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/*
* (C) Copyright IBM Corporation 2004
* 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
* on the rights to use, copy, modify, merge, publish, distribute, sub
* license, 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 NON-INFRINGEMENT. IN NO EVENT SHALL
* IBM AND/OR THEIR 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 via_texcombine.c
* Calculate texture combine hardware state.
*
* \author Ian Romanick <idr@us.ibm.com>
*/
#include <stdio.h>
#include "main/glheader.h"
#include "main/context.h"
#include "main/macros.h"
#include "main/colormac.h"
#include "main/enums.h"
#include "via_context.h"
#include "via_tex.h"
#include "via_3d_reg.h"
#define VIA_USE_ALPHA (HC_XTC_Adif - HC_XTC_Dif)
#define INPUT_A_SHIFT 14
#define INPUT_B_SHIFT 7
#define INPUT_C_SHIFT 0
#define INPUT_CBias_SHIFT 14
#define CONST_ONE (HC_XTC_0 | HC_XTC_InvTOPC)
static const unsigned color_operand_modifier[4] = {
0,
HC_XTC_InvTOPC,
VIA_USE_ALPHA,
VIA_USE_ALPHA | HC_XTC_InvTOPC,
};
static const unsigned alpha_operand_modifier[2] = {
0, HC_XTA_InvTOPA
};
static const unsigned bias_alpha_operand_modifier[2] = {
0, HC_HTXnTBLAbias_Inv
};
static const unsigned c_shift_table[3] = {
HC_HTXnTBLCshift_No, HC_HTXnTBLCshift_1, HC_HTXnTBLCshift_2
};
static const unsigned a_shift_table[3] = {
HC_HTXnTBLAshift_No, HC_HTXnTBLAshift_1, HC_HTXnTBLAshift_2
};
/**
* Calculate the hardware state for the specified texture combine mode
*
* \bug
* All forms of DOT3 bumpmapping are completely untested, and are most
* likely wrong. KW: Looks like it will never be quite right as the
* hardware seems to experience overflow in color calculation at the
* 4x shift levels, which need to be programed for DOT3. Maybe newer
* hardware fixes these issues.
*
* \bug
* KW: needs attention to the case where texunit 1 is enabled but
* texunit 0 is not.
*/
GLboolean
viaTexCombineState( struct via_context *vmesa,
const struct gl_tex_env_combine_state * combine,
unsigned unit )
{
unsigned color_arg[3];
unsigned alpha_arg[3];
unsigned bias_alpha_arg[3];
unsigned color = HC_HTXnTBLCsat_MASK;
unsigned alpha = HC_HTXnTBLAsat_MASK;
unsigned bias = 0;
unsigned op = 0;
unsigned a_shift = combine->ScaleShiftA;
unsigned c_shift = combine->ScaleShiftRGB;
unsigned i;
unsigned constant_color[3];
unsigned ordered_constant_color[4];
unsigned constant_alpha[3];
unsigned bias_alpha = 0;
unsigned abc_alpha = 0;
const struct gl_texture_unit * texUnit =
&vmesa->glCtx->Texture.Unit[unit];
unsigned env_color[4];
/* It seems that the color clamping can be overwhelmed at the 4x
* scale settings, necessitating this fallback:
*/
if (c_shift == 2 || a_shift == 2) {
return GL_FALSE;
}
CLAMPED_FLOAT_TO_UBYTE(env_color[0], texUnit->EnvColor[0]);
CLAMPED_FLOAT_TO_UBYTE(env_color[1], texUnit->EnvColor[1]);
CLAMPED_FLOAT_TO_UBYTE(env_color[2], texUnit->EnvColor[2]);
CLAMPED_FLOAT_TO_UBYTE(env_color[3], texUnit->EnvColor[3]);
(void) memset( constant_color, 0, sizeof( constant_color ) );
(void) memset( ordered_constant_color, 0, sizeof( ordered_constant_color ) );
(void) memset( constant_alpha, 0, sizeof( constant_alpha ) );
for ( i = 0 ; i < combine->_NumArgsRGB ; i++ ) {
const GLint op = combine->OperandRGB[i] - GL_SRC_COLOR;
switch ( combine->SourceRGB[i] ) {
case GL_TEXTURE:
color_arg[i] = HC_XTC_Tex;
color_arg[i] += color_operand_modifier[op];
break;
case GL_CONSTANT:
color_arg[i] = HC_XTC_HTXnTBLRC;
switch( op ) {
case 0: /* GL_SRC_COLOR */
constant_color[i] = ((env_color[0] << 16) |
(env_color[1] << 8) |
env_color[2]);
break;
case 1: /* GL_ONE_MINUS_SRC_COLOR */
constant_color[i] = ~((env_color[0] << 16) |
(env_color[1] << 8) |
env_color[2]) & 0x00ffffff;
break;
case 2: /* GL_SRC_ALPHA */
constant_color[i] = ((env_color[3] << 16) |
(env_color[3] << 8) |
env_color[3]);
break;
case 3: /* GL_ONE_MINUS_SRC_ALPHA */
constant_color[i] = ~((env_color[3] << 16) |
(env_color[3] << 8) |
env_color[3]) & 0x00ffffff;
break;
}
break;
case GL_PRIMARY_COLOR:
color_arg[i] = HC_XTC_Dif;
color_arg[i] += color_operand_modifier[op];
break;
case GL_PREVIOUS:
color_arg[i] = (unit == 0) ? HC_XTC_Dif : HC_XTC_Cur;
color_arg[i] += color_operand_modifier[op];
break;
}
}
/* On the Unichrome, all combine operations take on some form of:
*
* (xA * (xB op xC) + xBias) << xShift
*
* 'op' can be selected as add, subtract, min, max, or mask. The min, max
* and mask modes are currently unused. With the exception of DOT3, all
* standard GL_COMBINE modes can be implemented simply by selecting the
* correct inputs for A, B, C, and Bias and the correct operation for op.
*
* NOTE: xBias (when read from the constant registers) is signed,
* and scaled to fit -255..255 in 8 bits, ie 0x1 == 2.
*/
switch( combine->ModeRGB ) {
/* Ca = 1.0, Cb = arg0, Cc = 0, Cbias = 0
*/
case GL_REPLACE:
color |= ((CONST_ONE << INPUT_A_SHIFT) |
(color_arg[0] << INPUT_B_SHIFT));
ordered_constant_color[1] = constant_color[0];
break;
/* Ca = arg[0], Cb = arg[1], Cc = 0, Cbias = 0
*/
case GL_MODULATE:
color |= ((color_arg[0] << INPUT_A_SHIFT) |
(color_arg[1] << INPUT_B_SHIFT));
ordered_constant_color[0] = constant_color[0];
ordered_constant_color[1] = constant_color[1];
break;
/* Ca = 1.0, Cb = arg[0], Cc = arg[1], Cbias = 0
*/
case GL_ADD:
case GL_SUBTRACT:
if ( combine->ModeRGB == GL_SUBTRACT ) {
op |= HC_HTXnTBLCop_Sub;
}
color |= ((CONST_ONE << INPUT_A_SHIFT) |
(color_arg[0] << INPUT_B_SHIFT) |
(color_arg[1] << INPUT_C_SHIFT));
ordered_constant_color[1] = constant_color[0];
ordered_constant_color[2] = constant_color[1];
break;
/* Ca = 1.0, Cb = arg[0], Cc = arg[1], Cbias = -0.5
*/
case GL_ADD_SIGNED:
color |= ((CONST_ONE << INPUT_A_SHIFT) |
(color_arg[0] << INPUT_B_SHIFT) |
(color_arg[1] << INPUT_C_SHIFT));
bias |= HC_HTXnTBLCbias_HTXnTBLRC;
ordered_constant_color[1] = constant_color[0];
ordered_constant_color[2] = constant_color[1];
ordered_constant_color[3] = 0x00bfbfbf; /* -.5 */
break;
/* Ca = arg[2], Cb = arg[0], Cc = arg[1], Cbias = arg[1]
*/
case GL_INTERPOLATE:
op |= HC_HTXnTBLCop_Sub;
color |= ((color_arg[2] << INPUT_A_SHIFT) |
(color_arg[0] << INPUT_B_SHIFT) |
(color_arg[1] << INPUT_C_SHIFT));
bias |= (color_arg[1] << INPUT_CBias_SHIFT);
ordered_constant_color[0] = constant_color[2];
ordered_constant_color[1] = constant_color[0];
ordered_constant_color[2] = constant_color[1];
ordered_constant_color[3] = (constant_color[1] >> 1) & 0x7f7f7f;
break;
#if 0
/* At this point this code is completely untested. It appears that the
* Unichrome has the same limitation as the Radeon R100. The only
* supported post-scale when doing DOT3 bumpmapping is 1x.
*/
case GL_DOT3_RGB_EXT:
case GL_DOT3_RGBA_EXT:
case GL_DOT3_RGB:
case GL_DOT3_RGBA:
c_shift = 2;
a_shift = 2;
color |= ((color_arg[0] << INPUT_A_SHIFT) |
(color_arg[1] << INPUT_B_SHIFT));
op |= HC_HTXnTBLDOT4;
break;
#endif
default:
assert(0);
break;
}
/* The alpha blend stage has the annoying quirk of not having a
* hard-wired 0 input, like the color stage. As a result, we have
* to program the constant register with 0 and use that as our
* 0 input.
*
* (xA * (xB op xC) + xBias) << xShift
*
*/
for ( i = 0 ; i < combine->_NumArgsA ; i++ ) {
const GLint op = combine->OperandA[i] - GL_SRC_ALPHA;
switch ( combine->SourceA[i] ) {
case GL_TEXTURE:
alpha_arg[i] = HC_XTA_Atex;
alpha_arg[i] += alpha_operand_modifier[op];
bias_alpha_arg[i] = HC_HTXnTBLAbias_Atex;
bias_alpha_arg[i] += bias_alpha_operand_modifier[op];
break;
case GL_CONSTANT:
alpha_arg[i] = HC_XTA_HTXnTBLRA;
bias_alpha_arg[i] = HC_HTXnTBLAbias_HTXnTBLRAbias;
constant_alpha[i] = (op == 0) ? env_color[3] : (~env_color[3] & 0xff);
break;
case GL_PRIMARY_COLOR:
alpha_arg[i] = HC_XTA_Adif;
alpha_arg[i] += alpha_operand_modifier[op];
bias_alpha_arg[i] = HC_HTXnTBLAbias_Adif;
bias_alpha_arg[i] += bias_alpha_operand_modifier[op];
break;
case GL_PREVIOUS:
alpha_arg[i] = (unit == 0) ? HC_XTA_Adif : HC_XTA_Acur;
alpha_arg[i] += alpha_operand_modifier[op];
bias_alpha_arg[i] = (unit == 0 ?
HC_HTXnTBLAbias_Adif :
HC_HTXnTBLAbias_Acur);
bias_alpha_arg[i] += bias_alpha_operand_modifier[op];
break;
}
}
switch( combine->ModeA ) {
/* Aa = 0, Ab = 0, Ac = 0, Abias = arg0
*/
case GL_REPLACE:
alpha |= ((HC_XTA_HTXnTBLRA << INPUT_A_SHIFT) |
(HC_XTA_HTXnTBLRA << INPUT_B_SHIFT) |
(HC_XTA_HTXnTBLRA << INPUT_C_SHIFT));
abc_alpha = 0;
bias |= bias_alpha_arg[0];
bias_alpha = constant_alpha[0] >> 1;
break;
/* Aa = arg[0], Ab = arg[1], Ac = 0, Abias = 0
*/
case GL_MODULATE:
alpha |= ((alpha_arg[1] << INPUT_A_SHIFT) |
(alpha_arg[0] << INPUT_B_SHIFT) |
(HC_XTA_HTXnTBLRA << INPUT_C_SHIFT));
abc_alpha = ((constant_alpha[1] << HC_HTXnTBLRAa_SHIFT) |
(constant_alpha[0] << HC_HTXnTBLRAb_SHIFT) |
(0 << HC_HTXnTBLRAc_SHIFT));
bias |= HC_HTXnTBLAbias_HTXnTBLRAbias;
bias_alpha = 0;
break;
/* Aa = 1.0, Ab = arg[0], Ac = arg[1], Abias = 0
*/
case GL_ADD:
case GL_SUBTRACT:
if ( combine->ModeA == GL_SUBTRACT ) {
op |= HC_HTXnTBLAop_Sub;
}
alpha |= ((HC_XTA_HTXnTBLRA << INPUT_A_SHIFT) |
(alpha_arg[0] << INPUT_B_SHIFT) |
(alpha_arg[1] << INPUT_C_SHIFT));
abc_alpha = ((0xff << HC_HTXnTBLRAa_SHIFT) |
(constant_alpha[0] << HC_HTXnTBLRAb_SHIFT) |
(constant_alpha[1] << HC_HTXnTBLRAc_SHIFT));
bias |= HC_HTXnTBLAbias_HTXnTBLRAbias;
bias_alpha = 0;
break;
/* Aa = 1.0, Ab = arg[0], Ac = arg[1], Abias = -0.5
*/
case GL_ADD_SIGNED:
alpha |= ((HC_XTA_HTXnTBLRA << INPUT_A_SHIFT) |
(alpha_arg[0] << INPUT_B_SHIFT) |
(alpha_arg[1] << INPUT_C_SHIFT));
abc_alpha = ((0xff << HC_HTXnTBLRAa_SHIFT) |
(constant_alpha[0] << HC_HTXnTBLRAb_SHIFT) |
(constant_alpha[1] << HC_HTXnTBLRAc_SHIFT));
bias |= HC_HTXnTBLAbias_HTXnTBLRAbias;
bias_alpha = 0xbf;
break;
/* Aa = arg[2], Ab = arg[0], Ac = arg[1], Abias = arg[1]
*/
case GL_INTERPOLATE:
op |= HC_HTXnTBLAop_Sub;
alpha |= ((alpha_arg[2] << INPUT_A_SHIFT) |
(alpha_arg[0] << INPUT_B_SHIFT) |
(alpha_arg[1] << INPUT_C_SHIFT));
abc_alpha = ((constant_alpha[2] << HC_HTXnTBLRAa_SHIFT) |
(constant_alpha[0] << HC_HTXnTBLRAb_SHIFT) |
(constant_alpha[1] << HC_HTXnTBLRAc_SHIFT));
bias |= bias_alpha_arg[1];
bias_alpha = constant_alpha[1] >> 1;
break;
}
op |= c_shift_table[ c_shift ] | a_shift_table[ a_shift ];
vmesa->regHTXnTBLMPfog[unit] = HC_HTXnTBLMPfog_Fog;
vmesa->regHTXnTBLCsat[unit] = color;
vmesa->regHTXnTBLAsat[unit] = alpha;
vmesa->regHTXnTBLCop[unit] = op | bias;
vmesa->regHTXnTBLRAa[unit] = abc_alpha;
vmesa->regHTXnTBLRFog[unit] = bias_alpha;
vmesa->regHTXnTBLRCa[unit] = ordered_constant_color[0];
vmesa->regHTXnTBLRCb[unit] = ordered_constant_color[1];
vmesa->regHTXnTBLRCc[unit] = ordered_constant_color[2];
vmesa->regHTXnTBLRCbias[unit] = ordered_constant_color[3];
return GL_TRUE;
}
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