
[0])
dst
[0] = value
[0];
if (dest
->WriteMask
[1])
dst
[1] = value
[1];
if (dest
->WriteMask
[2])
dst
[2] = value
[2];
if (dest
->WriteMask
[3])
dst
[3] = value
[3];
}
/**
* Set x to positive or negative infinity.
*/
#ifdef USE_IEEE
#define SET_POS_INFINITY(x) ( *((GLuint *) &x) = 0x7F800000 )
#define SET_NEG_INFINITY(x) ( *((GLuint *) &x) = 0xFF800000 )
#elif defined(VMS)
#define SET_POS_INFINITY(x) x = __MAXFLOAT
#define SET_NEG_INFINITY(x) x = -__MAXFLOAT
#else
#define SET_POS_INFINITY(x) x = (GLfloat) HUGE_VAL
#define SET_NEG_INFINITY(x) x = (GLfloat) -HUGE_VAL
#endif
#define SET_FLOAT_BITS(x, bits) ((fi_type *) &(x))->i = bits
/**
* Execute the given vertex program
*/
void
_mesa_exec_program
(GLcontext
*ctx
, const struct vp_program
*program
)
{
struct vp_machine
*machine
= &ctx
->VertexProgram.
Machine;
const struct vp_instruction
*inst
;
/* XXX load vertex fields into input registers */
/* and do other initialization */
for (inst
= program
->Instructions
; inst
->Opcode
!=END
; inst
++) {
switch (inst
->Opcode
) {
case MOV
:
{
GLfloat t
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
store_vector4
( &inst
->DstReg
, machine
, t
);
}
break;
case LIT
:
{
const GLfloat epsilon
= 1.0e
-5F
; /* XXX fix? */
GLfloat t
[4], lit
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
if (t
[3] < -(128.0F - epsilon
))
t
[3] = - (128.0F - epsilon
);
else if (t
[3] > 128.0F - epsilon
)
t
[3] = 128.0F - epsilon
;
if (t
[0] < 0.0)
t
[0] = 0.0;
if (t
[1] < 0.0)
t
[1] = 0.0;
lit
[0] = 1.0;
lit
[1] = t
[0];
lit
[2] = (t
[0] > 0.0) ? (GLfloat
) exp(t
[3] * log(t
[1])) : 0.0F;
lit
[3] = 1.0;
store_vector4
( &inst
->DstReg
, machine
, lit
);
}
break;
case RCP
:
{
GLfloat t
[4];
fetch_vector1
( &inst
->SrcReg
[0], machine
, t
);
if (t
[0] != 1.0F)
t
[0] = 1.0F / t
[0]; /* div by zero is infinity! */
t
[1] = t
[2] = t
[3] = t
[0];
store_vector4
( &inst
->DstReg
, machine
, t
);
}
break;
case RSQ
:
{
GLfloat t
[4];
fetch_vector1
( &inst
->SrcReg
[0], machine
, t
);
t
[0] = (float) (1.0 / sqrt(fabs(t
[0])));
t
[1] = t
[2] = t
[3] = t
[0];
store_vector4
( &inst
->DstReg
, machine
, t
);
}
break;
case EXP
:
{
GLfloat t
[4], q
[4], floor_t0
;
fetch_vector1
( &inst
->SrcReg
[0], machine
, t
);
floor_t0
= (float) floor(t
[0]);
if (floor_t0
> FLT_MAX_EXP
) {
SET_POS_INFINITY
(q
[0]);
q
[1] = 0.0F;
SET_POS_INFINITY
(q
[2]);
q
[3] = 1.0F;
}
else if (floor_t0
< FLT_MIN_EXP
) {
q
[0] = 0.0F;
q
[1] = 0.0F;
q
[2] = 0.0F;
q
[3] = 0.0F;
}
else {
#ifdef USE_IEEE
GLint ii
= (GLint
) floor_t0
;
ii
= (ii
< 23) + 0x3f800000;
SET_FLOAT_BITS
(q
[0], ii
);
q
[0] = *((GLfloat
*) &ii
);
#else
q
[0] = (GLfloat
) pow(2.0, floor_t0
);
#endif
q
[1] = t
[0] - floor_t0
;
q
[2] = (GLfloat
) (q
[0] * LOG2
(q
[1]));
q
[3] = 1.0F;
}
store_vector4
( &inst
->DstReg
, machine
, t
);
}
break;
case LOG
:
{
GLfloat t
[4], q
[4], abs_t0
;
fetch_vector1
( &inst
->SrcReg
[0], machine
, t
);
abs_t0
= (GLfloat
) fabs(t
[0]);
if (abs_t0
!= 0.0F) {
/* Since we really can't handle infinite values on VMS
* like other OSes we'll use __MAXFLOAT to represent
* infinity. This may need some tweaking.
*/
#ifdef VMS
if (abs_t0
== __MAXFLOAT
) {
#else
if (IS_INF_OR_NAN
(abs_t0
)) {
#endif
SET_POS_INFINITY
(q
[0]);
q
[1] = 1.0F;
SET_POS_INFINITY
(q
[2]);
}
else {
int exponent
;
double mantissa
= frexp(t
[0], &exponent
);
q
[0] = (GLfloat
) (exponent
- 1);
q
[1] = (GLfloat
) (2.0 * mantissa
); /* map [.5, 1) -> [1, 2) */
q
[2] = (GLfloat
) (q
[0] + LOG2
(q
[1]));
}
}
else {
SET_NEG_INFINITY
(q
[0]);
q
[1] = 1.0F;
SET_NEG_INFINITY
(q
[2]);
}
q
[3] = 1.0;
store_vector4
( &inst
->DstReg
, machine
, q
);
}
break;
case MUL
:
{
GLfloat t
[4], u
[4], prod
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
prod
[0] = t
[0] * u
[0];
prod
[1] = t
[1] * u
[1];
prod
[2] = t
[2] * u
[2];
prod
[3] = t
[3] * u
[3];
store_vector4
( &inst
->DstReg
, machine
, prod
);
}
break;
case ADD
:
{
GLfloat t
[4], u
[4], sum
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
sum
[0] = t
[0] + u
[0];
sum
[1] = t
[1] + u
[1];
sum
[2] = t
[2] + u
[2];
sum
[3] = t
[3] + u
[3];
store_vector4
( &inst
->DstReg
, machine
, sum
);
}
break;
case DP3
:
{
GLfloat t
[4], u
[4], dot
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
dot
[0] = t
[0] * u
[0] + t
[1] * u
[1] + t
[2] * u
[2];
dot
[1] = dot
[2] = dot
[3] = dot
[0];
store_vector4
( &inst
->DstReg
, machine
, dot
);
}
break;
case DP4
:
{
GLfloat t
[4], u
[4], dot
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
dot
[0] = t
[0] * u
[0] + t
[1] * u
[1] + t
[2] * u
[2] + t
[3] * u
[3];
dot
[1] = dot
[2] = dot
[3] = dot
[0];
store_vector4
( &inst
->DstReg
, machine
, dot
);
}
break;
case DST
:
{
GLfloat t
[4], u
[4], dst
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
dst
[0] = 1.0F;
dst
[1] = t
[1] * u
[1];
dst
[2] = t
[2];
dst
[3] = u
[3];
store_vector4
( &inst
->DstReg
, machine
, dst
);
}
break;
case MIN
:
{
GLfloat t
[4], u
[4], min
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
min
[0] = (t
[0] < u
[0]) ? t
[0] : u
[0];
min
[1] = (t
[1] < u
[1]) ? t
[1] : u
[1];
min
[2] = (t
[2] < u
[2]) ? t
[2] : u
[2];
min
[3] = (t
[3] < u
[3]) ? t
[3] : u
[3];
store_vector4
( &inst
->DstReg
, machine
, min
);
}
break;
case MAX
:
{
GLfloat t
[4], u
[4], max
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
max
[0] = (t
[0] > u
[0]) ? t
[0] : u
[0];
max
[1] = (t
[1] > u
[1]) ? t
[1] : u
[1];
max
[2] = (t
[2] > u
[2]) ? t
[2] : u
[2];
max
[3] = (t
[3] > u
[3]) ? t
[3] : u
[3];
store_vector4
( &inst
->DstReg
, machine
, max
);
}
break;
case SLT
:
{
GLfloat t
[4], u
[4], slt
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
slt
[0] = (t
[0] < u
[0]) ? 1.0F : 0.0F;
slt
[1] = (t
[1] < u
[1]) ? 1.0F : 0.0F;
slt
[2] = (t
[2] < u
[2]) ? 1.0F : 0.0F;
slt
[3] = (t
[3] < u
[3]) ? 1.0F : 0.0F;
store_vector4
( &inst
->DstReg
, machine
, slt
);
}
break;
case SGE
:
{
GLfloat t
[4], u
[4], sge
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
sge
[0] = (t
[0] >= u
[0]) ? 1.0F : 0.0F;
sge
[1] = (t
[1] >= u
[1]) ? 1.0F : 0.0F;
sge
[2] = (t
[2] >= u
[2]) ? 1.0F : 0.0F;
sge
[3] = (t
[3] >= u
[3]) ? 1.0F : 0.0F;
store_vector4
( &inst
->DstReg
, machine
, sge
);
}
break;
case MAD
:
{
GLfloat t
[4], u
[4], v
[4], sum
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
fetch_vector4
( &inst
->SrcReg
[2], machine
, v
);
sum
[0] = t
[0] * u
[0] + v
[0];
sum
[1] = t
[1] * u
[1] + v
[1];
sum
[2] = t
[2] * u
[2] + v
[2];
sum
[3] = t
[3] * u
[3] + v
[3];
store_vector4
( &inst
->DstReg
, machine
, sum
);
}
break;
case ARL
:
{
GLfloat t
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
machine
->AddressReg
= (GLint
) floor(t
[0]);
}
break;
case DPH
:
{
GLfloat t
[4], u
[4], dot
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
dot
[0] = t
[0] * u
[0] + t
[1] * u
[1] + t
[2] * u
[2] + u
[3];
dot
[1] = dot
[2] = dot
[3] = dot
[0];
store_vector4
( &inst
->DstReg
, machine
, dot
);
}
break;
case RCC
:
{
GLfloat t
[4], u
;
fetch_vector1
( &inst
->SrcReg
[0], machine
, t
);
if (t
[0] == 1.0F)
u
= 1.0F;
else
u
= 1.0F / t
[0];
if (u
> 0.0F) {
if (u
> 1.884467e
+019F
) {
u
= 1.884467e
+019F
; /* IEEE 32-bit binary value 0x5F800000 */
}
else if (u
< 5.42101e
-020F
) {
u
= 5.42101e
-020F
; /* IEEE 32-bit binary value 0x1F800000 */
}
}
else {
if (u
< -1.884467e
+019F
) {
u
= -1.884467e
+019F
; /* IEEE 32-bit binary value 0xDF800000 */
}
else if (u
> -5.42101e
-020F
) {
u
= -5.42101e
-020F
; /* IEEE 32-bit binary value 0x9F800000 */
}
}
t
[0] = t
[1] = t
[2] = t
[3] = u
;
store_vector4
( &inst
->DstReg
, machine
, t
);
}
break;
case SUB
:
{
GLfloat t
[4], u
[4], sum
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
fetch_vector4
( &inst
->SrcReg
[1], machine
, u
);
sum
[0] = t
[0] - u
[0];
sum
[1] = t
[1] - u
[1];
sum
[2] = t
[2] - u
[2];
sum
[3] = t
[3] - u
[3];
store_vector4
( &inst
->DstReg
, machine
, sum
);
}
break;
case ABS
:
{
GLfloat t
[4];
fetch_vector4
( &inst
->SrcReg
[0], machine
, t
);
if (t
[0] < 0.0) t
[0] = -t
[0];
if (t
[1] < 0.0) t
[1] = -t
[1];
if (t
[2] < 0.0) t
[2] = -t
[2];
if (t
[3] < 0.0) t
[3] = -t
[3];
store_vector4
( &inst
->DstReg
, machine
, t
);
}
break;
case END
:
return;
default:
/* bad instruction opcode */
_mesa_problem
(ctx
, "Bad VP Opcode in _mesa_exec_program");
return;
}
}
}
/**
Thoughts on vertex program optimization:
The obvious thing to do is to compile the vertex program into X86/SSE/3DNow!
assembly code. That will probably be a lot of work.
Another approach might be to replace the vp_instruction->Opcode field with
a pointer to a specialized C function which executes the instruction.
In particular we can write functions which skip swizzling, negating,
masking, relative addressing, etc. when they're not needed.
For example:
void simple_add( struct vp_instruction *inst )
{
GLfloat *sum = machine->Registers[inst->DstReg.Register];
GLfloat *a = machine->Registers[inst->SrcReg[0].Register];
GLfloat *b = machine->Registers[inst->SrcReg[1].Register];
sum[0] = a[0] + b[0];
sum[1] = a[1] + b[1];
sum[2] = a[2] + b[2];
sum[3] = a[3] + b[3];
}
*/
/*
KW:
A first step would be to 'vectorize' the programs in the same way as
the normal transformation code in the tnl module. Thus each opcode
takes zero or more input vectors (registers) and produces one or more
output vectors.
These operations would intially be coded in C, with machine-specific
assembly following, as is currently the case for matrix
transformations in the math/ directory. The preprocessing scheme for
selecting simpler operations Brian describes above would also work
here.
This should give reasonable performance without excessive effort.
*/