/* * Mesa 3-D graphics library * Version: 6.1 * * Copyright (C) 1999-2004 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. */ /* * Updated for P6 architecture by Gareth Hughes. */ #include "glheader.h" #include "context.h" #include "macros.h" #include "imports.h" #include "m_matrix.h" #include "m_xform.h" #include "m_debug.h" #include "m_debug_util.h" #ifdef __UNIXOS2__ /* The linker doesn't like empty files */ static char dummy; #endif #ifdef DEBUG_MATH /* This code only used for debugging */ /* Overhead of profiling counter in cycles. Automatically adjusted to * your machine at run time - counter initialization should give very * consistent results. */ long counter_overhead = 0; /* This is the value of the environment variable MESA_PROFILE, and is * used to determine if we should benchmark the functions as well as * verify their correctness. */ char *mesa_profile = NULL; static int m_general[16] = { VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR }; static int m_identity[16] = { ONE, NIL, NIL, NIL, NIL, ONE, NIL, NIL, NIL, NIL, ONE, NIL, NIL, NIL, NIL, ONE }; static int m_2d[16] = { VAR, VAR, NIL, VAR, VAR, VAR, NIL, VAR, NIL, NIL, ONE, NIL, NIL, NIL, NIL, ONE }; static int m_2d_no_rot[16] = { VAR, NIL, NIL, VAR, NIL, VAR, NIL, VAR, NIL, NIL, ONE, NIL, NIL, NIL, NIL, ONE }; static int m_3d[16] = { VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, VAR, NIL, NIL, NIL, ONE }; static int m_3d_no_rot[16] = { VAR, NIL, NIL, VAR, NIL, VAR, NIL, VAR, NIL, NIL, VAR, VAR, NIL, NIL, NIL, ONE }; static int m_perspective[16] = { VAR, NIL, VAR, NIL, NIL, VAR, VAR, NIL, NIL, NIL, VAR, VAR, NIL, NIL, NEG, NIL }; static int *templates[7] = { m_general, m_identity, m_3d_no_rot, m_perspective, m_2d, m_2d_no_rot, m_3d }; static enum GLmatrixtype mtypes[7] = { MATRIX_GENERAL, MATRIX_IDENTITY, MATRIX_3D_NO_ROT, MATRIX_PERSPECTIVE, MATRIX_2D, MATRIX_2D_NO_ROT, MATRIX_3D }; static char *mstrings[7] = { "MATRIX_GENERAL", "MATRIX_IDENTITY", "MATRIX_3D_NO_ROT", "MATRIX_PERSPECTIVE", "MATRIX_2D", "MATRIX_2D_NO_ROT", "MATRIX_3D" }; /* ============================================================= * Reference transformations */ static void ref_transform( GLvector4f *dst, const GLmatrix *mat, const GLvector4f *src ) { GLuint i; GLfloat *s = (GLfloat *)src->start; GLfloat (*d)[4] = (GLfloat (*)[4])dst->start; const GLfloat *m = mat->m; for ( i = 0 ; i < src->count ; i++ ) { TRANSFORM_POINT( d[i], m, s ); s = (GLfloat *)((char *)s + src->stride); } } /* ============================================================= * Vertex 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; } ALIGN16(static GLfloat, s[TEST_COUNT][4]); ALIGN16(static GLfloat, d[TEST_COUNT][4]); ALIGN16(static GLfloat, r[TEST_COUNT][4]); static int test_transform_function( transform_func func, int psize, int mtype, unsigned long *cycles ) { GLvector4f source[1], dest[1], ref[1]; GLmatrix mat[1]; GLfloat *m; int i, j; #ifdef RUN_DEBUG_BENCHMARK int cycle_i; /* the counter for the benchmarks we run */ #endif (void) cycles; if ( psize > 4 ) { _mesa_problem( NULL, "test_transform_function called with psize > 4\n" ); return 0; } mat->m = (GLfloat *) ALIGN_MALLOC( 16 * sizeof(GLfloat), 16 ); mat->type = mtypes[mtype]; m = mat->m; ASSERT( ((long)m & 15) == 0 ); init_matrix( m ); for ( i = 0 ; i < 4 ; i++ ) { for ( j = 0 ; j < 4 ; j++ ) { switch ( 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_4V( d[i], 0.0, 0.0, 0.0, 1.0 ); ASSIGN_4V( s[i], 0.0, 0.0, 0.0, 1.0 ); for ( j = 0 ; j < psize ; j++ ) s[i][j] = rnd(); } source->data = (GLfloat(*)[4])s; source->start = (GLfloat *)s; source->count = TEST_COUNT; source->stride = sizeof(s[0]); source->size = 4; source->flags = 0; dest->data = (GLfloat(*)[4])d; dest->start = (GLfloat *)d; dest->count = TEST_COUNT; dest->stride = sizeof(float[4]); dest->size = 0; dest->flags = 0; ref->data = (GLfloat(*)[4])r; ref->start = (GLfloat *)r; ref->count = TEST_COUNT; ref->stride = sizeof(float[4]); ref->size = 0; ref->flags = 0; ref_transform( ref, mat, source ); if ( mesa_profile ) { BEGIN_RACE( *cycles ); func( dest, mat->m, source ); END_RACE( *cycles ); } else { func( dest, mat->m, source ); } for ( i = 0 ; i < TEST_COUNT ; i++ ) { for ( j = 0 ; j < 4 ; j++ ) { if ( significand_match( d[i][j], r[i][j] ) < REQUIRED_PRECISION ) { _mesa_printf("-----------------------------\n" ); _mesa_printf("(i = %i, j = %i)\n", i, j ); _mesa_printf("%f \t %f \t [diff = %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("%f \t %f \t [diff = %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("%f \t %f \t [diff = %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] ) ); _mesa_printf("%f \t %f \t [diff = %e - %i bit missed]\n", d[i][3], r[i][3], r[i][3]-d[i][3], MAX_PRECISION - significand_match( d[i][3], r[i][3] ) ); return 0; } } } ALIGN_FREE( mat->m ); return 1; } void _math_test_all_transform_functions( char *description ) { int psize, mtype; unsigned long benchmark_tab[4][7]; static int first_time = 1; if ( first_time ) { first_time = 0; mesa_profile = _mesa_getenv( "MESA_PROFILE" ); } #ifdef RUN_DEBUG_BENCHMARK if ( mesa_profile ) { if ( !counter_overhead ) { INIT_COUNTER(); _mesa_printf("counter overhead: %lu cycles\n\n", counter_overhead ); } _mesa_printf("transform results after hooking in %s functions:\n", description ); } #endif #ifdef RUN_DEBUG_BENCHMARK if ( mesa_profile ) { _mesa_printf("\n" ); for ( psize = 1 ; psize <= 4 ; psize++ ) { _mesa_printf(" p%d\t", psize ); } _mesa_printf("\n--------------------------------------------------------\n" ); } #endif for ( mtype = 0 ; mtype < 7 ; mtype++ ) { for ( psize = 1 ; psize <= 4 ; psize++ ) { transform_func func = _mesa_transform_tab[psize][mtypes[mtype]]; unsigned long *cycles = &(benchmark_tab[psize-1][mtype]); if ( test_transform_function( func, psize, mtype, cycles ) == 0 ) { char buf[100]; _mesa_sprintf(buf, "_mesa_transform_tab[0][%d][%s] failed test (%s)", psize, mstrings[mtype], description ); _mesa_problem( NULL, buf ); } #ifdef RUN_DEBUG_BENCHMARK if ( mesa_profile ) _mesa_printf(" %li\t", benchmark_tab[psize-1][mtype] ); #endif } #ifdef RUN_DEBUG_BENCHMARK if ( mesa_profile ) _mesa_printf(" | [%s]\n", mstrings[mtype] ); #endif } #ifdef RUN_DEBUG_BENCHMARK if ( mesa_profile ) _mesa_printf( "\n" ); #endif } #endif /* DEBUG_MATH */