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/* $Id: m_norm_debug.c,v 1.1 2003-04-24 13:37:47 giacomo 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.
*
* Authors:
* Gareth Hughes
*/
#include "glheader.h"
#include "context.h"
#include "macros.h"
#include "imports.h"
#include "mmath.h"
#include "m_matrix.h"
#include "m_xform.h"
#include "m_debug.h"
#include "m_debug_util.h"
#ifdef DEBUG /* This code only used for debugging */
static int m_norm_identity
[16] = {
ONE
, NIL
, NIL
, NIL
,
NIL
, ONE
, NIL
, NIL
,
NIL
, NIL
, ONE
, NIL
,
NIL
, NIL
, NIL
, NIL
};
static int m_norm_general
[16] = {
VAR
, VAR
, VAR
, NIL
,
VAR
, VAR
, VAR
, NIL
,
VAR
, VAR
, VAR
, NIL
,
NIL
, NIL
, NIL
, NIL
};
static int m_norm_no_rot
[16] = {
VAR
, NIL
, NIL
, NIL
,
NIL
, VAR
, NIL
, NIL
,
NIL
, NIL
, VAR
, NIL
,
NIL
, NIL
, NIL
, NIL
};
static int *norm_templates
[8] = {
m_norm_no_rot
,
m_norm_no_rot
,
m_norm_no_rot
,
m_norm_general
,
m_norm_general
,
m_norm_general
,
m_norm_identity
,
m_norm_identity
};
static int norm_types
[8] = {
NORM_TRANSFORM_NO_ROT
,
NORM_TRANSFORM_NO_ROT
| NORM_RESCALE
,
NORM_TRANSFORM_NO_ROT
| NORM_NORMALIZE
,
NORM_TRANSFORM
,
NORM_TRANSFORM
| NORM_RESCALE
,
NORM_TRANSFORM
| NORM_NORMALIZE
,
NORM_RESCALE
,
NORM_NORMALIZE
};
static int norm_scale_types
[8] = { /* rescale factor */
NIL
, /* NIL disables rescaling */
VAR
,
NIL
,
NIL
,
VAR
,
NIL
,
VAR
,
NIL
};
static int norm_normalize_types
[8] = { /* normalizing ?? (no = 0) */
0,
0,
1,
0,
0,
1,
0,
1
};
static char *norm_strings
[8] = {
"NORM_TRANSFORM_NO_ROT",
"NORM_TRANSFORM_NO_ROT | NORM_RESCALE",
"NORM_TRANSFORM_NO_ROT | NORM_NORMALIZE",
"NORM_TRANSFORM",
"NORM_TRANSFORM | NORM_RESCALE",
"NORM_TRANSFORM | NORM_NORMALIZE",
"NORM_RESCALE",
"NORM_NORMALIZE"
};
/* =============================================================
* Reference transformations
*/
static void ref_norm_transform_rescale
( const GLmatrix
*mat
,
GLfloat scale
,
const GLvector4f
*in
,
const GLfloat
*lengths
,
GLvector4f
*dest
)
{
GLuint i
;
const GLfloat
*s
= in
->start
;
const GLfloat
*m
= mat
->inv
;
GLfloat
(*out
)[4] = (GLfloat
(*)[4]) dest
->start
;
(void) lengths
;
for ( i
= 0 ; i
< in
->count
; i
++ ) {
GLfloat t
[3];
TRANSFORM_NORMAL
( t
, s
, m
);
SCALE_SCALAR_3V
( out
[i
], scale
, t
);
s
= (GLfloat
*)((char *)s
+ in
->stride
);
}
}
static void ref_norm_transform_normalize
( const GLmatrix
*mat
,
GLfloat scale
,
const GLvector4f
*in
,
const GLfloat
*lengths
,
GLvector4f
*dest
)
{
GLuint i
;
const GLfloat
*s
= in
->start
;
const GLfloat
*m
= mat
->inv
;
GLfloat
(*out
)[4] = (GLfloat
(*)[4]) dest
->start
;
for ( i
= 0 ; i
< in
->count
; i
++ ) {
GLfloat t
[3];
TRANSFORM_NORMAL
( t
, s
, m
);
if ( !lengths
) {
GLfloat len
= LEN_SQUARED_3FV
( t
);
if ( len
> 1e-20 ) {
/* Hmmm, don't know how we could test the precalculated
* length case...
*/
scale
= 1.0 / sqrt( len
);
SCALE_SCALAR_3V
( out
[i
], scale
, t
);
} else {
out
[i
][0] = out
[i
][1] = out
[i
][2] = 0;
}
} else {
scale
= lengths
[i
];;
SCALE_SCALAR_3V
( out
[i
], scale
, t
);
}
s
= (GLfloat
*)((char *)s
+ in
->stride
);
}
}
/* =============================================================
* Normal transformation tests
*/
static void init_matrix
( GLfloat
*m
)
{
m
[0] = 63.0; m
[4] = 43.0; m
[ 8] = 29.0; m
[12] = 43.0;
m
[1] = 55.0; m
[5] = 17.0; m
[ 9] = 31.0; m
[13] = 7.0;
m
[2] = 44.0; m
[6] = 9.0; m
[10] = 7.0; m
[14] = 3.0;
m
[3] = 11.0; m
[7] = 23.0; m
[11] = 91.0; m
[15] = 9.0;
}
static int test_norm_function
( normal_func func
, int mtype
, long *cycles
)
{
GLvector4f source
[1], dest
[1], dest2
[1], ref
[1], ref2
[1];
GLmatrix mat
[1];
GLfloat s
[TEST_COUNT
][5], d
[TEST_COUNT
][4], r
[TEST_COUNT
][4];
GLfloat d2
[TEST_COUNT
][4], r2
[TEST_COUNT
][4], length
[TEST_COUNT
];
GLfloat scale
;
GLfloat
*m
;
int i
, j
;
#ifdef RUN_DEBUG_BENCHMARK
int cycle_i
; /* the counter for the benchmarks we run */
#endif
(void) cycles
;
mat
->m
= (GLfloat
*) ALIGN_MALLOC
( 16 * sizeof(GLfloat
), 16 );
mat
->inv
= m
= mat
->m
;
init_matrix
( m
);
scale
= 1.0F + rnd
() * norm_scale_types
[mtype
];
for ( i
= 0 ; i
< 4 ; i
++ ) {
for ( j
= 0 ; j
< 4 ; j
++ ) {
switch ( norm_templates
[mtype
][i
* 4 + j
] ) {
case NIL
:
m
[j
* 4 + i
] = 0.0;
break;
case ONE
:
m
[j
* 4 + i
] = 1.0;
break;
case NEG
:
m
[j
* 4 + i
] = -1.0;
break;
case VAR
:
break;
default:
abort();
}
}
}
for ( i
= 0 ; i
< TEST_COUNT
; i
++ ) {
ASSIGN_3V
( d
[i
], 0.0, 0.0, 0.0 );
ASSIGN_3V
( s
[i
], 0.0, 0.0, 0.0 );
ASSIGN_3V
( d2
[i
], 0.0, 0.0, 0.0 );
for ( j
= 0 ; j
< 3 ; j
++ )
s
[i
][j
] = rnd
();
length
[i
] = 1 / sqrt( LEN_SQUARED_3FV
( s
[i
] ) );
}
source
->data
= (GLfloat
(*)[4]) s
;
source
->start
= (GLfloat
*) s
;
source
->count
= TEST_COUNT
;
source
->stride
= sizeof(s
[0]);
source
->flags
= 0;
dest
->data
= d
;
dest
->start
= (GLfloat
*) d
;
dest
->count
= TEST_COUNT
;
dest
->stride
= sizeof(float[4]);
dest
->flags
= 0;
dest2
->data
= d2
;
dest2
->start
= (GLfloat
*) d2
;
dest2
->count
= TEST_COUNT
;
dest2
->stride
= sizeof(float[4]);
dest2
->flags
= 0;
ref
->data
= r
;
ref
->start
= (GLfloat
*) r
;
ref
->count
= TEST_COUNT
;
ref
->stride
= sizeof(float[4]);
ref
->flags
= 0;
ref2
->data
= r2
;
ref2
->start
= (GLfloat
*) r2
;
ref2
->count
= TEST_COUNT
;
ref2
->stride
= sizeof(float[4]);
ref2
->flags
= 0;
if ( norm_normalize_types
[mtype
] == 0 ) {
ref_norm_transform_rescale
( mat
, scale
, source
, NULL
, ref
);
} else {
ref_norm_transform_normalize
( mat
, scale
, source
, NULL
, ref
);
ref_norm_transform_normalize
( mat
, scale
, source
, length
, ref2
);
}
if ( mesa_profile
) {
BEGIN_RACE
( *cycles
);
func
( mat
, scale
, source
, NULL
, dest
);
END_RACE
( *cycles
);
func
( mat
, scale
, source
, length
, dest2
);
} else {
func
( mat
, scale
, source
, NULL
, dest
);
func
( mat
, scale
, source
, length
, dest2
);
}
for ( i
= 0 ; i
< TEST_COUNT
; i
++ ) {
for ( j
= 0 ; j
< 3 ; j
++ ) {
if ( significand_match
( d
[i
][j
], r
[i
][j
] ) < REQUIRED_PRECISION
) {
_mesa_printf
(NULL
, "-----------------------------\n" );
_mesa_printf
(NULL
, "(i = %i, j = %i)\n", i
, j
);
_mesa_printf
(NULL
, "%f \t %f \t [ratio = %e - %i bit missed]\n",
d
[i
][0], r
[i
][0], r
[i
][0]/d
[i
][0],
MAX_PRECISION
- significand_match
( d
[i
][0], r
[i
][0] ) );
_mesa_printf
(NULL
, "%f \t %f \t [ratio = %e - %i bit missed]\n",
d
[i
][1], r
[i
][1], r
[i
][1]/d
[i
][1],
MAX_PRECISION
- significand_match
( d
[i
][1], r
[i
][1] ) );
_mesa_printf
(NULL
, "%f \t %f \t [ratio = %e - %i bit missed]\n",
d
[i
][2], r
[i
][2], r
[i
][2]/d
[i
][2],
MAX_PRECISION
- significand_match
( d
[i
][2], r
[i
][2] ) );
return 0;
}
if ( norm_normalize_types
[mtype
] != 0 ) {
if ( significand_match
( d2
[i
][j
], r2
[i
][j
] ) < REQUIRED_PRECISION
) {
_mesa_printf
(NULL
, "------------------- precalculated length case ------\n" );
_mesa_printf
(NULL
, "(i = %i, j = %i)\n", i
, j
);
_mesa_printf
(NULL
, "%f \t %f \t [ratio = %e - %i bit missed]\n",
d2
[i
][0], r2
[i
][0], r2
[i
][0]/d2
[i
][0],
MAX_PRECISION
- significand_match
( d2
[i
][0], r2
[i
][0] ) );
_mesa_printf
(NULL
, "%f \t %f \t [ratio = %e - %i bit missed]\n",
d2
[i
][1], r2
[i
][1], r2
[i
][1]/d2
[i
][1],
MAX_PRECISION
- significand_match
( d2
[i
][1], r2
[i
][1] ) );
_mesa_printf
(NULL
, "%f \t %f \t [ratio = %e - %i bit missed]\n",
d2
[i
][2], r2
[i
][2], r2
[i
][2]/d2
[i
][2],
MAX_PRECISION
- significand_match
( d2
[i
][2], r2
[i
][2] ) );
return 0;
}
}
}
}
ALIGN_FREE
( mat
->m
);
return 1;
}
void _math_test_all_normal_transform_functions
( char *description
)
{
int mtype
;
long benchmark_tab
[0xf];
static int first_time
= 1;
if ( first_time
) {
first_time
= 0;
mesa_profile
= getenv( "MESA_PROFILE" );
}
#ifdef RUN_DEBUG_BENCHMARK
if ( mesa_profile
) {
if ( !counter_overhead
) {
INIT_COUNTER
();
_mesa_printf
(NULL
, "counter overhead: %ld cycles\n\n", counter_overhead
);
}
_mesa_printf
(NULL
, "normal transform results after hooking in %s functions:\n",
description
);
_mesa_printf
(NULL
, "\n-------------------------------------------------------\n" );
}
#endif
for ( mtype
= 0 ; mtype
< 8 ; mtype
++ ) {
normal_func func
= _mesa_normal_tab
[norm_types
[mtype
]];
long *cycles
= &benchmark_tab
[mtype
];
if ( test_norm_function
( func
, mtype
, cycles
) == 0 ) {
char buf
[100];
_mesa_sprintf
(NULL
, buf
, "_mesa_normal_tab[0][%s] failed test (%s)",
norm_strings
[mtype
], description
);
_mesa_problem
( NULL
, buf
);
}
#ifdef RUN_DEBUG_BENCHMARK
if ( mesa_profile
) {
_mesa_printf
(NULL
, " %li\t", benchmark_tab
[mtype
] );
_mesa_printf
(NULL
, " | [%s]\n", norm_strings
[mtype
] );
}
#endif
}
#ifdef RUN_DEBUG_BENCHMARK
if ( mesa_profile
) {
_mesa_printf
(NULL
, "\n" );
fflush( stdout
);
}
#endif
}
#endif /* DEBUG */