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/* $Id: s_aaline.c,v 1.1 2003-02-28 11:49:40 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.
*/
#include "glheader.h"
#include "swrast/s_aaline.h"
#include "swrast/s_context.h"
#include "swrast/s_span.h"
#include "swrast/swrast.h"
#include "mtypes.h"
#include "mmath.h"
#define SUB_PIXEL 4
/*
* Info about the AA line we're rendering
*/
struct LineInfo
{
GLfloat x0
, y0
; /* start */
GLfloat x1
, y1
; /* end */
GLfloat dx
, dy
; /* direction vector */
GLfloat len
; /* length */
GLfloat halfWidth
; /* half of line width */
GLfloat xAdj
, yAdj
; /* X and Y adjustment for quad corners around line */
/* for coverage computation */
GLfloat qx0
, qy0
; /* quad vertices */
GLfloat qx1
, qy1
;
GLfloat qx2
, qy2
;
GLfloat qx3
, qy3
;
GLfloat ex0
, ey0
; /* quad edge vectors */
GLfloat ex1
, ey1
;
GLfloat ex2
, ey2
;
GLfloat ex3
, ey3
;
/* DO_Z */
GLfloat zPlane
[4];
/* DO_FOG */
GLfloat fPlane
[4];
/* DO_RGBA */
GLfloat rPlane
[4], gPlane
[4], bPlane
[4], aPlane
[4];
/* DO_INDEX */
GLfloat iPlane
[4];
/* DO_SPEC */
GLfloat srPlane
[4], sgPlane
[4], sbPlane
[4];
/* DO_TEX or DO_MULTITEX */
GLfloat sPlane
[MAX_TEXTURE_UNITS
][4];
GLfloat tPlane
[MAX_TEXTURE_UNITS
][4];
GLfloat uPlane
[MAX_TEXTURE_UNITS
][4];
GLfloat vPlane
[MAX_TEXTURE_UNITS
][4];
GLfloat lambda
[MAX_TEXTURE_UNITS
];
GLfloat texWidth
[MAX_TEXTURE_UNITS
], texHeight
[MAX_TEXTURE_UNITS
];
struct sw_span span
;
};
/*
* Compute the equation of a plane used to interpolate line fragment data
* such as color, Z, texture coords, etc.
* Input: (x0, y0) and (x1,y1) are the endpoints of the line.
* z0, and z1 are the end point values to interpolate.
* Output: plane - the plane equation.
*
* Note: we don't really have enough parameters to specify a plane.
* We take the endpoints of the line and compute a plane such that
* the cross product of the line vector and the plane normal is
* parallel to the projection plane.
*/
static void
compute_plane
(GLfloat x0
, GLfloat y0
, GLfloat x1
, GLfloat y1
,
GLfloat z0
, GLfloat z1
, GLfloat plane
[4])
{
#if 0
/* original */
const GLfloat px
= x1
- x0
;
const GLfloat py
= y1
- y0
;
const GLfloat pz
= z1
- z0
;
const GLfloat qx
= -py
;
const GLfloat qy
= px
;
const GLfloat qz
= 0;
const GLfloat a
= py
* qz
- pz
* qy
;
const GLfloat b
= pz
* qx
- px
* qz
;
const GLfloat c
= px
* qy
- py
* qx
;
const GLfloat d
= -(a
* x0
+ b
* y0
+ c
* z0
);
plane
[0] = a
;
plane
[1] = b
;
plane
[2] = c
;
plane
[3] = d
;
#else
/* simplified */
const GLfloat px
= x1
- x0
;
const GLfloat py
= y1
- y0
;
const GLfloat pz
= z0
- z1
;
const GLfloat a
= pz
* px
;
const GLfloat b
= pz
* py
;
const GLfloat c
= px
* px
+ py
* py
;
const GLfloat d
= -(a
* x0
+ b
* y0
+ c
* z0
);
if (a
== 0.0 && b
== 0.0 && c
== 0.0 && d
== 0.0) {
plane
[0] = 0.0;
plane
[1] = 0.0;
plane
[2] = 1.0;
plane
[3] = 0.0;
}
else {
plane
[0] = a
;
plane
[1] = b
;
plane
[2] = c
;
plane
[3] = d
;
}
#endif
}
static INLINE
void
constant_plane
(GLfloat value
, GLfloat plane
[4])
{
plane
[0] = 0.0;
plane
[1] = 0.0;
plane
[2] = -1.0;
plane
[3] = value
;
}
static INLINE GLfloat
solve_plane
(GLfloat x
, GLfloat y
, const GLfloat plane
[4])
{
const GLfloat z
= (plane
[3] + plane
[0] * x
+ plane
[1] * y
) / -plane
[2];
return z
;
}
#define SOLVE_PLANE(X, Y, PLANE) \
((PLANE[3] + PLANE[0] * (X) + PLANE[1] * (Y)) / -PLANE[2])
/*
* Return 1 / solve_plane().
*/
static INLINE GLfloat
solve_plane_recip
(GLfloat x
, GLfloat y
, const GLfloat plane
[4])
{
const GLfloat denom
= plane
[3] + plane
[0] * x
+ plane
[1] * y
;
if (denom
== 0.0)
return 0.0;
else
return -plane
[2] / denom
;
}
/*
* Solve plane and return clamped GLchan value.
*/
static INLINE GLchan
solve_plane_chan
(GLfloat x
, GLfloat y
, const GLfloat plane
[4])
{
GLfloat z
= (plane
[3] + plane
[0] * x
+ plane
[1] * y
) / -plane
[2] + 0.5F;
if (z
< 0.0F)
return 0;
else if (z
> CHAN_MAXF
)
return (GLchan
) CHAN_MAXF
;
return (GLchan
) (GLint
) z
;
}
/*
* Compute mipmap level of detail.
*/
static INLINE GLfloat
compute_lambda
(const GLfloat sPlane
[4], const GLfloat tPlane
[4],
GLfloat invQ
, GLfloat width
, GLfloat height
)
{
GLfloat dudx
= sPlane
[0] / sPlane
[2] * invQ
* width
;
GLfloat dudy
= sPlane
[1] / sPlane
[2] * invQ
* width
;
GLfloat dvdx
= tPlane
[0] / tPlane
[2] * invQ
* height
;
GLfloat dvdy
= tPlane
[1] / tPlane
[2] * invQ
* height
;
GLfloat r1
= dudx
* dudx
+ dudy
* dudy
;
GLfloat r2
= dvdx
* dvdx
+ dvdy
* dvdy
;
GLfloat rho2
= r1
+ r2
;
/* return log base 2 of rho */
if (rho2
== 0.0F)
return 0.0;
else
return (GLfloat
) (log(rho2
) * 1.442695 * 0.5);/* 1.442695 = 1/log(2) */
}
/*
* Fill in the samples[] array with the (x,y) subpixel positions of
* xSamples * ySamples sample positions.
* Note that the four corner samples are put into the first four
* positions of the array. This allows us to optimize for the common
* case of all samples being inside the polygon.
*/
static void
make_sample_table
(GLint xSamples
, GLint ySamples
, GLfloat samples
[][2])
{
const GLfloat dx
= 1.0F / (GLfloat
) xSamples
;
const GLfloat dy
= 1.0F / (GLfloat
) ySamples
;
GLint x
, y
;
GLint i
;
i
= 4;
for (x
= 0; x
< xSamples
; x
++) {
for (y
= 0; y
< ySamples
; y
++) {
GLint j
;
if (x
== 0 && y
== 0) {
/* lower left */
j
= 0;
}
else if (x
== xSamples
- 1 && y
== 0) {
/* lower right */
j
= 1;
}
else if (x
== 0 && y
== ySamples
- 1) {
/* upper left */
j
= 2;
}
else if (x
== xSamples
- 1 && y
== ySamples
- 1) {
/* upper right */
j
= 3;
}
else {
j
= i
++;
}
samples
[j
][0] = x
* dx
+ 0.5F * dx
;
samples
[j
][1] = y
* dy
+ 0.5F * dy
;
}
}
}
/*
* Compute how much of the given pixel's area is inside the rectangle
* defined by vertices v0, v1, v2, v3.
* Vertices MUST be specified in counter-clockwise order.
* Return: coverage in [0, 1].
*/
static GLfloat
compute_coveragef
(const struct LineInfo
*info
,
GLint winx
, GLint winy
)
{
static GLfloat samples
[SUB_PIXEL
* SUB_PIXEL
][2];
static GLboolean haveSamples
= GL_FALSE
;
const GLfloat x
= (GLfloat
) winx
;
const GLfloat y
= (GLfloat
) winy
;
GLint stop
= 4, i
;
GLfloat insideCount
= SUB_PIXEL
* SUB_PIXEL
;
if (!haveSamples
) {
make_sample_table
(SUB_PIXEL
, SUB_PIXEL
, samples
);
haveSamples
= GL_TRUE
;
}
#if 0 /*DEBUG*/
{
const GLfloat area
= dx0
* dy1
- dx1
* dy0
;
assert(area
>= 0.0);
}
#endif
for (i
= 0; i
< stop
; i
++) {
const GLfloat sx
= x
+ samples
[i
][0];
const GLfloat sy
= y
+ samples
[i
][1];
const GLfloat fx0
= sx
- info
->qx0
;
const GLfloat fy0
= sy
- info
->qy0
;
const GLfloat fx1
= sx
- info
->qx1
;
const GLfloat fy1
= sy
- info
->qy1
;
const GLfloat fx2
= sx
- info
->qx2
;
const GLfloat fy2
= sy
- info
->qy2
;
const GLfloat fx3
= sx
- info
->qx3
;
const GLfloat fy3
= sy
- info
->qy3
;
/* cross product determines if sample is inside or outside each edge */
GLfloat cross0
= (info
->ex0
* fy0
- info
->ey0
* fx0
);
GLfloat cross1
= (info
->ex1
* fy1
- info
->ey1
* fx1
);
GLfloat cross2
= (info
->ex2
* fy2
- info
->ey2
* fx2
);
GLfloat cross3
= (info
->ex3
* fy3
- info
->ey3
* fx3
);
/* Check if the sample is exactly on an edge. If so, let cross be a
* positive or negative value depending on the direction of the edge.
*/
if (cross0
== 0.0F)
cross0
= info
->ex0
+ info
->ey0
;
if (cross1
== 0.0F)
cross1
= info
->ex1
+ info
->ey1
;
if (cross2
== 0.0F)
cross2
= info
->ex2
+ info
->ey2
;
if (cross3
== 0.0F)
cross3
= info
->ex3
+ info
->ey3
;
if (cross0
< 0.0F || cross1
< 0.0F || cross2
< 0.0F || cross3
< 0.0F) {
/* point is outside quadrilateral */
insideCount
-= 1.0F;
stop
= SUB_PIXEL
* SUB_PIXEL
;
}
}
if (stop
== 4)
return 1.0F;
else
return insideCount
* (1.0F / (SUB_PIXEL
* SUB_PIXEL
));
}
typedef void (*plot_func
)(GLcontext
*ctx
, struct LineInfo
*line
,
int ix
, int iy
);
/*
* Draw an AA line segment (called many times per line when stippling)
*/
static void
segment
(GLcontext
*ctx
,
struct LineInfo
*line
,
plot_func plot
,
GLfloat t0
, GLfloat t1
)
{
const GLfloat absDx
= (line
->dx
< 0.0F) ? -line
->dx
: line
->dx
;
const GLfloat absDy
= (line
->dy
< 0.0F) ? -line
->dy
: line
->dy
;
/* compute the actual segment's endpoints */
const GLfloat x0
= line
->x0
+ t0
* line
->dx
;
const GLfloat y0
= line
->y0
+ t0
* line
->dy
;
const GLfloat x1
= line
->x0
+ t1
* line
->dx
;
const GLfloat y1
= line
->y0
+ t1
* line
->dy
;
/* compute vertices of the line-aligned quadrilateral */
line
->qx0
= x0
- line
->yAdj
;
line
->qy0
= y0
+ line
->xAdj
;
line
->qx1
= x0
+ line
->yAdj
;
line
->qy1
= y0
- line
->xAdj
;
line
->qx2
= x1
+ line
->yAdj
;
line
->qy2
= y1
- line
->xAdj
;
line
->qx3
= x1
- line
->yAdj
;
line
->qy3
= y1
+ line
->xAdj
;
/* compute the quad's edge vectors (for coverage calc) */
line
->ex0
= line
->qx1
- line
->qx0
;
line
->ey0
= line
->qy1
- line
->qy0
;
line
->ex1
= line
->qx2
- line
->qx1
;
line
->ey1
= line
->qy2
- line
->qy1
;
line
->ex2
= line
->qx3
- line
->qx2
;
line
->ey2
= line
->qy3
- line
->qy2
;
line
->ex3
= line
->qx0
- line
->qx3
;
line
->ey3
= line
->qy0
- line
->qy3
;
if (absDx
> absDy
) {
/* X-major line */
GLfloat dydx
= line
->dy
/ line
->dx
;
GLfloat xLeft
, xRight
, yBot
, yTop
;
GLint ix
, ixRight
;
if (x0
< x1
) {
xLeft
= x0
- line
->halfWidth
;
xRight
= x1
+ line
->halfWidth
;
if (line
->dy
>= 0.0) {
yBot
= y0
- 3.0F * line
->halfWidth
;
yTop
= y0
+ line
->halfWidth
;
}
else {
yBot
= y0
- line
->halfWidth
;
yTop
= y0
+ 3.0F * line
->halfWidth
;
}
}
else {
xLeft
= x1
- line
->halfWidth
;
xRight
= x0
+ line
->halfWidth
;
if (line
->dy
<= 0.0) {
yBot
= y1
- 3.0F * line
->halfWidth
;
yTop
= y1
+ line
->halfWidth
;
}
else {
yBot
= y1
- line
->halfWidth
;
yTop
= y1
+ 3.0F * line
->halfWidth
;
}
}
/* scan along the line, left-to-right */
ixRight
= (GLint
) (xRight
+ 1.0F);
/*printf("avg span height: %g\n", yTop - yBot);*/
for (ix
= (GLint
) xLeft
; ix
< ixRight
; ix
++) {
const GLint iyBot
= (GLint
) yBot
;
const GLint iyTop
= (GLint
) (yTop
+ 1.0F);
GLint iy
;
/* scan across the line, bottom-to-top */
for (iy
= iyBot
; iy
< iyTop
; iy
++) {
(*plot
)(ctx
, line
, ix
, iy
);
}
yBot
+= dydx
;
yTop
+= dydx
;
}
}
else {
/* Y-major line */
GLfloat dxdy
= line
->dx
/ line
->dy
;
GLfloat yBot
, yTop
, xLeft
, xRight
;
GLint iy
, iyTop
;
if (y0
< y1
) {
yBot
= y0
- line
->halfWidth
;
yTop
= y1
+ line
->halfWidth
;
if (line
->dx
>= 0.0) {
xLeft
= x0
- 3.0F * line
->halfWidth
;
xRight
= x0
+ line
->halfWidth
;
}
else {
xLeft
= x0
- line
->halfWidth
;
xRight
= x0
+ 3.0F * line
->halfWidth
;
}
}
else {
yBot
= y1
- line
->halfWidth
;
yTop
= y0
+ line
->halfWidth
;
if (line
->dx
<= 0.0) {
xLeft
= x1
- 3.0F * line
->halfWidth
;
xRight
= x1
+ line
->halfWidth
;
}
else {
xLeft
= x1
- line
->halfWidth
;
xRight
= x1
+ 3.0F * line
->halfWidth
;
}
}
/* scan along the line, bottom-to-top */
iyTop
= (GLint
) (yTop
+ 1.0F);
/*printf("avg span width: %g\n", xRight - xLeft);*/
for (iy
= (GLint
) yBot
; iy
< iyTop
; iy
++) {
const GLint ixLeft
= (GLint
) xLeft
;
const GLint ixRight
= (GLint
) (xRight
+ 1.0F);
GLint ix
;
/* scan across the line, left-to-right */
for (ix
= ixLeft
; ix
< ixRight
; ix
++) {
(*plot
)(ctx
, line
, ix
, iy
);
}
xLeft
+= dxdy
;
xRight
+= dxdy
;
}
}
}
#define NAME(x) aa_ci_##x
#define DO_Z
#define DO_FOG
#define DO_INDEX
#include "s_aalinetemp.h"
#define NAME(x) aa_rgba_##x
#define DO_Z
#define DO_FOG
#define DO_RGBA
#include "s_aalinetemp.h"
#define NAME(x) aa_tex_rgba_##x
#define DO_Z
#define DO_FOG
#define DO_RGBA
#define DO_TEX
#include "s_aalinetemp.h"
#define NAME(x) aa_multitex_rgba_##x
#define DO_Z
#define DO_FOG
#define DO_RGBA
#define DO_MULTITEX
#include "s_aalinetemp.h"
#define NAME(x) aa_multitex_spec_##x
#define DO_Z
#define DO_FOG
#define DO_RGBA
#define DO_MULTITEX
#define DO_SPEC
#include "s_aalinetemp.h"
void
_swrast_choose_aa_line_function
(GLcontext
*ctx
)
{
SWcontext
*swrast
= SWRAST_CONTEXT
(ctx
);
ASSERT
(ctx
->Line.
SmoothFlag);
if (ctx
->Visual.
rgbMode) {
/* RGBA */
if (ctx
->Texture._EnabledUnits
!= 0) {
if (ctx
->Texture._EnabledUnits
> 1) {
/* Multitextured! */
if (ctx
->Light.
Model.
ColorControl==GL_SEPARATE_SPECULAR_COLOR
||
ctx
->Fog.
ColorSumEnabled)
swrast
->Line
= aa_multitex_spec_line
;
else
swrast
->Line
= aa_multitex_rgba_line
;
}
else {
swrast
->Line
= aa_tex_rgba_line
;
}
}
else {
swrast
->Line
= aa_rgba_line
;
}
}
else {
/* Color Index */
swrast
->Line
= aa_ci_line
;
}
}