*
* Copyright 2007 Tungsten Graphics, Inc., Cedar Park, Texas.
* All Rights Reserved.
- * Copyright 2008 VMware, Inc. All rights reserved.
+ * Copyright 2008-2010 VMware, Inc. All rights reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the
/*
- * Note, the FRAC macro has to work perfectly. Otherwise you'll sometimes
- * see 1-pixel bands of improperly weighted linear-filtered textures.
+ * Return fractional part of 'f'. Used for computing interpolation weights.
+ * Need to be careful with negative values.
+ * Note, if this function isn't perfect you'll sometimes see 1-pixel bands
+ * of improperly weighted linear-filtered textures.
* The tests/texwrap.c demo is a good test.
- * Also note, FRAC(x) doesn't truly return the fractional part of x for x < 0.
- * Instead, if x < 0 then FRAC(x) = 1 - true_frac(x).
*/
-#define FRAC(f) ((f) - util_ifloor(f))
+static INLINE float
+frac(float f)
+{
+ return f - floorf(f);
+}
+
/**
/**
- * If A is a signed integer, A % B doesn't give the right value for A < 0
- * (in terms of texture repeat). Just casting to unsigned fixes that.
+ * Compute coord % size for repeat wrap modes.
+ * Note that if coord is a signed integer, coord % size doesn't give
+ * the right value for coord < 0 (in terms of texture repeat). Just
+ * casting to unsigned fixes that.
*/
-#define REMAINDER(A, B) ((unsigned) (A) % (unsigned) (B))
+static INLINE int
+repeat(int coord, unsigned size)
+{
+ return (int) ((unsigned) coord % size);
+}
/**
* \return integer texture index
*/
static void
-wrap_nearest_repeat(const float s[4], unsigned size,
- int icoord[4])
+wrap_nearest_repeat(const float s[4], unsigned size, int icoord[4])
{
uint ch;
-
/* s limited to [0,1) */
/* i limited to [0,size-1] */
for (ch = 0; ch < 4; ch++) {
int i = util_ifloor(s[ch] * size);
- icoord[ch] = REMAINDER(i, size);
+ icoord[ch] = repeat(i, size);
}
}
static void
-wrap_nearest_clamp(const float s[4], unsigned size,
- int icoord[4])
+wrap_nearest_clamp(const float s[4], unsigned size, int icoord[4])
{
uint ch;
/* s limited to [0,1] */
static void
-wrap_nearest_clamp_to_edge(const float s[4], unsigned size,
- int icoord[4])
+wrap_nearest_clamp_to_edge(const float s[4], unsigned size, int icoord[4])
{
uint ch;
/* s limited to [min,max] */
static void
-wrap_nearest_clamp_to_border(const float s[4], unsigned size,
- int icoord[4])
+wrap_nearest_clamp_to_border(const float s[4], unsigned size, int icoord[4])
{
uint ch;
/* s limited to [min,max] */
}
}
+
static void
-wrap_nearest_mirror_repeat(const float s[4], unsigned size,
- int icoord[4])
+wrap_nearest_mirror_repeat(const float s[4], unsigned size, int icoord[4])
{
uint ch;
const float min = 1.0F / (2.0F * size);
const float max = 1.0F - min;
for (ch = 0; ch < 4; ch++) {
const int flr = util_ifloor(s[ch]);
- float u;
+ float u = frac(s[ch]);
if (flr & 1)
- u = 1.0F - (s[ch] - (float) flr);
- else
- u = s[ch] - (float) flr;
+ u = 1.0F - u;
if (u < min)
icoord[ch] = 0;
else if (u > max)
}
}
+
static void
-wrap_nearest_mirror_clamp(const float s[4], unsigned size,
- int icoord[4])
+wrap_nearest_mirror_clamp(const float s[4], unsigned size, int icoord[4])
{
uint ch;
for (ch = 0; ch < 4; ch++) {
}
}
+
static void
wrap_nearest_mirror_clamp_to_edge(const float s[4], unsigned size,
- int icoord[4])
+ int icoord[4])
{
uint ch;
/* s limited to [min,max] */
int icoord0[4], int icoord1[4], float w[4])
{
uint ch;
-
for (ch = 0; ch < 4; ch++) {
float u = s[ch] * size - 0.5F;
- icoord0[ch] = REMAINDER(util_ifloor(u), size);
- icoord1[ch] = REMAINDER(icoord0[ch] + 1, size);
- w[ch] = FRAC(u);
+ icoord0[ch] = repeat(util_ifloor(u), size);
+ icoord1[ch] = repeat(icoord0[ch] + 1, size);
+ w[ch] = frac(u);
}
}
+
static void
wrap_linear_clamp(const float s[4], unsigned size,
int icoord0[4], int icoord1[4], float w[4])
u = u * size - 0.5f;
icoord0[ch] = util_ifloor(u);
icoord1[ch] = icoord0[ch] + 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
+
static void
wrap_linear_clamp_to_edge(const float s[4], unsigned size,
int icoord0[4], int icoord1[4], float w[4])
icoord0[ch] = 0;
if (icoord1[ch] >= (int) size)
icoord1[ch] = size - 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
+
static void
wrap_linear_clamp_to_border(const float s[4], unsigned size,
int icoord0[4], int icoord1[4], float w[4])
u = u * size - 0.5f;
icoord0[ch] = util_ifloor(u);
icoord1[ch] = icoord0[ch] + 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
uint ch;
for (ch = 0; ch < 4; ch++) {
const int flr = util_ifloor(s[ch]);
- float u;
+ float u = frac(s[ch]);
if (flr & 1)
- u = 1.0F - (s[ch] - (float) flr);
- else
- u = s[ch] - (float) flr;
+ u = 1.0F - u;
u = u * size - 0.5F;
icoord0[ch] = util_ifloor(u);
icoord1[ch] = icoord0[ch] + 1;
icoord0[ch] = 0;
if (icoord1[ch] >= (int) size)
icoord1[ch] = size - 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
+
static void
wrap_linear_mirror_clamp(const float s[4], unsigned size,
int icoord0[4], int icoord1[4], float w[4])
u -= 0.5F;
icoord0[ch] = util_ifloor(u);
icoord1[ch] = icoord0[ch] + 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
+
static void
wrap_linear_mirror_clamp_to_edge(const float s[4], unsigned size,
int icoord0[4], int icoord1[4], float w[4])
icoord0[ch] = 0;
if (icoord1[ch] >= (int) size)
icoord1[ch] = size - 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
+
static void
wrap_linear_mirror_clamp_to_border(const float s[4], unsigned size,
int icoord0[4], int icoord1[4], float w[4])
u -= 0.5F;
icoord0[ch] = util_ifloor(u);
icoord1[ch] = icoord0[ch] + 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
/**
- * For RECT textures / unnormalized texcoords
- * Only a subset of wrap modes supported.
+ * PIPE_TEX_WRAP_CLAMP for nearest sampling, unnormalized coords.
*/
static void
-wrap_nearest_unorm_clamp(const float s[4], unsigned size,
- int icoord[4])
+wrap_nearest_unorm_clamp(const float s[4], unsigned size, int icoord[4])
{
uint ch;
for (ch = 0; ch < 4; ch++) {
}
}
-/* Handles clamp_to_edge and clamp_to_border:
+
+/**
+ * PIPE_TEX_WRAP_CLAMP_TO_BORDER for nearest sampling, unnormalized coords.
*/
static void
wrap_nearest_unorm_clamp_to_border(const float s[4], unsigned size,
- int icoord[4])
+ int icoord[4])
+{
+ uint ch;
+ for (ch = 0; ch < 4; ch++) {
+ icoord[ch]= util_ifloor( CLAMP(s[ch], -0.5F, (float) size + 0.5F) );
+ }
+}
+
+
+/**
+ * PIPE_TEX_WRAP_CLAMP_TO_EDGE for nearest sampling, unnormalized coords.
+ */
+static void
+wrap_nearest_unorm_clamp_to_edge(const float s[4], unsigned size,
+ int icoord[4])
{
uint ch;
for (ch = 0; ch < 4; ch++) {
/**
- * For RECT textures / unnormalized texcoords.
- * Only a subset of wrap modes supported.
+ * PIPE_TEX_WRAP_CLAMP for linear sampling, unnormalized coords.
*/
static void
wrap_linear_unorm_clamp(const float s[4], unsigned size,
- int icoord0[4], int icoord1[4], float w[4])
+ int icoord0[4], int icoord1[4], float w[4])
{
uint ch;
for (ch = 0; ch < 4; ch++) {
float u = CLAMP(s[ch] - 0.5F, 0.0f, (float) size - 1.0f);
icoord0[ch] = util_ifloor(u);
icoord1[ch] = icoord0[ch] + 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
+
+/**
+ * PIPE_TEX_WRAP_CLAMP_TO_BORDER for linear sampling, unnormalized coords.
+ */
static void
-wrap_linear_unorm_clamp_to_border( const float s[4], unsigned size,
- int icoord0[4], int icoord1[4], float w[4])
+wrap_linear_unorm_clamp_to_border(const float s[4], unsigned size,
+ int icoord0[4], int icoord1[4], float w[4])
{
uint ch;
for (ch = 0; ch < 4; ch++) {
- float u = CLAMP(s[ch], 0.5F, (float) size - 0.5F);
+ float u = CLAMP(s[ch], -0.5F, (float) size + 0.5F);
u -= 0.5F;
icoord0[ch] = util_ifloor(u);
icoord1[ch] = icoord0[ch] + 1;
if (icoord1[ch] > (int) size - 1)
icoord1[ch] = size - 1;
- w[ch] = FRAC(u);
+ w[ch] = frac(u);
}
}
+/**
+ * PIPE_TEX_WRAP_CLAMP_TO_EDGE for linear sampling, unnormalized coords.
+ */
+static void
+wrap_linear_unorm_clamp_to_edge(const float s[4], unsigned size,
+ int icoord0[4], int icoord1[4], float w[4])
+{
+ uint ch;
+ for (ch = 0; ch < 4; ch++) {
+ float u = CLAMP(s[ch], +0.5F, (float) size - 0.5F);
+ u -= 0.5F;
+ icoord0[ch] = util_ifloor(u);
+ icoord1[ch] = icoord0[ch] + 1;
+ if (icoord1[ch] > (int) size - 1)
+ icoord1[ch] = size - 1;
+ w[ch] = frac(u);
+ }
+}
compute_lambda_1d(const struct sp_sampler_varient *samp,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
- const float p[QUAD_SIZE],
- float lodbias)
+ const float p[QUAD_SIZE])
{
const struct pipe_texture *texture = samp->texture;
- const struct pipe_sampler_state *sampler = samp->sampler;
float dsdx = fabsf(s[QUAD_BOTTOM_RIGHT] - s[QUAD_BOTTOM_LEFT]);
float dsdy = fabsf(s[QUAD_TOP_LEFT] - s[QUAD_BOTTOM_LEFT]);
- float rho = MAX2(dsdx, dsdy) * texture->width[0];
- float lambda;
+ float rho = MAX2(dsdx, dsdy) * texture->width0;
- lambda = util_fast_log2(rho);
- lambda += lodbias + sampler->lod_bias;
- lambda = CLAMP(lambda, sampler->min_lod, sampler->max_lod);
-
- return lambda;
+ return util_fast_log2(rho);
}
+
static float
compute_lambda_2d(const struct sp_sampler_varient *samp,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
- const float p[QUAD_SIZE],
- float lodbias)
+ const float p[QUAD_SIZE])
{
const struct pipe_texture *texture = samp->texture;
- const struct pipe_sampler_state *sampler = samp->sampler;
float dsdx = fabsf(s[QUAD_BOTTOM_RIGHT] - s[QUAD_BOTTOM_LEFT]);
float dsdy = fabsf(s[QUAD_TOP_LEFT] - s[QUAD_BOTTOM_LEFT]);
float dtdx = fabsf(t[QUAD_BOTTOM_RIGHT] - t[QUAD_BOTTOM_LEFT]);
float dtdy = fabsf(t[QUAD_TOP_LEFT] - t[QUAD_BOTTOM_LEFT]);
- float maxx = MAX2(dsdx, dsdy) * texture->width[0];
- float maxy = MAX2(dtdx, dtdy) * texture->height[0];
+ float maxx = MAX2(dsdx, dsdy) * texture->width0;
+ float maxy = MAX2(dtdx, dtdy) * texture->height0;
float rho = MAX2(maxx, maxy);
- float lambda;
- lambda = util_fast_log2(rho);
- lambda += lodbias + sampler->lod_bias;
- lambda = CLAMP(lambda, sampler->min_lod, sampler->max_lod);
-
- return lambda;
+ return util_fast_log2(rho);
}
compute_lambda_3d(const struct sp_sampler_varient *samp,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
- const float p[QUAD_SIZE],
- float lodbias)
+ const float p[QUAD_SIZE])
{
const struct pipe_texture *texture = samp->texture;
- const struct pipe_sampler_state *sampler = samp->sampler;
float dsdx = fabsf(s[QUAD_BOTTOM_RIGHT] - s[QUAD_BOTTOM_LEFT]);
float dsdy = fabsf(s[QUAD_TOP_LEFT] - s[QUAD_BOTTOM_LEFT]);
float dtdx = fabsf(t[QUAD_BOTTOM_RIGHT] - t[QUAD_BOTTOM_LEFT]);
float dtdy = fabsf(t[QUAD_TOP_LEFT] - t[QUAD_BOTTOM_LEFT]);
float dpdx = fabsf(p[QUAD_BOTTOM_RIGHT] - p[QUAD_BOTTOM_LEFT]);
float dpdy = fabsf(p[QUAD_TOP_LEFT] - p[QUAD_BOTTOM_LEFT]);
- float maxx = MAX2(dsdx, dsdy) * texture->width[0];
- float maxy = MAX2(dtdx, dtdy) * texture->height[0];
- float maxz = MAX2(dpdx, dpdy) * texture->depth[0];
- float rho, lambda;
+ float maxx = MAX2(dsdx, dsdy) * texture->width0;
+ float maxy = MAX2(dtdx, dtdy) * texture->height0;
+ float maxz = MAX2(dpdx, dpdy) * texture->depth0;
+ float rho;
rho = MAX2(maxx, maxy);
rho = MAX2(rho, maxz);
- lambda = util_fast_log2(rho);
- lambda += lodbias + sampler->lod_bias;
- lambda = CLAMP(lambda, sampler->min_lod, sampler->max_lod);
-
- return lambda;
+ return util_fast_log2(rho);
}
-
+/**
+ * Compute lambda for a vertex texture sampler.
+ * Since there aren't derivatives to use, just return 0.
+ */
static float
compute_lambda_vert(const struct sp_sampler_varient *samp,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
- const float p[QUAD_SIZE],
- float lodbias)
+ const float p[QUAD_SIZE])
{
- return lodbias;
+ return 0.0f;
}
const struct pipe_texture *texture = samp->texture;
unsigned level = addr.bits.level;
- if (x < 0 || x >= (int) texture->width[level] ||
- y < 0 || y >= (int) texture->height[level]) {
+ if (x < 0 || x >= (int) u_minify(texture->width0, level) ||
+ y < 0 || y >= (int) u_minify(texture->height0, level)) {
return samp->sampler->border_color;
}
else {
*/
static INLINE const float *
get_texel_3d_no_border(const struct sp_sampler_varient *samp,
- union tex_tile_address addr, int x, int y, int z)
+ union tex_tile_address addr, int x, int y, int z)
{
const struct softpipe_tex_cached_tile *tile;
static INLINE const float *
get_texel_3d(const struct sp_sampler_varient *samp,
- union tex_tile_address addr, int x, int y, int z )
+ union tex_tile_address addr, int x, int y, int z)
{
const struct pipe_texture *texture = samp->texture;
unsigned level = addr.bits.level;
- if (x < 0 || x >= (int) texture->width[level] ||
- y < 0 || y >= (int) texture->height[level] ||
- z < 0 || z >= (int) texture->depth[level]) {
+ if (x < 0 || x >= (int) u_minify(texture->width0, level) ||
+ y < 0 || y >= (int) u_minify(texture->height0, level) ||
+ z < 0 || z >= (int) u_minify(texture->depth0, level)) {
return samp->sampler->border_color;
}
else {
}
+/**
+ * Given the logbase2 of a mipmap's base level size and a mipmap level,
+ * return the size (in texels) of that mipmap level.
+ * For example, if level[0].width = 256 then base_pot will be 8.
+ * If level = 2, then we'll return 64 (the width at level=2).
+ * Return 1 if level > base_pot.
+ */
+static INLINE unsigned
+pot_level_size(unsigned base_pot, unsigned level)
+{
+ return (base_pot >= level) ? (1 << (base_pot - level)) : 1;
+}
+
+
/* Some image-filter fastpaths:
*/
static INLINE void
img_filter_2d_linear_repeat_POT(struct tgsi_sampler *tgsi_sampler,
- const float s[QUAD_SIZE],
- const float t[QUAD_SIZE],
- const float p[QUAD_SIZE],
- float lodbias,
- float rgba[NUM_CHANNELS][QUAD_SIZE])
+ const float s[QUAD_SIZE],
+ const float t[QUAD_SIZE],
+ const float p[QUAD_SIZE],
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
+ float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
unsigned j;
unsigned level = samp->level;
- unsigned xpot = 1 << (samp->xpot - level);
- unsigned ypot = 1 << (samp->ypot - level);
+ unsigned xpot = pot_level_size(samp->xpot, level);
+ unsigned ypot = pot_level_size(samp->ypot, level);
unsigned xmax = (xpot - 1) & (TILE_SIZE - 1); /* MIN2(TILE_SIZE, xpot) - 1; */
unsigned ymax = (ypot - 1) & (TILE_SIZE - 1); /* MIN2(TILE_SIZE, ypot) - 1; */
union tex_tile_address addr;
addr.value = 0;
addr.bits.level = samp->level;
-
for (j = 0; j < QUAD_SIZE; j++) {
int c;
/* Can we fetch all four at once:
*/
- if (x0 < xmax && y0 < ymax)
- {
+ if (x0 < xmax && y0 < ymax) {
get_texel_quad_2d_no_border_single_tile(samp, addr, x0, y0, tx);
}
- else
- {
+ else {
unsigned x1 = (x0 + 1) & (xpot - 1);
unsigned y1 = (y0 + 1) & (ypot - 1);
get_texel_quad_2d_no_border(samp, addr, x0, y0, x1, y1, tx);
}
-
/* interpolate R, G, B, A */
for (c = 0; c < 4; c++) {
rgba[c][j] = lerp_2d(xw, yw,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
unsigned j;
unsigned level = samp->level;
- unsigned xpot = 1 << (samp->xpot - level);
- unsigned ypot = 1 << (samp->ypot - level);
+ unsigned xpot = pot_level_size(samp->xpot, level);
+ unsigned ypot = pot_level_size(samp->ypot, level);
union tex_tile_address addr;
addr.value = 0;
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
unsigned j;
unsigned level = samp->level;
- unsigned xpot = 1 << (samp->xpot - level);
- unsigned ypot = 1 << (samp->ypot - level);
+ unsigned xpot = pot_level_size(samp->xpot, level);
+ unsigned ypot = pot_level_size(samp->ypot, level);
union tex_tile_address addr;
addr.value = 0;
}
}
+
static void
img_filter_1d_nearest(struct tgsi_sampler *tgsi_sampler,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
union tex_tile_address addr;
level0 = samp->level;
- width = texture->width[level0];
+ width = u_minify(texture->width0, level0);
assert(width > 0);
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
level0 = samp->level;
- width = texture->width[level0];
- height = texture->height[level0];
+ width = u_minify(texture->width0, level0);
+ height = u_minify(texture->height0, level0);
assert(width > 0);
assert(height > 0);
}
}
-static inline union tex_tile_address face( union tex_tile_address addr,
- unsigned face )
+
+static INLINE union tex_tile_address
+face(union tex_tile_address addr, unsigned face )
{
addr.bits.face = face;
return addr;
}
+
static void
img_filter_cube_nearest(struct tgsi_sampler *tgsi_sampler,
- const float s[QUAD_SIZE],
- const float t[QUAD_SIZE],
- const float p[QUAD_SIZE],
- float lodbias,
- float rgba[NUM_CHANNELS][QUAD_SIZE])
+ const float s[QUAD_SIZE],
+ const float t[QUAD_SIZE],
+ const float p[QUAD_SIZE],
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
+ float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
const struct pipe_texture *texture = samp->texture;
int x[4], y[4];
union tex_tile_address addr;
-
level0 = samp->level;
- width = texture->width[level0];
- height = texture->height[level0];
+ width = u_minify(texture->width0, level0);
+ height = u_minify(texture->height0, level0);
assert(width > 0);
assert(height > 0);
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
union tex_tile_address addr;
level0 = samp->level;
- width = texture->width[level0];
- height = texture->height[level0];
- depth = texture->depth[level0];
+ width = u_minify(texture->width0, level0);
+ height = u_minify(texture->height0, level0);
+ depth = u_minify(texture->depth0, level0);
assert(width > 0);
assert(height > 0);
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
float xw[4]; /* weights */
union tex_tile_address addr;
-
level0 = samp->level;
- width = texture->width[level0];
+ width = u_minify(texture->width0, level0);
assert(width > 0);
samp->linear_texcoord_s(s, width, x0, x1, xw);
-
for (j = 0; j < QUAD_SIZE; j++) {
const float *tx0 = get_texel_2d(samp, addr, x0[j], 0);
const float *tx1 = get_texel_2d(samp, addr, x1[j], 0);
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
float xw[4], yw[4]; /* weights */
union tex_tile_address addr;
-
level0 = samp->level;
- width = texture->width[level0];
- height = texture->height[level0];
+ width = u_minify(texture->width0, level0);
+ height = u_minify(texture->height0, level0);
assert(width > 0);
assert(height > 0);
static void
img_filter_cube_linear(struct tgsi_sampler *tgsi_sampler,
- const float s[QUAD_SIZE],
- const float t[QUAD_SIZE],
- const float p[QUAD_SIZE],
- float lodbias,
- float rgba[NUM_CHANNELS][QUAD_SIZE])
+ const float s[QUAD_SIZE],
+ const float t[QUAD_SIZE],
+ const float p[QUAD_SIZE],
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
+ float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
const struct pipe_texture *texture = samp->texture;
float xw[4], yw[4]; /* weights */
union tex_tile_address addr;
-
level0 = samp->level;
- width = texture->width[level0];
- height = texture->height[level0];
+ width = u_minify(texture->width0, level0);
+ height = u_minify(texture->height0, level0);
assert(width > 0);
assert(height > 0);
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
const struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
union tex_tile_address addr;
level0 = samp->level;
- width = texture->width[level0];
- height = texture->height[level0];
- depth = texture->depth[level0];
+ width = u_minify(texture->width0, level0);
+ height = u_minify(texture->height0, level0);
+ depth = u_minify(texture->depth0, level0);
addr.value = 0;
addr.bits.level = level0;
}
+/* Calculate level of detail for every fragment.
+ * Note that lambda has already been biased by global LOD bias.
+ */
+static INLINE void
+compute_lod(const struct pipe_sampler_state *sampler,
+ const float biased_lambda,
+ const float lodbias[QUAD_SIZE],
+ float lod[QUAD_SIZE])
+{
+ uint i;
-
-
+ for (i = 0; i < QUAD_SIZE; i++) {
+ lod[i] = biased_lambda + lodbias[i];
+ lod[i] = CLAMP(lod[i], sampler->min_lod, sampler->max_lod);
+ }
+}
static void
mip_filter_linear(struct tgsi_sampler *tgsi_sampler,
- const float s[QUAD_SIZE],
- const float t[QUAD_SIZE],
- const float p[QUAD_SIZE],
- float lodbias,
- float rgba[NUM_CHANNELS][QUAD_SIZE])
+ const float s[QUAD_SIZE],
+ const float t[QUAD_SIZE],
+ const float p[QUAD_SIZE],
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
+ float rgba[NUM_CHANNELS][QUAD_SIZE])
{
struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
const struct pipe_texture *texture = samp->texture;
int level0;
float lambda;
+ float lod[QUAD_SIZE];
+
+ if (control == tgsi_sampler_lod_bias) {
+ lambda = samp->compute_lambda(samp, s, t, p) + samp->sampler->lod_bias;
+ compute_lod(samp->sampler, lambda, c0, lod);
+ } else {
+ assert(control == tgsi_sampler_lod_explicit);
- lambda = samp->compute_lambda(samp, s, t, p, lodbias);
+ memcpy(lod, c0, sizeof(lod));
+ }
+
+ /* XXX: Take into account all lod values.
+ */
+ lambda = lod[0];
level0 = (int)lambda;
if (lambda < 0.0) {
samp->level = 0;
- samp->mag_img_filter( tgsi_sampler, s, t, p, 0, rgba );
+ samp->mag_img_filter(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba);
}
else if (level0 >= texture->last_level) {
samp->level = texture->last_level;
- samp->min_img_filter( tgsi_sampler, s, t, p, 0, rgba );
+ samp->min_img_filter(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba);
}
else {
float levelBlend = lambda - level0;
int c,j;
samp->level = level0;
- samp->min_img_filter( tgsi_sampler, s, t, p, 0, rgba0 );
+ samp->min_img_filter(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba0);
samp->level = level0+1;
- samp->min_img_filter( tgsi_sampler, s, t, p, 0, rgba1 );
+ samp->min_img_filter(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba1);
for (j = 0; j < QUAD_SIZE; j++) {
for (c = 0; c < 4; c++) {
}
-
+/**
+ * Compute nearest mipmap level from texcoords.
+ * Then sample the texture level for four elements of a quad.
+ * \param c0 the LOD bias factors, or absolute LODs (depending on control)
+ */
static void
mip_filter_nearest(struct tgsi_sampler *tgsi_sampler,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
const struct pipe_texture *texture = samp->texture;
float lambda;
+ float lod[QUAD_SIZE];
- lambda = samp->compute_lambda(samp, s, t, p, lodbias);
+ if (control == tgsi_sampler_lod_bias) {
+ lambda = samp->compute_lambda(samp, s, t, p) + samp->sampler->lod_bias;
+ compute_lod(samp->sampler, lambda, c0, lod);
+ } else {
+ assert(control == tgsi_sampler_lod_explicit);
+
+ memcpy(lod, c0, sizeof(lod));
+ }
+
+ /* XXX: Take into account all lod values.
+ */
+ lambda = lod[0];
if (lambda < 0.0) {
samp->level = 0;
- samp->mag_img_filter( tgsi_sampler, s, t, p, 0, rgba );
+ samp->mag_img_filter(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba);
}
else {
samp->level = (int)(lambda + 0.5) ;
samp->level = MIN2(samp->level, (int)texture->last_level);
- samp->min_img_filter( tgsi_sampler, s, t, p, 0, rgba );
+ samp->min_img_filter(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba);
}
+
+#if 0
+ printf("RGBA %g %g %g %g, %g %g %g %g, %g %g %g %g, %g %g %g %g\n",
+ rgba[0][0], rgba[1][0], rgba[2][0], rgba[3][0],
+ rgba[0][1], rgba[1][1], rgba[2][1], rgba[3][1],
+ rgba[0][2], rgba[1][2], rgba[2][2], rgba[3][2],
+ rgba[0][3], rgba[1][3], rgba[2][3], rgba[3][3]);
+#endif
}
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
- float lambda = samp->compute_lambda(samp, s, t, p, lodbias);
+ float lambda;
+ float lod[QUAD_SIZE];
+
+ if (control == tgsi_sampler_lod_bias) {
+ lambda = samp->compute_lambda(samp, s, t, p) + samp->sampler->lod_bias;
+ compute_lod(samp->sampler, lambda, c0, lod);
+ } else {
+ assert(control == tgsi_sampler_lod_explicit);
+
+ memcpy(lod, c0, sizeof(lod));
+ }
+
+ /* XXX: Take into account all lod values.
+ */
+ lambda = lod[0];
if (lambda < 0.0) {
- samp->mag_img_filter( tgsi_sampler, s, t, p, 0, rgba );
+ samp->mag_img_filter(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba);
}
else {
- samp->min_img_filter( tgsi_sampler, s, t, p, 0, rgba );
+ samp->min_img_filter(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba);
}
}
-/* Specialized version of mip_filter_linear with hard-wired calls to
+/**
+ * Specialized version of mip_filter_linear with hard-wired calls to
* 2d lambda calculation and 2d_linear_repeat_POT img filters.
*/
static void
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
const struct pipe_texture *texture = samp->texture;
int level0;
float lambda;
+ float lod[QUAD_SIZE];
- lambda = compute_lambda_2d(samp, s, t, p, lodbias);
+ if (control == tgsi_sampler_lod_bias) {
+ lambda = samp->compute_lambda(samp, s, t, p) + samp->sampler->lod_bias;
+ compute_lod(samp->sampler, lambda, c0, lod);
+ } else {
+ assert(control == tgsi_sampler_lod_explicit);
+
+ memcpy(lod, c0, sizeof(lod));
+ }
+
+ /* XXX: Take into account all lod values.
+ */
+ lambda = lod[0];
level0 = (int)lambda;
/* Catches both negative and large values of level0:
else
samp->level = texture->last_level;
- img_filter_2d_linear_repeat_POT( tgsi_sampler, s, t, p, 0, rgba );
+ img_filter_2d_linear_repeat_POT(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba);
}
else {
float levelBlend = lambda - level0;
int c,j;
samp->level = level0;
- img_filter_2d_linear_repeat_POT( tgsi_sampler, s, t, p, 0, rgba0 );
+ img_filter_2d_linear_repeat_POT(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba0);
samp->level = level0+1;
- img_filter_2d_linear_repeat_POT( tgsi_sampler, s, t, p, 0, rgba1 );
+ img_filter_2d_linear_repeat_POT(tgsi_sampler, s, t, p, NULL, tgsi_sampler_lod_bias, rgba1);
for (j = 0; j < QUAD_SIZE; j++) {
for (c = 0; c < 4; c++) {
-/* Compare stage in the little sampling pipeline.
+/**
+ * Do shadow/depth comparisons.
*/
static void
sample_compare(struct tgsi_sampler *tgsi_sampler,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
int j, k0, k1, k2, k3;
float val;
- samp->mip_filter( tgsi_sampler, s, t, p, lodbias, rgba );
-
+ samp->mip_filter(tgsi_sampler, s, t, p, c0, control, rgba);
/**
* Compare texcoord 'p' (aka R) against texture value 'rgba[0]'
}
}
-/* Calculate cube faces.
+
+/**
+ * Use 3D texcoords to choose a cube face, then sample the 2D cube faces.
+ * Put face info into the sampler faces[] array.
*/
static void
sample_cube(struct tgsi_sampler *tgsi_sampler,
const float s[QUAD_SIZE],
const float t[QUAD_SIZE],
const float p[QUAD_SIZE],
- float lodbias,
+ const float c0[QUAD_SIZE],
+ enum tgsi_sampler_control control,
float rgba[NUM_CHANNELS][QUAD_SIZE])
{
struct sp_sampler_varient *samp = sp_sampler_varient(tgsi_sampler);
/*
major axis
- direction target sc tc ma
- ---------- ------------------------------- --- --- ---
+ direction target sc tc ma
+ ---------- ------------------------------- --- --- ---
+rx TEXTURE_CUBE_MAP_POSITIVE_X_EXT -rz -ry rx
-rx TEXTURE_CUBE_MAP_NEGATIVE_X_EXT +rz -ry rx
+ry TEXTURE_CUBE_MAP_POSITIVE_Y_EXT +rx +rz ry
+rz TEXTURE_CUBE_MAP_POSITIVE_Z_EXT +rx -ry rz
-rz TEXTURE_CUBE_MAP_NEGATIVE_Z_EXT -rx -ry rz
*/
- for (j = 0; j < QUAD_SIZE; j++) {
- float rx = s[j];
- float ry = t[j];
- float rz = p[j];
+
+ /* Choose the cube face and compute new s/t coords for the 2D face.
+ *
+ * Use the same cube face for all four pixels in the quad.
+ *
+ * This isn't ideal, but if we want to use a different cube face
+ * per pixel in the quad, we'd have to also compute the per-face
+ * LOD here too. That's because the four post-face-selection
+ * texcoords are no longer related to each other (they're
+ * per-face!) so we can't use subtraction to compute the partial
+ * deriviates to compute the LOD. Doing so (near cube edges
+ * anyway) gives us pretty much random values.
+ */
+ {
+ /* use the average of the four pixel's texcoords to choose the face */
+ const float rx = 0.25 * (s[0] + s[1] + s[2] + s[3]);
+ const float ry = 0.25 * (t[0] + t[1] + t[2] + t[3]);
+ const float rz = 0.25 * (p[0] + p[1] + p[2] + p[3]);
const float arx = fabsf(rx), ary = fabsf(ry), arz = fabsf(rz);
- unsigned face;
- float sc, tc, ma;
-
- if (arx > ary && arx > arz) {
- if (rx >= 0.0F) {
- face = PIPE_TEX_FACE_POS_X;
- sc = -rz;
- tc = -ry;
- ma = arx;
- }
- else {
- face = PIPE_TEX_FACE_NEG_X;
- sc = rz;
- tc = -ry;
- ma = arx;
+
+ if (arx >= ary && arx >= arz) {
+ float sign = (rx >= 0.0F) ? 1.0F : -1.0F;
+ uint face = (rx >= 0.0F) ? PIPE_TEX_FACE_POS_X : PIPE_TEX_FACE_NEG_X;
+ for (j = 0; j < QUAD_SIZE; j++) {
+ const float ima = -0.5F / fabsf(s[j]);
+ ssss[j] = sign * p[j] * ima + 0.5F;
+ tttt[j] = t[j] * ima + 0.5F;
+ samp->faces[j] = face;
}
}
- else if (ary > arx && ary > arz) {
- if (ry >= 0.0F) {
- face = PIPE_TEX_FACE_POS_Y;
- sc = rx;
- tc = rz;
- ma = ary;
- }
- else {
- face = PIPE_TEX_FACE_NEG_Y;
- sc = rx;
- tc = -rz;
- ma = ary;
+ else if (ary >= arx && ary >= arz) {
+ float sign = (ry >= 0.0F) ? 1.0F : -1.0F;
+ uint face = (ry >= 0.0F) ? PIPE_TEX_FACE_POS_Y : PIPE_TEX_FACE_NEG_Y;
+ for (j = 0; j < QUAD_SIZE; j++) {
+ const float ima = -0.5F / fabsf(t[j]);
+ ssss[j] = -s[j] * ima + 0.5F;
+ tttt[j] = sign * -p[j] * ima + 0.5F;
+ samp->faces[j] = face;
}
}
else {
- if (rz > 0.0F) {
- face = PIPE_TEX_FACE_POS_Z;
- sc = rx;
- tc = -ry;
- ma = arz;
- }
- else {
- face = PIPE_TEX_FACE_NEG_Z;
- sc = -rx;
- tc = -ry;
- ma = arz;
+ float sign = (rz >= 0.0F) ? 1.0F : -1.0F;
+ uint face = (rz >= 0.0F) ? PIPE_TEX_FACE_POS_Z : PIPE_TEX_FACE_NEG_Z;
+ for (j = 0; j < QUAD_SIZE; j++) {
+ const float ima = -0.5 / fabsf(p[j]);
+ ssss[j] = sign * -s[j] * ima + 0.5F;
+ tttt[j] = t[j] * ima + 0.5F;
+ samp->faces[j] = face;
}
}
-
- {
- const float ima = 1.0 / ma;
- ssss[j] = ( sc * ima + 1.0F ) * 0.5F;
- tttt[j] = ( tc * ima + 1.0F ) * 0.5F;
- samp->faces[j] = face;
- }
}
/* In our little pipeline, the compare stage is next. If compare
* is not active, this will point somewhere deeper into the
* pipeline, eg. to mip_filter or even img_filter.
*/
- samp->compare(tgsi_sampler, ssss, tttt, NULL, lodbias, rgba);
+ samp->compare(tgsi_sampler, ssss, tttt, NULL, c0, control, rgba);
}
-
-static wrap_nearest_func get_nearest_unorm_wrap( unsigned mode )
+static wrap_nearest_func
+get_nearest_unorm_wrap(unsigned mode)
{
switch (mode) {
case PIPE_TEX_WRAP_CLAMP:
return wrap_nearest_unorm_clamp;
case PIPE_TEX_WRAP_CLAMP_TO_EDGE:
+ return wrap_nearest_unorm_clamp_to_edge;
case PIPE_TEX_WRAP_CLAMP_TO_BORDER:
return wrap_nearest_unorm_clamp_to_border;
default:
}
-static wrap_nearest_func get_nearest_wrap( unsigned mode )
+static wrap_nearest_func
+get_nearest_wrap(unsigned mode)
{
switch (mode) {
case PIPE_TEX_WRAP_REPEAT:
}
}
-static wrap_linear_func get_linear_unorm_wrap( unsigned mode )
+
+static wrap_linear_func
+get_linear_unorm_wrap(unsigned mode)
{
switch (mode) {
case PIPE_TEX_WRAP_CLAMP:
return wrap_linear_unorm_clamp;
case PIPE_TEX_WRAP_CLAMP_TO_EDGE:
+ return wrap_linear_unorm_clamp_to_edge;
case PIPE_TEX_WRAP_CLAMP_TO_BORDER:
return wrap_linear_unorm_clamp_to_border;
default:
}
}
-static wrap_linear_func get_linear_wrap( unsigned mode )
+
+static wrap_linear_func
+get_linear_wrap(unsigned mode)
{
switch (mode) {
case PIPE_TEX_WRAP_REPEAT:
}
}
-static compute_lambda_func get_lambda_func( const union sp_sampler_key key )
+
+static compute_lambda_func
+get_lambda_func(const union sp_sampler_key key)
{
if (key.bits.processor == TGSI_PROCESSOR_VERTEX)
return compute_lambda_vert;
}
}
-static filter_func get_img_filter( const union sp_sampler_key key,
- unsigned filter,
- const struct pipe_sampler_state *sampler )
+
+static filter_func
+get_img_filter(const union sp_sampler_key key,
+ unsigned filter,
+ const struct pipe_sampler_state *sampler)
{
switch (key.bits.target) {
case PIPE_TEXTURE_1D:
samp->texture = texture;
samp->cache = tex_cache;
- samp->xpot = util_unsigned_logbase2( texture->width[0] );
- samp->ypot = util_unsigned_logbase2( texture->height[0] );
+ samp->xpot = util_unsigned_logbase2( texture->width0 );
+ samp->ypot = util_unsigned_logbase2( texture->height0 );
samp->level = CLAMP((int) sampler->min_lod, 0, (int) texture->last_level);
}
}
-/* Create a sampler varient for a given set of non-orthogonal state. Currently the
+/**
+ * Create a sampler varient for a given set of non-orthogonal state.
*/
struct sp_sampler_varient *
sp_create_sampler_varient( const struct pipe_sampler_state *sampler,
break;
}
- if (sampler->compare_mode != FALSE) {
+ if (sampler->compare_mode != PIPE_TEX_COMPARE_NONE) {
samp->compare = sample_compare;
}
else {
return samp;
}
-
-
-
-
-
-