/* * ScreenPressor version 3 decoder * * Copyright (c) 2017 Paul B Mahol * * This file is part of FFmpeg. * * FFmpeg is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * FFmpeg is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with FFmpeg; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include #include #include #include "libavutil/qsort.h" #include "avcodec.h" #include "bytestream.h" #include "internal.h" #include "scpr.h" static void renew_table3(uint32_t nsym, uint32_t *cntsum, uint16_t *freqs, uint16_t *freqs1, uint16_t *cnts, uint8_t *dectab) { uint32_t a = 0, b = 4096 / nsym, c = b - (b >> 1); *cntsum = c * nsym; for (int d = 0; d < nsym; d++) { freqs[d] = b; freqs1[d] = a; cnts[d] = c; for (int q = a + 128 - 1 >> 7, f = (a + b - 1 >> 7) + 1; q < f; q++) dectab[q] = d; a += b; } } static void reinit_tables3(SCPRContext * s) { for (int i = 0; i < 3; i++) { for (int j = 0; j < 4096; j++) { PixelModel3 *m = &s->pixel_model3[i][j]; m->type = 0; } } for (int i = 0; i < 6; i++) { renew_table3(256, &s->run_model3[i].cntsum, s->run_model3[i].freqs[0], s->run_model3[i].freqs[1], s->run_model3[i].cnts, s->run_model3[i].dectab); } renew_table3(256, &s->range_model3.cntsum, s->range_model3.freqs[0], s->range_model3.freqs[1], s->range_model3.cnts, s->range_model3.dectab); renew_table3(5, &s->fill_model3.cntsum, s->fill_model3.freqs[0], s->fill_model3.freqs[1], s->fill_model3.cnts, s->fill_model3.dectab); renew_table3(256, &s->count_model3.cntsum, s->count_model3.freqs[0], s->count_model3.freqs[1], s->count_model3.cnts, s->count_model3.dectab); for (int i = 0; i < 4; i++) { renew_table3(16, &s->sxy_model3[i].cntsum, s->sxy_model3[i].freqs[0], s->sxy_model3[i].freqs[1], s->sxy_model3[i].cnts, s->sxy_model3[i].dectab); } for (int i = 0; i < 2; i++) { renew_table3(512, &s->mv_model3[i].cntsum, s->mv_model3[i].freqs[0], s->mv_model3[i].freqs[1], s->mv_model3[i].cnts, s->mv_model3[i].dectab); } for (int i = 0; i < 6; i++) { renew_table3(6, &s->op_model3[i].cntsum, s->op_model3[i].freqs[0], s->op_model3[i].freqs[1], s->op_model3[i].cnts, s->op_model3[i].dectab); } } static int decode3(GetByteContext *gb, RangeCoder *rc, uint32_t a, uint32_t b) { uint32_t code = a * (rc->code >> 12) + (rc->code & 0xFFF) - b; while (code < 0x800000 && bytestream2_get_bytes_left(gb) > 0) code = bytestream2_get_byteu(gb) | (code << 8); rc->code = code; return 0; } static void rescale(PixelModel3 *m, int *totfr) { uint32_t a; a = 256 - m->size; for (int b = 0; b < m->size; b++) { m->freqs[b] -= m->freqs[b] >> 1; a += m->freqs[b]; } *totfr = a; } static int add_symbol(PixelModel3 *m, int index, uint32_t symbol, int *totfr, int max) { if (m->size == max) return 0; for (int c = m->size - 1; c >= index; c--) { m->symbols[c + 1] = m->symbols[c]; m->freqs[c + 1] = m->freqs[c]; } m->symbols[index] = symbol; m->freqs[index] = 50; m->size++; if (m->maxpos >= index) m->maxpos++; *totfr += 50; if (*totfr + 50 > 4096) rescale(m, totfr); return 1; } static int decode_adaptive45(PixelModel3 *m, int rccode, uint32_t *value, uint16_t *a, uint16_t *b, uint32_t *c, int max) { uint32_t q, g, maxpos, d, e = *c, totfr = *c; int ret; for (d = 0; e <= 2048; d++) e <<= 1; maxpos = m->maxpos; rccode >>= d; *c = m->freqs[maxpos]; m->freqs[maxpos] += 4096 - e >> d; for (q = 0, g = 0, e = 0; q < m->size; q++) { uint32_t f = m->symbols[q]; uint32_t p = e + f - g; uint32_t k = m->freqs[q]; if (rccode < p) { *value = rccode - e + g; *b = rccode << d; *a = 1 << d; m->freqs[maxpos] = *c; ret = add_symbol(m, q, *value, &totfr, max); *c = totfr; return ret; } if (p + k > rccode) { *value = f; e += *value - g; *b = e << d; *a = k << d; m->freqs[maxpos] = *c; m->freqs[q] += 50; totfr += 50; if ((q != maxpos) && (m->freqs[q] > m->freqs[maxpos])) m->maxpos = q; if (totfr + 50 > 4096) rescale(m, &totfr); *c = totfr; return 1; } e += f - g + k; g = f + 1; } m->freqs[maxpos] = *c; *value = g + rccode - e; *b = rccode << d; *a = 1 << d; ret = add_symbol(m, q, *value, &totfr, max); *c = totfr; return ret; } static int update_model6_to_7(PixelModel3 *m) { PixelModel3 n = {0}; int c, d, e, f, k, p, length, i, j, index; uint16_t *freqs, *freqs1, *cnts; n.type = 7; length = m->length; freqs = n.freqs; freqs1 = n.freqs1; cnts = n.cnts; n.cntsum = m->cnts[length]; for (i = 0; i < length; i++) { if (!m->cnts[i]) continue; index = m->symbols[i]; freqs[index] = m->freqs[2 * i]; freqs1[index] = m->freqs[2 * i + 1]; cnts[index] = m->cnts[i]; } c = 1 << m->fshift; d = c - (c >> 1); for (j = 0, e = 0; j < 256; j++) { f = freqs[j]; if (!f) { f = c; freqs[j] = c; freqs1[j] = e; cnts[j] = d; } p = (e + 127) >> 7; k = ((f + e - 1) >> 7) + 1; if (k > FF_ARRAY_ELEMS(n.dectab)) return AVERROR_INVALIDDATA; for (i = 0; i < k - p; i++) n.dectab[p + i] = j; e += f; } memcpy(m, &n, sizeof(n)); return 0; } static void calc_sum(PixelModel3 *m) { uint32_t a; int len; len = m->length; a = 256 - m->size << (m->fshift > 0 ? m->fshift - 1 : 0); for (int c = 0; c < len; c++) a += m->cnts[c]; m->cnts[len] = a; } static void rescale_dec(PixelModel3 *m) { uint16_t cnts[256] = {0}; uint16_t freqs[512] = {0}; int b, c, e, g; uint32_t a; for (a = 1 << (0 < m->fshift ? m->fshift - 1 : 0), b = 0; b < 256; b++) cnts[b] = a; for (a = 0, b = m->size; a < b; a++) cnts[m->symbols[a]] = m->cnts[a]; for (b = a = 0; b < 256; b++) { freqs[2 * b] = cnts[b]; freqs[2 * b + 1] = a; a += cnts[b]; } if (m->fshift > 0) m->fshift--; a = 256 - m->size << (0 < m->fshift ? m->fshift - 1 : 0); for (b = 0, c = m->size; b < c; b++) { m->cnts[b] -= m->cnts[b] >> 1; a = a + m->cnts[b]; e = m->symbols[b]; g = freqs[2 * e + 1]; m->freqs[2 * b] = freqs[2 * e]; m->freqs[2 * b + 1] = g; } m->cnts[m->length] = a; } static int update_model5_to_6(PixelModel3 *m, uint8_t value) { PixelModel3 n = {0}; int c, d, e, f, g, k, q, p; n.type = 6; n.length = 32; for (c = m->size, d = 256 - c, e = 0; e < c; e++) d = d + m->freqs[e]; for (e = 0; d <= 2048; e++) d <<= 1; for (q = d = 0, g = q = 0; g < c; g++) { p = m->symbols[g]; d = d + (p - q); q = m->freqs[g]; k = q << e; n.freqs[2 * g] = k; n.freqs[2 * g + 1] = d << e; n.cnts[g] = k - (k >> 1); n.symbols[g] = p; d += q; q = p + 1; } n.fshift = e; e = 1 << n.fshift; d = 0; if (value > 0) { d = -1; for (p = f = g = 0; p < c; p++) { k = n.symbols[p]; if (k > d && k < value) { d = k; g = n.freqs[2 * p]; f = n.freqs[2 * p + 1]; } } d = 0 < g ? f + g + (value - d - 1 << n.fshift) : value << n.fshift; } n.freqs[2 * c] = e; n.freqs[2 * c + 1] = d; n.cnts[c] = e - (e >> 1); n.symbols[c] = value; n.size = c + 1; e = 25 << n.fshift; n.cnts[c] += e; n.cnts[32] += e; if (n.cnts[32] + e > 4096) rescale_dec(&n); calc_sum(&n); for (c = 0, e = n.size - 1; c < e; c++) { for (g = c + 1, f = n.size; g < f; g++) { if (q = n.freqs[2 * g], k = n.freqs[2 * c], q > k) { int l = n.freqs[2 * c + 1]; int h = n.freqs[2 * g + 1]; n.freqs[2 * c] = q; n.freqs[2 * c + 1] = h; n.freqs[2 * g] = k; n.freqs[2 * g + 1] = l; FFSWAP(uint16_t, n.cnts[c], n.cnts[g]); FFSWAP(uint8_t, n.symbols[c], n.symbols[g]); } } } memcpy(m, &n, sizeof(n)); return 0; } static void grow_dec(PixelModel3 *m) { int a; a = 2 * m->length; m->cnts[2 * m->length] = m->cnts[m->length]; m->length = a; } static int add_dec(PixelModel3 *m, int sym, int f1, int f2) { int size; if (m->size >= 40 || m->size >= m->length) return -1; size = m->size; m->symbols[size] = sym; m->freqs[2 * size] = f1; m->freqs[2 * size + 1] = f2; m->cnts[size] = f1 - (f1 >> 1); m->size++; return size; } static void incr_cntdec(PixelModel3 *m, int a) { int b, len, d, e, g; b = 25 << m->fshift; len = m->length; m->cnts[a] += b; m->cnts[len] += b; if (a > 0 && m->cnts[a] > m->cnts[a - 1]) { FFSWAP(uint16_t, m->cnts[a], m->cnts[a - 1]); d = m->freqs[2 * a]; e = m->freqs[2 * a + 1]; g = m->freqs[2 * (a - 1) + 1]; m->freqs[2 * a] = m->freqs[2 * (a - 1)]; m->freqs[2 * a + 1] = g; g = a - 1; m->freqs[2 * g] = d; m->freqs[2 * g + 1] = e; FFSWAP(uint8_t, m->symbols[a], m->symbols[a - 1]); } if (m->cnts[len] + b > 4096) rescale_dec(m); } static int decode_adaptive6(PixelModel3 *m, uint32_t code, uint32_t *value, uint16_t *a, uint16_t *b) { int c, d, e, f, g, q; for (c = 0, d = 0, e = 0, f = 0, g = 0, q = m->size; g < q; g++) { uint32_t p = m->freqs[2 * g + 1]; if (p <= code) { uint32_t k = m->freqs[2 * g]; if (p + k > code) { *value = m->symbols[g]; *a = k; *b = p; incr_cntdec(m, g); return 1; } if (p >= d) { c = k; d = p; e = m->symbols[g]; } } } g = 1 << m->fshift; q = f = 0; if (c > 0) { f = code - (d + c) >> m->fshift; q = f + e + 1; f = d + c + (f << m->fshift); } else { q = code >> m->fshift; f = q << m->fshift; } *a = g; *b = f; *value = q; c = add_dec(m, q, g, f); if (c < 0) { if (m->length == 64) return 0; grow_dec(m); c = add_dec(m, q, g, f); if (c < 0) return AVERROR_INVALIDDATA; } incr_cntdec(m, c); return 1; } static int cmpbytes(const void *p1, const void *p2) { int left = *(const uint8_t *)p1; int right = *(const uint8_t *)p2; return FFDIFFSIGN(left, right); } static int update_model1_to_2(PixelModel3 *m, uint32_t val) { PixelModel3 n = {0}; int i, b; n.type = 2; n.size = m->size + 1; b = m->size; for (i = 0; i < b; i++) n.symbols[i] = m->symbols[i]; n.symbols[b] = val; memcpy(m, &n, sizeof(n)); return 0; } static int update_model1_to_4(PixelModel3 *m, uint32_t val) { PixelModel3 n = {0}; int size, i; size = m->size; n.type = 4; n.size = size; for (i = 0; i < n.size; i++) { n.symbols[i] = m->symbols[i]; } AV_QSORT(n.symbols, size, uint8_t, cmpbytes); for (i = 0; i < n.size; i++) { if (val == n.symbols[i]) { n.freqs[i] = 100; n.maxpos = i; } else { n.freqs[i] = 50; } } memcpy(m, &n, sizeof(n)); return 0; } static int update_model1_to_5(PixelModel3 *m, uint32_t val) { PixelModel3 n = {0}; int i, size, freqs; uint32_t a; size = m->size; n.size = size; for (i = 0; i < size; i++) { n.symbols[i] = m->symbols[i]; } AV_QSORT(n.symbols, size, uint8_t, cmpbytes); size = n.size; for (i = 0; i < size; i++) { if (val == n.symbols[i]) { n.freqs[i] = 100; n.maxpos = i; } else { n.freqs[i] = 50; } } a = 256 - size; for (i = 0; i < size; i++, a += freqs) freqs = n.freqs[i]; n.type = 5; n.cntsum = a; memcpy(m, &n, sizeof(n)); return 0; } static int decode_static1(PixelModel3 *m, uint32_t val) { uint32_t size; size = m->size; for (int i = 0; i < size; i++) { if (val == m->symbols[i]) { if (size <= 4) return update_model1_to_4(m, val); else return update_model1_to_5(m, val); } } if (size >= 14) return update_model1_to_2(m, val); m->symbols[size] = val; m->size++; return 0; } static int update_model2_to_6(PixelModel3 *m, uint8_t value, int a4) { PixelModel3 n = {0}; int c, d, e, f, g, q; n.type = 6; n.length = a4; memset(n.symbols, 1u, a4); c = m->size; d = 256 - c + (64 * c + 64); for (e = 0; d <= 2048; e++) { d <<= 1; } g = q = 0; AV_QSORT(m->symbols, c, uint8_t, cmpbytes); for (f = d = 0; f < c; f++) { int p = f; int k = m->symbols[p]; int l; g = g + (k - q); if (k == value) { d = p; q = 128; } else { q = 64; } l = q << e; n.freqs[2 * p] = l; n.freqs[2 * p + 1] = g << e; n.symbols[p] = k; n.cnts[p] = l - (l >> 1); g += q; q = k + 1; } n.size = c; n.fshift = e; calc_sum(&n); if (d > 0) { c = n.freqs[0]; e = n.freqs[1]; g = n.freqs[2 * d + 1]; n.freqs[0] = n.freqs[2 * d]; n.freqs[1] = g; n.freqs[2 * d] = c; n.freqs[2 * d + 1] = e; FFSWAP(uint16_t, n.cnts[0], n.cnts[d]); FFSWAP(uint8_t, n.symbols[0], n.symbols[d]); } memcpy(m, &n, sizeof(n)); return 0; } static int update_model2_to_3(PixelModel3 *m, uint32_t val) { PixelModel3 n = {0}; uint32_t size; n.type = 3; n.size = m->size + 1; size = m->size; for (int i = 0; i < size; i++) n.symbols[i] = m->symbols[i]; n.symbols[size] = val; memcpy(m, &n, sizeof(n)); return 0; } static int decode_static2(PixelModel3 *m, uint32_t val) { uint32_t size; size = m->size; for (int i = 0; i < size; i++) { if (val == m->symbols[i]) { int a; if (m->size <= 32) a = 32; else a = 64; return update_model2_to_6(m, val, a); } } if (size >= 64) return update_model2_to_3(m, val); m->symbols[size] = val; m->size++; return 0; } static int update_model3_to_7(PixelModel3 *m, uint8_t value) { PixelModel3 n = {0}; int c, d, e, f, g, q; n.type = 7; for (c = 0; c < 256; c++) { d = c; n.freqs[d] = 1; n.cnts[d] = 1; } for (c = m->size, d = (4096 - (256 - c)) / (c + 1) | 0, e = d - (d >> 1), g = 0; g < c;) { q = g++; q = m->symbols[q]; n.freqs[q] = d; n.cnts[q] = e; } n.freqs[value] += d; n.cnts[value] += 16; for (d = c = n.cntsum = 0; 256 > d; d++) { e = d; n.cntsum += n.cnts[e]; n.freqs1[e] = c; g = n.freqs[e]; f = (c + g - 1 >> 7) + 1; if (f > FF_ARRAY_ELEMS(n.dectab)) return AVERROR_INVALIDDATA; for (q = c + 128 - 1 >> 7; q < f; q++) { n.dectab[q] = e; } c += g; } memcpy(m, &n, sizeof(n)); return 0; } static int decode_static3(PixelModel3 *m, uint32_t val) { uint32_t size = m->size; for (int i = 0; i < size; i++) { if (val == m->symbols[i]) return update_model3_to_7(m, val); } if (size >= 256) return 0; m->symbols[size] = val; m->size++; return 0; } static void sync_code3(GetByteContext *gb, RangeCoder *rc) { rc->code1++; if (rc->code1 == 0x20000) { rc->code = bytestream2_get_le32(gb); rc->code1 = 0; } } static int decode_value3(SCPRContext *s, uint32_t max, uint32_t *cntsum, uint16_t *freqs1, uint16_t *freqs2, uint16_t *cnts, uint8_t *dectable, uint32_t *value) { GetByteContext *gb = &s->gb; RangeCoder *rc = &s->rc; uint32_t r, y, a, b, e, g, q; r = dectable[(rc->code & 0xFFFu) >> 7]; if (r < max) { while (freqs2[r + 1] <= (rc->code & 0xFFF)) { if (++r >= max) break; } } if (r > max) return AVERROR_INVALIDDATA; cnts[r] += 16; a = freqs1[r]; b = freqs2[r]; *cntsum += 16; if (*cntsum + 16 > 4096) { *cntsum = 0; for (int c = 0, i = 0; i < max + 1; i++) { e = cnts[i]; freqs2[i] = c; freqs1[i] = e; g = (c + 127) >> 7; c += e; q = ((c - 1) >> 7) + 1; if (q > g) { for (int j = 0; j < q - g; j++) dectable[j + g] = i; } y = e - (e >> 1); cnts[i] = y; *cntsum += y; } } decode3(gb, rc, a, b); sync_code3(gb, rc); *value = r; return 0; } static void calc_sum5(PixelModel3 *m) { uint32_t a; a = 256 - m->size; for (int b = 0; b < m->size; b++) a += m->freqs[b]; m->cntsum = a; } static int update_model4_to_5(PixelModel3 *m, uint32_t value) { PixelModel3 n = {0}; int c, e, g, totfr; n.type = 5; for (c = 0, e = 0; c < m->size && m->symbols[c] < value; c++) { n.symbols[c] = m->symbols[c]; e += n.freqs[c] = m->freqs[c]; } g = c; n.symbols[g] = value; e += n.freqs[g++] = 50; for (; c < m->size; g++, c++) { n.symbols[g] = m->symbols[c]; e += n.freqs[g] = m->freqs[c]; } n.size = m->size + 1; if (e > 4096) rescale(&n, &totfr); calc_sum5(&n); memcpy(m, &n, sizeof(n)); return 0; } static int decode_unit3(SCPRContext *s, PixelModel3 *m, uint32_t code, uint32_t *value) { GetByteContext *gb = &s->gb; RangeCoder *rc = &s->rc; uint16_t a = 0, b = 0; uint32_t param; int type; int ret; type = m->type; switch (type) { case 0: *value = bytestream2_get_byte(&s->gb); m->type = 1; m->size = 1; m->symbols[0] = *value; sync_code3(gb, rc); break; case 1: *value = bytestream2_get_byte(&s->gb); decode_static1(m, *value); sync_code3(gb, rc); break; case 2: *value = bytestream2_get_byte(&s->gb); decode_static2(m, *value); sync_code3(gb, rc); break; case 3: *value = bytestream2_get_byte(&s->gb); ret = decode_static3(m, *value); if (ret < 0) return AVERROR_INVALIDDATA; sync_code3(gb, rc); break; case 4: param = m->freqs[0] + m->freqs[1] + m->freqs[2] + m->freqs[3] + 256 - m->size; if (!decode_adaptive45(m, code, value, &a, &b, ¶m, 4)) update_model4_to_5(m, *value); decode3(gb, rc, a, b); sync_code3(gb, rc); break; case 5: if (!decode_adaptive45(m, code, value, &a, &b, &m->cntsum, 16)) update_model5_to_6(m, *value); decode3(gb, rc, a, b); sync_code3(gb, rc); break; case 6: ret = decode_adaptive6(m, code, value, &a, &b); if (!ret) ret = update_model6_to_7(m); if (ret < 0) return ret; decode3(gb, rc, a, b); sync_code3(gb, rc); break; case 7: return decode_value3(s, 255, &m->cntsum, m->freqs, m->freqs1, m->cnts, m->dectab, value); } if (*value > 255) return AVERROR_INVALIDDATA; return 0; } static int decode_units3(SCPRContext * s, uint32_t *red, uint32_t *green, uint32_t *blue, int *cx, int *cx1) { RangeCoder *rc = &s->rc; int ret; ret = decode_unit3(s, &s->pixel_model3[0][*cx + *cx1], rc->code & 0xFFF, red); if (ret < 0) return ret; *cx1 = (*cx << 6) & 0xFC0; *cx = *red >> 2; ret = decode_unit3(s, &s->pixel_model3[1][*cx + *cx1], rc->code & 0xFFF, green); if (ret < 0) return ret; *cx1 = (*cx << 6) & 0xFC0; *cx = *green >> 2; ret = decode_unit3(s, &s->pixel_model3[2][*cx + *cx1], rc->code & 0xFFF, blue); if (ret < 0) return ret; *cx1 = (*cx << 6) & 0xFC0; *cx = *blue >> 2; return 0; } static void init_rangecoder3(RangeCoder *rc, GetByteContext *gb) { rc->code = bytestream2_get_le32(gb); rc->code1 = 0; } static int decompress_i3(AVCodecContext *avctx, uint32_t *dst, int linesize) { SCPRContext *s = avctx->priv_data; GetByteContext *gb = &s->gb; RangeCoder *rc = &s->rc; int cx = 0, cx1 = 0, k = 0; int run, off, y = 0, x = 0, ret; uint32_t backstep = linesize - avctx->width; uint32_t clr = 0, lx, ly, ptype, r, g, b; bytestream2_skip(gb, 1); init_rangecoder3(rc, gb); reinit_tables3(s); while (k < avctx->width + 1) { ret = decode_units3(s, &r, &g, &b, &cx, &cx1); if (ret < 0) return ret; ret = decode_value3(s, 255, &s->run_model3[0].cntsum, s->run_model3[0].freqs[0], s->run_model3[0].freqs[1], s->run_model3[0].cnts, s->run_model3[0].dectab, &run); if (ret < 0) return ret; if (run <= 0) return AVERROR_INVALIDDATA; clr = (b << 16) + (g << 8) + r; k += run; while (run-- > 0) { if (y >= avctx->height) return AVERROR_INVALIDDATA; dst[y * linesize + x] = clr; lx = x; ly = y; x++; if (x >= avctx->width) { x = 0; y++; } } } off = -linesize - 1; ptype = 0; while (x < avctx->width && y < avctx->height) { ret = decode_value3(s, 5, &s->op_model3[ptype].cntsum, s->op_model3[ptype].freqs[0], s->op_model3[ptype].freqs[1], s->op_model3[ptype].cnts, s->op_model3[ptype].dectab, &ptype); if (ret < 0) return ret; if (ptype == 0) { ret = decode_units3(s, &r, &g, &b, &cx, &cx1); if (ret < 0) return ret; clr = (b << 16) + (g << 8) + r; } if (ptype > 5) return AVERROR_INVALIDDATA; ret = decode_value3(s, 255, &s->run_model3[ptype].cntsum, s->run_model3[ptype].freqs[0], s->run_model3[ptype].freqs[1], s->run_model3[ptype].cnts, s->run_model3[ptype].dectab, &run); if (ret < 0) return ret; if (run <= 0) return AVERROR_INVALIDDATA; ret = decode_run_i(avctx, ptype, run, &x, &y, clr, dst, linesize, &lx, &ly, backstep, off, &cx, &cx1); if (ret < 0) return ret; } return 0; } static int decompress_p3(AVCodecContext *avctx, uint32_t *dst, int linesize, uint32_t *prev, int plinesize) { SCPRContext *s = avctx->priv_data; GetByteContext *gb = &s->gb; int ret, temp, min, max, x, y, cx = 0, cx1 = 0; int backstep = linesize - avctx->width; int mvx = 0, mvy = 0; if (bytestream2_get_byte(gb) == 0) return 1; init_rangecoder3(&s->rc, gb); ret = decode_value3(s, 255, &s->range_model3.cntsum, s->range_model3.freqs[0], s->range_model3.freqs[1], s->range_model3.cnts, s->range_model3.dectab, &min); ret |= decode_value3(s, 255, &s->range_model3.cntsum, s->range_model3.freqs[0], s->range_model3.freqs[1], s->range_model3.cnts, s->range_model3.dectab, &temp); if (ret < 0) return ret; min += temp << 8; ret |= decode_value3(s, 255, &s->range_model3.cntsum, s->range_model3.freqs[0], s->range_model3.freqs[1], s->range_model3.cnts, s->range_model3.dectab, &max); ret |= decode_value3(s, 255, &s->range_model3.cntsum, s->range_model3.freqs[0], s->range_model3.freqs[1], s->range_model3.cnts, s->range_model3.dectab, &temp); if (ret < 0) return ret; max += temp << 8; if (min > max || min >= s->nbcount) return AVERROR_INVALIDDATA; memset(s->blocks, 0, sizeof(*s->blocks) * s->nbcount); while (min <= max) { int fill, count; ret = decode_value3(s, 4, &s->fill_model3.cntsum, s->fill_model3.freqs[0], s->fill_model3.freqs[1], s->fill_model3.cnts, s->fill_model3.dectab, &fill); ret |= decode_value3(s, 255, &s->count_model3.cntsum, s->count_model3.freqs[0], s->count_model3.freqs[1], s->count_model3.cnts, s->count_model3.dectab, &count); if (ret < 0) return ret; if (count <= 0) return AVERROR_INVALIDDATA; while (min < s->nbcount && count-- > 0) { s->blocks[min++] = fill; } } ret = av_frame_copy(s->current_frame, s->last_frame); if (ret < 0) return ret; for (y = 0; y < s->nby; y++) { for (x = 0; x < s->nbx; x++) { int sy1 = 0, sy2 = 16, sx1 = 0, sx2 = 16; if (s->blocks[y * s->nbx + x] == 0) continue; if (((s->blocks[y * s->nbx + x] + 1) & 1) > 0) { ret = decode_value3(s, 15, &s->sxy_model3[0].cntsum, s->sxy_model3[0].freqs[0], s->sxy_model3[0].freqs[1], s->sxy_model3[0].cnts, s->sxy_model3[0].dectab, &sx1); ret |= decode_value3(s, 15, &s->sxy_model3[1].cntsum, s->sxy_model3[1].freqs[0], s->sxy_model3[1].freqs[1], s->sxy_model3[1].cnts, s->sxy_model3[1].dectab, &sy1); ret |= decode_value3(s, 15, &s->sxy_model3[2].cntsum, s->sxy_model3[2].freqs[0], s->sxy_model3[2].freqs[1], s->sxy_model3[2].cnts, s->sxy_model3[2].dectab, &sx2); ret |= decode_value3(s, 15, &s->sxy_model3[3].cntsum, s->sxy_model3[3].freqs[0], s->sxy_model3[3].freqs[1], s->sxy_model3[3].cnts, s->sxy_model3[3].dectab, &sy2); if (ret < 0) return ret; sx2++; sy2++; } if (((s->blocks[y * s->nbx + x] + 3) & 2) > 0) { int i, a, b, c, j, by = y * 16, bx = x * 16; uint32_t code; a = s->rc.code & 0xFFF; c = 1; if (a < 0x800) c = 0; b = 2048; if (!c) b = 0; code = a + ((s->rc.code >> 1) & 0xFFFFF800) - b; while (code < 0x800000 && bytestream2_get_bytes_left(gb) > 0) code = bytestream2_get_byteu(gb) | (code << 8); s->rc.code = code; sync_code3(gb, &s->rc); if (!c) { ret = decode_value3(s, 511, &s->mv_model3[0].cntsum, s->mv_model3[0].freqs[0], s->mv_model3[0].freqs[1], s->mv_model3[0].cnts, s->mv_model3[0].dectab, &mvx); ret |= decode_value3(s, 511, &s->mv_model3[1].cntsum, s->mv_model3[1].freqs[0], s->mv_model3[1].freqs[1], s->mv_model3[1].cnts, s->mv_model3[1].dectab, &mvy); if (ret < 0) return ret; mvx -= 256; mvy -= 256; } if (by + mvy + sy1 < 0 || bx + mvx + sx1 < 0 || by + mvy + sy1 >= avctx->height || bx + mvx + sx1 >= avctx->width) return AVERROR_INVALIDDATA; for (i = 0; i < sy2 - sy1 && (by + sy1 + i) < avctx->height && (by + mvy + sy1 + i) < avctx->height; i++) { for (j = 0; j < sx2 - sx1 && (bx + sx1 + j) < avctx->width && (bx + mvx + sx1 + j) < avctx->width; j++) { dst[(by + i + sy1) * linesize + bx + sx1 + j] = prev[(by + mvy + sy1 + i) * plinesize + bx + sx1 + mvx + j]; } } } else { int run, bx = x * 16 + sx1, by = y * 16 + sy1; uint32_t clr, ptype = 0, r, g, b; if (bx >= avctx->width) return AVERROR_INVALIDDATA; for (; by < y * 16 + sy2 && by < avctx->height;) { ret = decode_value3(s, 5, &s->op_model3[ptype].cntsum, s->op_model3[ptype].freqs[0], s->op_model3[ptype].freqs[1], s->op_model3[ptype].cnts, s->op_model3[ptype].dectab, &ptype); if (ret < 0) return ret; if (ptype == 0) { ret = decode_units3(s, &r, &g, &b, &cx, &cx1); if (ret < 0) return ret; clr = (b << 16) + (g << 8) + r; } if (ptype > 5) return AVERROR_INVALIDDATA; ret = decode_value3(s, 255, &s->run_model3[ptype].cntsum, s->run_model3[ptype].freqs[0], s->run_model3[ptype].freqs[1], s->run_model3[ptype].cnts, s->run_model3[ptype].dectab, &run); if (ret < 0) return ret; if (run <= 0) return AVERROR_INVALIDDATA; ret = decode_run_p(avctx, ptype, run, x, y, clr, dst, prev, linesize, plinesize, &bx, &by, backstep, sx1, sx2, &cx, &cx1); if (ret < 0) return ret; } } } } return 0; }