/* Copyright 2007 nVidia, Inc. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ // Thanks to Jacob Munkberg (jacob@cs.lth.se) for the shortcut of using SVD to do the equivalent of principal components analysis // x10000000 5555.1x4 64p 2bi (30b) #include "bits.h" #include "tile.h" #include "avpcl.h" #include "nvcore/debug.h" #include "nvmath/vector.inl" #include "nvmath/matrix.inl" #include "nvmath/fitting.h" #include "avpcl_utils.h" #include "endpts.h" #include #include #include "shapes_two.h" using namespace nv; using namespace AVPCL; #define NLSBMODES 4 // number of different lsb modes per region. since we have two .1 per region, that can have 4 values #define NINDICES 4 #define INDEXBITS 2 #define HIGH_INDEXBIT (1<<(INDEXBITS-1)) #define DENOM (NINDICES-1) #define BIAS (DENOM/2) // WORK: determine optimal traversal pattern to search for best shape -- what does the error curve look like? // i.e. can we search shapes in a particular order so we can see the global error minima easily and // stop without having to touch all shapes? #define POS_TO_X(pos) ((pos)&3) #define POS_TO_Y(pos) (((pos)>>2)&3) #define NBITSIZES (NREGIONS*2) #define ABITINDEX(region) (2*(region)+0) #define BBITINDEX(region) (2*(region)+1) struct ChanBits { int nbitsizes[NBITSIZES]; // bitsizes for one channel }; struct Pattern { ChanBits chan[NCHANNELS_RGBA];// bit patterns used per channel int transformed; // if 0, deltas are unsigned and no transform; otherwise, signed and transformed int mode; // associated mode value int modebits; // number of mode bits const char *encoding; // verilog description of encoding for this mode }; #define NPATTERNS 1 #define NREGIONS 2 static Pattern patterns[NPATTERNS] = { // red green blue alpha xfm mode mb 5,5,5,5, 5,5,5,5, 5,5,5,5, 5,5,5,5, 0, 0x80, 8, "", }; struct RegionPrec { int endpt_a_prec[NCHANNELS_RGBA]; int endpt_b_prec[NCHANNELS_RGBA]; }; struct PatternPrec { RegionPrec region_precs[NREGIONS]; }; // this is the precision for each channel and region // NOTE: this MUST match the corresponding data in "patterns" above -- WARNING: there is NO nvAssert to check this! static PatternPrec pattern_precs[NPATTERNS] = { 5,5,5,5, 5,5,5,5, 5,5,5,5, 5,5,5,5, }; // return # of bits needed to store n. handle signed or unsigned cases properly static int nbits(int n, bool issigned) { int nb; if (n==0) return 0; // no bits needed for 0, signed or not else if (n > 0) { for (nb=0; n; ++nb, n>>=1) ; return nb + (issigned?1:0); } else { nvAssert (issigned); for (nb=0; n<-1; ++nb, n>>=1) ; return nb + 1; } } static void transform_forward(IntEndptsRGBA_2 ep[NREGIONS]) { nvUnreachable(); } static void transform_inverse(IntEndptsRGBA_2 ep[NREGIONS]) { nvUnreachable(); } /* we're using this table to assign lsbs abgr >=2 correct 0000 0 0 0001 0 0 0010 0 0 0011 1 x1 0100 0 0 0101 1 x1 0110 1 x1 0111 1 1 1000 0 0 1001 1 x0 1010 1 x0 1011 1 1 1100 1 x0 1101 1 1 1110 1 1 1111 1 1 we need 8 0's and 8 1's. the x's can be either 0 or 1 as long as you get 8/8. I choose to assign the lsbs so that the rgb channels are as good as possible. */ // 6666 ->5555.1, use the "correct" column above to assign the lsb static void compress_one(const IntEndptsRGBA& endpts, IntEndptsRGBA_2& compr_endpts) { int onescnt; onescnt = 0; for (int j=0; j> 1; nvAssert (compr_endpts.A[j] < 32); } compr_endpts.a_lsb = onescnt >= 2; onescnt = 0; for (int j=0; j> 1; nvAssert (compr_endpts.B[j] < 32); } compr_endpts.b_lsb = onescnt >= 2; } static void uncompress_one(const IntEndptsRGBA_2& compr_endpts, IntEndptsRGBA& endpts) { for (int j=0; j> 2) & 3 and x = index & 3 static void swap_indices(IntEndptsRGBA_2 endpts[NREGIONS], int indices[Tile::TILE_H][Tile::TILE_W], int shapeindex) { for (int region = 0; region < NREGIONS; ++region) { int position = SHAPEINDEX_TO_COMPRESSED_INDICES(shapeindex,region); int x = POS_TO_X(position); int y = POS_TO_Y(position); nvAssert(REGION(x,y,shapeindex) == region); // double check the table if (indices[y][x] & HIGH_INDEXBIT) { // high bit is set, swap the endpts and indices for this region int t; for (int i=0; i= 0 && pat_index < NPATTERNS); nvAssert (in.getptr() == patterns[pat_index].modebits); shapeindex = in.read(SHAPEBITS); p = patterns[pat_index]; for (int j=0; j 0; ++j) { err = !AVPCL::flag_premult ? Utils::metric4(colors[i], palette[j]) : Utils::metric4premult(colors[i], palette[j]) ; if (err > besterr) // error increased, so we're done searching break; if (err < besterr) { besterr = err; indices[i] = j; } } toterr += besterr; // check for early exit if (toterr > current_err) { // fill out bogus index values so it's initialized at least for (int k = i; k < np; ++k) indices[k] = -1; return FLT_MAX; } } return toterr; } // assign indices given a tile, shape, and quantized endpoints, return toterr for each region static void assign_indices(const Tile &tile, int shapeindex, IntEndptsRGBA_2 endpts[NREGIONS], const PatternPrec &pattern_prec, int indices[Tile::TILE_H][Tile::TILE_W], float toterr[NREGIONS]) { // build list of possibles Vector4 palette[NREGIONS][NINDICES]; for (int region = 0; region < NREGIONS; ++region) { generate_palette_quantized(endpts[region], pattern_prec.region_precs[region], &palette[region][0]); toterr[region] = 0; } Vector4 err; for (int y = 0; y < tile.size_y; y++) for (int x = 0; x < tile.size_x; x++) { int region = REGION(x,y,shapeindex); float err, besterr = FLT_MAX; for (int i = 0; i < NINDICES && besterr > 0; ++i) { err = !AVPCL::flag_premult ? Utils::metric4(tile.data[y][x], palette[region][i]) : Utils::metric4premult(tile.data[y][x], palette[region][i]) ; if (err > besterr) // error increased, so we're done searching break; if (err < besterr) { besterr = err; indices[y][x] = i; } } toterr[region] += besterr; } } // note: indices are valid only if the value returned is less than old_err; otherwise they contain -1's // this function returns either old_err or a value smaller (if it was successful in improving the error) static float perturb_one(const Vector4 colors[], const float importance[], int np, int ch, const RegionPrec ®ion_prec, const IntEndptsRGBA_2 &old_endpts, IntEndptsRGBA_2 &new_endpts, float old_err, int do_b, int indices[Tile::TILE_TOTAL]) { // we have the old endpoints: old_endpts // we have the perturbed endpoints: new_endpts // we have the temporary endpoints: temp_endpts IntEndptsRGBA_2 temp_endpts; float min_err = old_err; // start with the best current error int beststep; int temp_indices[Tile::TILE_TOTAL]; for (int i=0; i>= 1) { bool improved = false; for (int sign = -1; sign <= 1; sign += 2) { if (do_b == 0) { temp_endpts.A[ch] = new_endpts.A[ch] + sign * step; if (temp_endpts.A[ch] < 0 || temp_endpts.A[ch] >= (1 << prec)) continue; } else { temp_endpts.B[ch] = new_endpts.B[ch] + sign * step; if (temp_endpts.B[ch] < 0 || temp_endpts.B[ch] >= (1 << prec)) continue; } float err = map_colors(colors, importance, np, temp_endpts, region_prec, min_err, temp_indices); if (err < min_err) { improved = true; min_err = err; beststep = sign * step; for (int i=0; i 5000 perturb endpoints 50% of precision // if err > 1000 25% // if err > 200 12.5% // if err > 40 6.25% // for np = 16 -- adjust error thresholds as a function of np // always ensure endpoint ordering is preserved (no need to overlap the scan) // if orig_err returned from this is less than its input value, then indices[] will contain valid indices static float exhaustive(const Vector4 colors[], const float importance[], int np, int ch, const RegionPrec ®ion_prec, float orig_err, IntEndptsRGBA_2 &opt_endpts, int indices[Tile::TILE_TOTAL]) { IntEndptsRGBA_2 temp_endpts; float best_err = orig_err; int aprec = region_prec.endpt_a_prec[ch]; int bprec = region_prec.endpt_b_prec[ch]; int good_indices[Tile::TILE_TOTAL]; int temp_indices[Tile::TILE_TOTAL]; for (int i=0; i 5000.0*thr_scale) { adelta = (1 << aprec)/2; bdelta = (1 << bprec)/2; } else if (orig_err > 1000.0*thr_scale) { adelta = (1 << aprec)/4; bdelta = (1 << bprec)/4; } else if (orig_err > 200.0*thr_scale) { adelta = (1 << aprec)/8; bdelta = (1 << bprec)/8; } else if (orig_err > 40.0*thr_scale) { adelta = (1 << aprec)/16; bdelta = (1 << bprec)/16; } adelta = max(adelta, 3); bdelta = max(bdelta, 3); #ifdef DISABLE_EXHAUSTIVE adelta = bdelta = 3; #endif temp_endpts = opt_endpts; // ok figure out the range of A and B int alow = max(0, opt_endpts.A[ch] - adelta); int ahigh = min((1<= initial_error) break rgb0 += delta0 next = 1 else if (err1 >= initial_error) break rgb1 += delta1 next = 0 initial_err = map() for (;;) err = perturb(next ? rgb1:rgb0, delta) if (err >= initial_err) break next? rgb1 : rgb0 += delta initial_err = err */ IntEndptsRGBA_2 new_a, new_b; IntEndptsRGBA_2 new_endpt; int do_b; int orig_indices[Tile::TILE_TOTAL]; int new_indices[Tile::TILE_TOTAL]; int temp_indices0[Tile::TILE_TOTAL]; int temp_indices1[Tile::TILE_TOTAL]; // now optimize each channel separately // for the first error improvement, we save the indices. then, for any later improvement, we compare the indices // if they differ, we restart the loop (which then falls back to looking for a first improvement.) for (int ch = 0; ch < NCHANNELS_RGBA; ++ch) { // figure out which endpoint when perturbed gives the most improvement and start there // if we just alternate, we can easily end up in a local minima float err0 = perturb_one(colors, importance, np, ch, region_prec, opt_endpts, new_a, opt_err, 0, temp_indices0); // perturb endpt A float err1 = perturb_one(colors, importance, np, ch, region_prec, opt_endpts, new_b, opt_err, 1, temp_indices1); // perturb endpt B if (err0 < err1) { if (err0 >= opt_err) continue; for (int i=0; i= opt_err) continue; for (int i=0; i= opt_err) break; for (int i=0; i> 1) & 1; // make sure we have a valid error for temp_in // we use FLT_MAX here because we want an accurate temp_in_err, no shortcuts // (mapcolors will compute a mapping but will stop if the error exceeds the value passed in the FLT_MAX position) float temp_in_err = map_colors(pixels, importance, np, temp_in, pattern_prec.region_precs[region], FLT_MAX, temp_indices); // now try to optimize these endpoints float temp_out_err = optimize_one(pixels, importance, np, temp_in_err, temp_in, pattern_prec.region_precs[region], temp_out); // if we find an improvement, update the best so far and correct the output endpoints and errors if (temp_out_err < best_err) { best_err = temp_out_err; opt_err[region] = temp_out_err; opt_endpts[region] = temp_out; } } } } /* optimization algorithm for each pattern convert endpoints using pattern precision assign indices and get initial error compress indices (and possibly reorder endpoints) transform endpoints if transformed endpoints fit pattern get original endpoints back optimize endpoints, get new endpoints, new indices, and new error // new error will almost always be better compress new indices transform new endpoints if new endpoints fit pattern AND if error is improved emit compressed block with new data else emit compressed block with original data // to try to preserve maximum endpoint precision */ static float refine(const Tile &tile, int shapeindex_best, const FltEndpts endpts[NREGIONS], char *block) { float orig_err[NREGIONS], opt_err[NREGIONS], orig_toterr, opt_toterr, expected_opt_err[NREGIONS]; IntEndptsRGBA_2 orig_endpts[NREGIONS], opt_endpts[NREGIONS]; int orig_indices[Tile::TILE_H][Tile::TILE_W], opt_indices[Tile::TILE_H][Tile::TILE_W]; for (int sp = 0; sp < NPATTERNS; ++sp) { quantize_endpts(endpts, pattern_precs[sp], orig_endpts); assign_indices(tile, shapeindex_best, orig_endpts, pattern_precs[sp], orig_indices, orig_err); swap_indices(orig_endpts, orig_indices, shapeindex_best); if (patterns[sp].transformed) transform_forward(orig_endpts); // apply a heuristic here -- we check if the endpoints fit before we try to optimize them. // the assumption made is that if they don't fit now, they won't fit after optimizing. if (endpts_fit(orig_endpts, patterns[sp])) { if (patterns[sp].transformed) transform_inverse(orig_endpts); optimize_endpts(tile, shapeindex_best, orig_err, orig_endpts, pattern_precs[sp], expected_opt_err, opt_endpts); assign_indices(tile, shapeindex_best, opt_endpts, pattern_precs[sp], opt_indices, opt_err); // (nreed) Commented out asserts because they go off all the time...not sure why //for (int i=0; i 255.0f) v.x = 255.0f; if (v.y < 0.0f) v.y = 0.0f; if (v.y > 255.0f) v.y = 255.0f; if (v.z < 0.0f) v.z = 0.0f; if (v.z > 255.0f) v.z = 255.0f; if (v.w < 0.0f) v.w = 0.0f; if (v.w > 255.0f) v.w = 255.0f; } static void generate_palette_unquantized(const FltEndpts endpts[NREGIONS], Vector4 palette[NREGIONS][NINDICES]) { for (int region = 0; region < NREGIONS; ++region) for (int i = 0; i < NINDICES; ++i) palette[region][i] = Utils::lerp(endpts[region].A, endpts[region].B, i, 0, DENOM); } // generate a palette from unquantized endpoints, then pick best palette color for all pixels in each region, return toterr for all regions combined static float map_colors(const Tile &tile, int shapeindex, const FltEndpts endpts[NREGIONS]) { // build list of possibles Vector4 palette[NREGIONS][NINDICES]; generate_palette_unquantized(endpts, palette); float toterr = 0; Vector4 err; for (int y = 0; y < tile.size_y; y++) for (int x = 0; x < tile.size_x; x++) { int region = REGION(x,y,shapeindex); float err, besterr = FLT_MAX; for (int i = 0; i < NINDICES && besterr > 0; ++i) { err = Utils::metric4(tile.data[y][x], palette[region][i]); if (err > besterr) // error increased, so we're done searching. this works for most norms. break; if (err < besterr) besterr = err; } toterr += besterr; } return toterr; } static float rough(const Tile &tile, int shapeindex, FltEndpts endpts[NREGIONS]) { for (int region=0; region maxp) maxp = dp; } // choose as endpoints 2 points along the principal direction that span the projections of all of the pixel values endpts[region].A = mean + minp*direction; endpts[region].B = mean + maxp*direction; // clamp endpoints // the argument for clamping is that the actual endpoints need to be clamped and thus we need to choose the best // shape based on endpoints being clamped clamp(endpts[region].A); clamp(endpts[region].B); } return map_colors(tile, shapeindex, endpts); } static void swap(float *list1, int *list2, int i, int j) { float t = list1[i]; list1[i] = list1[j]; list1[j] = t; int t1 = list2[i]; list2[i] = list2[j]; list2[j] = t1; } float AVPCL::compress_mode7(const Tile &t, char *block) { // number of rough cases to look at. reasonable values of this are 1, NSHAPES/4, and NSHAPES // NSHAPES/4 gets nearly all the cases; you can increase that a bit (say by 3 or 4) if you really want to squeeze the last bit out const int NITEMS=NSHAPES/4; // pick the best NITEMS shapes and refine these. struct { FltEndpts endpts[NREGIONS]; } all[NSHAPES]; float roughmse[NSHAPES]; int index[NSHAPES]; char tempblock[AVPCL::BLOCKSIZE]; float msebest = FLT_MAX; for (int i=0; i roughmse[j]) swap(roughmse, index, i, j); for (int i=0; i0; ++i) { int shape = index[i]; float mse = refine(t, shape, &all[shape].endpts[0], tempblock); if (mse < msebest) { memcpy(block, tempblock, sizeof(tempblock)); msebest = mse; } } return msebest; }