#include "mupdf/fitz.h" #include "mupdf/pdf.h" #include #include #include #include #define DIV_BY_ZERO(a, b, min, max) (((a) < 0) ^ ((b) < 0) ? (min) : (max)) enum { MAX_N = FZ_MAX_COLORS, MAX_M = FZ_MAX_COLORS }; typedef struct psobj_s psobj; enum { SAMPLE = 0, EXPONENTIAL = 2, STITCHING = 3, POSTSCRIPT = 4 }; struct pdf_function_s { fz_storable storable; size_t size; int m; /* number of input values */ int n; /* number of output values */ int type; /* 0=sample 2=exponential 3=stitching 4=postscript */ float domain[MAX_M][2]; /* even index : min value, odd index : max value */ float range[MAX_N][2]; /* even index : min value, odd index : max value */ int has_range; union { struct { unsigned short bps; int size[MAX_M]; float encode[MAX_M][2]; float decode[MAX_N][2]; float *samples; } sa; struct { float n; float c0[MAX_N]; float c1[MAX_N]; } e; struct { int k; pdf_function **funcs; /* k */ float *bounds; /* k - 1 */ float *encode; /* k * 2 */ } st; struct { psobj *code; int cap; } p; } u; }; pdf_function * pdf_keep_function(fz_context *ctx, pdf_function *func) { return fz_keep_storable(ctx, &func->storable); } void pdf_drop_function(fz_context *ctx, pdf_function *func) { fz_drop_storable(ctx, &func->storable); } size_t pdf_function_size(fz_context *ctx, pdf_function *func) { return (func ? func->size : 0); } static inline float lerp(float x, float xmin, float xmax, float ymin, float ymax) { if (xmin == xmax) return ymin; if (ymin == ymax) return ymin; return ymin + (x - xmin) * (ymax - ymin) / (xmax - xmin); } /* * PostScript calculator */ enum { PS_BOOL, PS_INT, PS_REAL, PS_OPERATOR, PS_BLOCK }; enum { PS_OP_ABS, PS_OP_ADD, PS_OP_AND, PS_OP_ATAN, PS_OP_BITSHIFT, PS_OP_CEILING, PS_OP_COPY, PS_OP_COS, PS_OP_CVI, PS_OP_CVR, PS_OP_DIV, PS_OP_DUP, PS_OP_EQ, PS_OP_EXCH, PS_OP_EXP, PS_OP_FALSE, PS_OP_FLOOR, PS_OP_GE, PS_OP_GT, PS_OP_IDIV, PS_OP_IF, PS_OP_IFELSE, PS_OP_INDEX, PS_OP_LE, PS_OP_LN, PS_OP_LOG, PS_OP_LT, PS_OP_MOD, PS_OP_MUL, PS_OP_NE, PS_OP_NEG, PS_OP_NOT, PS_OP_OR, PS_OP_POP, PS_OP_RETURN, PS_OP_ROLL, PS_OP_ROUND, PS_OP_SIN, PS_OP_SQRT, PS_OP_SUB, PS_OP_TRUE, PS_OP_TRUNCATE, PS_OP_XOR }; static char *ps_op_names[] = { "abs", "add", "and", "atan", "bitshift", "ceiling", "copy", "cos", "cvi", "cvr", "div", "dup", "eq", "exch", "exp", "false", "floor", "ge", "gt", "idiv", "if", "ifelse", "index", "le", "ln", "log", "lt", "mod", "mul", "ne", "neg", "not", "or", "pop", "return", "roll", "round", "sin", "sqrt", "sub", "true", "truncate", "xor" }; struct psobj_s { int type; union { int b; /* boolean (stack only) */ int i; /* integer (stack and code) */ float f; /* real (stack and code) */ int op; /* operator (code only) */ int block; /* if/ifelse block pointer (code only) */ } u; }; typedef struct ps_stack_s ps_stack; struct ps_stack_s { psobj stack[100]; int sp; }; void pdf_print_ps_stack(fz_context *ctx, fz_output *out, ps_stack *st) { int i; fz_write_printf(ctx, out, "stack:"); for (i = 0; i < st->sp; i++) { switch (st->stack[i].type) { case PS_BOOL: if (st->stack[i].u.b) fz_write_printf(ctx, out, " true"); else fz_write_printf(ctx, out, " false"); break; case PS_INT: fz_write_printf(ctx, out, " %d", st->stack[i].u.i); break; case PS_REAL: fz_write_printf(ctx, out, " %g", st->stack[i].u.f); break; } } fz_write_printf(ctx, out, "\n"); } static void ps_init_stack(ps_stack *st) { memset(st->stack, 0, sizeof(st->stack)); st->sp = 0; } static inline int ps_overflow(ps_stack *st, int n) { return n < 0 || st->sp + n >= nelem(st->stack); } static inline int ps_underflow(ps_stack *st, int n) { return n < 0 || n > st->sp; } static inline int ps_is_type(ps_stack *st, int t) { return !ps_underflow(st, 1) && st->stack[st->sp - 1].type == t; } static inline int ps_is_type2(ps_stack *st, int t) { return !ps_underflow(st, 2) && st->stack[st->sp - 1].type == t && st->stack[st->sp - 2].type == t; } static void ps_push_bool(ps_stack *st, int b) { if (!ps_overflow(st, 1)) { st->stack[st->sp].type = PS_BOOL; st->stack[st->sp].u.b = b; st->sp++; } } static void ps_push_int(ps_stack *st, int n) { if (!ps_overflow(st, 1)) { st->stack[st->sp].type = PS_INT; st->stack[st->sp].u.i = n; st->sp++; } } static void ps_push_real(ps_stack *st, float n) { if (!ps_overflow(st, 1)) { st->stack[st->sp].type = PS_REAL; if (isnan(n)) { /* Push 1.0, as it's a small known value that won't * cause a divide by 0. Same reason as in fz_atof. */ n = 1.0f; } st->stack[st->sp].u.f = fz_clamp(n, -FLT_MAX, FLT_MAX); st->sp++; } } static int ps_pop_bool(ps_stack *st) { if (!ps_underflow(st, 1)) { if (ps_is_type(st, PS_BOOL)) return st->stack[--st->sp].u.b; } return 0; } static int ps_pop_int(ps_stack *st) { if (!ps_underflow(st, 1)) { if (ps_is_type(st, PS_INT)) return st->stack[--st->sp].u.i; if (ps_is_type(st, PS_REAL)) return st->stack[--st->sp].u.f; } return 0; } static float ps_pop_real(ps_stack *st) { if (!ps_underflow(st, 1)) { if (ps_is_type(st, PS_INT)) return st->stack[--st->sp].u.i; if (ps_is_type(st, PS_REAL)) return st->stack[--st->sp].u.f; } return 0; } static void ps_copy(ps_stack *st, int n) { if (!ps_underflow(st, n) && !ps_overflow(st, n)) { memcpy(st->stack + st->sp, st->stack + st->sp - n, n * sizeof(psobj)); st->sp += n; } } static void ps_roll(ps_stack *st, int n, int j) { psobj tmp; int i; if (ps_underflow(st, n) || j == 0 || n == 0) return; if (j >= 0) { j %= n; } else { j = -j % n; if (j != 0) j = n - j; } for (i = 0; i < j; i++) { tmp = st->stack[st->sp - 1]; memmove(st->stack + st->sp - n + 1, st->stack + st->sp - n, n * sizeof(psobj)); st->stack[st->sp - n] = tmp; } } static void ps_index(ps_stack *st, int n) { if (!ps_overflow(st, 1) && !ps_underflow(st, n + 1)) { st->stack[st->sp] = st->stack[st->sp - n - 1]; st->sp++; } } static void ps_run(fz_context *ctx, psobj *code, ps_stack *st, int pc) { int i1, i2; float r1, r2; int b1, b2; while (1) { switch (code[pc].type) { case PS_INT: ps_push_int(st, code[pc++].u.i); break; case PS_REAL: ps_push_real(st, code[pc++].u.f); break; case PS_OPERATOR: switch (code[pc++].u.op) { case PS_OP_ABS: if (ps_is_type(st, PS_INT)) ps_push_int(st, fz_absi(ps_pop_int(st))); else ps_push_real(st, fz_abs(ps_pop_real(st))); break; case PS_OP_ADD: if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_int(st, i1 + i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_real(st, r1 + r2); } break; case PS_OP_AND: if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_int(st, i1 & i2); } else { b2 = ps_pop_bool(st); b1 = ps_pop_bool(st); ps_push_bool(st, b1 && b2); } break; case PS_OP_ATAN: r2 = ps_pop_real(st); r1 = ps_pop_real(st); r1 = atan2f(r1, r2) * FZ_RADIAN; if (r1 < 0) r1 += 360; ps_push_real(st, r1); break; case PS_OP_BITSHIFT: i2 = ps_pop_int(st); i1 = ps_pop_int(st); if (i2 > 0 && i2 < 8 * sizeof (i2)) ps_push_int(st, i1 << i2); else if (i2 < 0 && i2 > -8 * (int)sizeof (i2)) ps_push_int(st, (int)((unsigned int)i1 >> -i2)); else ps_push_int(st, i1); break; case PS_OP_CEILING: r1 = ps_pop_real(st); ps_push_real(st, ceilf(r1)); break; case PS_OP_COPY: ps_copy(st, ps_pop_int(st)); break; case PS_OP_COS: r1 = ps_pop_real(st); ps_push_real(st, cosf(r1/FZ_RADIAN)); break; case PS_OP_CVI: ps_push_int(st, ps_pop_int(st)); break; case PS_OP_CVR: ps_push_real(st, ps_pop_real(st)); break; case PS_OP_DIV: r2 = ps_pop_real(st); r1 = ps_pop_real(st); if (fabsf(r2) >= FLT_EPSILON) ps_push_real(st, r1 / r2); else ps_push_real(st, DIV_BY_ZERO(r1, r2, -FLT_MAX, FLT_MAX)); break; case PS_OP_DUP: ps_copy(st, 1); break; case PS_OP_EQ: if (ps_is_type2(st, PS_BOOL)) { b2 = ps_pop_bool(st); b1 = ps_pop_bool(st); ps_push_bool(st, b1 == b2); } else if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_bool(st, i1 == i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_bool(st, r1 == r2); } break; case PS_OP_EXCH: ps_roll(st, 2, 1); break; case PS_OP_EXP: r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_real(st, powf(r1, r2)); break; case PS_OP_FALSE: ps_push_bool(st, 0); break; case PS_OP_FLOOR: r1 = ps_pop_real(st); ps_push_real(st, floorf(r1)); break; case PS_OP_GE: if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_bool(st, i1 >= i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_bool(st, r1 >= r2); } break; case PS_OP_GT: if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_bool(st, i1 > i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_bool(st, r1 > r2); } break; case PS_OP_IDIV: i2 = ps_pop_int(st); i1 = ps_pop_int(st); if (i2 != 0) ps_push_int(st, i1 / i2); else ps_push_int(st, DIV_BY_ZERO(i1, i2, INT_MIN, INT_MAX)); break; case PS_OP_INDEX: ps_index(st, ps_pop_int(st)); break; case PS_OP_LE: if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_bool(st, i1 <= i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_bool(st, r1 <= r2); } break; case PS_OP_LN: r1 = ps_pop_real(st); /* Bug 692941 - logf as separate statement */ r2 = logf(r1); ps_push_real(st, r2); break; case PS_OP_LOG: r1 = ps_pop_real(st); ps_push_real(st, log10f(r1)); break; case PS_OP_LT: if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_bool(st, i1 < i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_bool(st, r1 < r2); } break; case PS_OP_MOD: i2 = ps_pop_int(st); i1 = ps_pop_int(st); if (i2 != 0) ps_push_int(st, i1 % i2); else ps_push_int(st, DIV_BY_ZERO(i1, i2, INT_MIN, INT_MAX)); break; case PS_OP_MUL: if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_int(st, i1 * i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_real(st, r1 * r2); } break; case PS_OP_NE: if (ps_is_type2(st, PS_BOOL)) { b2 = ps_pop_bool(st); b1 = ps_pop_bool(st); ps_push_bool(st, b1 != b2); } else if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_bool(st, i1 != i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_bool(st, r1 != r2); } break; case PS_OP_NEG: if (ps_is_type(st, PS_INT)) ps_push_int(st, -ps_pop_int(st)); else ps_push_real(st, -ps_pop_real(st)); break; case PS_OP_NOT: if (ps_is_type(st, PS_BOOL)) ps_push_bool(st, !ps_pop_bool(st)); else ps_push_int(st, ~ps_pop_int(st)); break; case PS_OP_OR: if (ps_is_type2(st, PS_BOOL)) { b2 = ps_pop_bool(st); b1 = ps_pop_bool(st); ps_push_bool(st, b1 || b2); } else { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_int(st, i1 | i2); } break; case PS_OP_POP: if (!ps_underflow(st, 1)) st->sp--; break; case PS_OP_ROLL: i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_roll(st, i1, i2); break; case PS_OP_ROUND: if (!ps_is_type(st, PS_INT)) { r1 = ps_pop_real(st); ps_push_real(st, (r1 >= 0) ? floorf(r1 + 0.5f) : ceilf(r1 - 0.5f)); } break; case PS_OP_SIN: r1 = ps_pop_real(st); ps_push_real(st, sinf(r1/FZ_RADIAN)); break; case PS_OP_SQRT: r1 = ps_pop_real(st); ps_push_real(st, sqrtf(r1)); break; case PS_OP_SUB: if (ps_is_type2(st, PS_INT)) { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_int(st, i1 - i2); } else { r2 = ps_pop_real(st); r1 = ps_pop_real(st); ps_push_real(st, r1 - r2); } break; case PS_OP_TRUE: ps_push_bool(st, 1); break; case PS_OP_TRUNCATE: if (!ps_is_type(st, PS_INT)) { r1 = ps_pop_real(st); ps_push_real(st, (r1 >= 0) ? floorf(r1) : ceilf(r1)); } break; case PS_OP_XOR: if (ps_is_type2(st, PS_BOOL)) { b2 = ps_pop_bool(st); b1 = ps_pop_bool(st); ps_push_bool(st, b1 ^ b2); } else { i2 = ps_pop_int(st); i1 = ps_pop_int(st); ps_push_int(st, i1 ^ i2); } break; case PS_OP_IF: b1 = ps_pop_bool(st); if (b1) ps_run(ctx, code, st, code[pc + 1].u.block); pc = code[pc + 2].u.block; break; case PS_OP_IFELSE: b1 = ps_pop_bool(st); if (b1) ps_run(ctx, code, st, code[pc + 1].u.block); else ps_run(ctx, code, st, code[pc + 0].u.block); pc = code[pc + 2].u.block; break; case PS_OP_RETURN: return; default: fz_warn(ctx, "foreign operator in calculator function"); return; } break; default: fz_warn(ctx, "foreign object in calculator function"); return; } } } static void resize_code(fz_context *ctx, pdf_function *func, int newsize) { if (newsize >= func->u.p.cap) { int new_cap = func->u.p.cap + 64; func->u.p.code = fz_resize_array(ctx, func->u.p.code, new_cap, sizeof(psobj)); func->u.p.cap = new_cap; } } static void parse_code(fz_context *ctx, pdf_function *func, fz_stream *stream, int *codeptr, pdf_lexbuf *buf) { pdf_token tok; int opptr, elseptr, ifptr; int a, b, mid, cmp; while (1) { tok = pdf_lex(ctx, stream, buf); switch (tok) { case PDF_TOK_EOF: fz_throw(ctx, FZ_ERROR_SYNTAX, "truncated calculator function"); case PDF_TOK_INT: resize_code(ctx, func, *codeptr); func->u.p.code[*codeptr].type = PS_INT; func->u.p.code[*codeptr].u.i = buf->i; ++*codeptr; break; case PDF_TOK_TRUE: resize_code(ctx, func, *codeptr); func->u.p.code[*codeptr].type = PS_BOOL; func->u.p.code[*codeptr].u.b = 1; ++*codeptr; break; case PDF_TOK_FALSE: resize_code(ctx, func, *codeptr); func->u.p.code[*codeptr].type = PS_BOOL; func->u.p.code[*codeptr].u.b = 0; ++*codeptr; break; case PDF_TOK_REAL: resize_code(ctx, func, *codeptr); func->u.p.code[*codeptr].type = PS_REAL; func->u.p.code[*codeptr].u.f = buf->f; ++*codeptr; break; case PDF_TOK_OPEN_BRACE: opptr = *codeptr; *codeptr += 4; resize_code(ctx, func, *codeptr); ifptr = *codeptr; parse_code(ctx, func, stream, codeptr, buf); tok = pdf_lex(ctx, stream, buf); if (tok == PDF_TOK_OPEN_BRACE) { elseptr = *codeptr; parse_code(ctx, func, stream, codeptr, buf); tok = pdf_lex(ctx, stream, buf); } else { elseptr = -1; } if (tok != PDF_TOK_KEYWORD) fz_throw(ctx, FZ_ERROR_SYNTAX, "missing keyword in 'if-else' context"); if (!strcmp(buf->scratch, "if")) { if (elseptr >= 0) fz_throw(ctx, FZ_ERROR_SYNTAX, "too many branches for 'if'"); func->u.p.code[opptr].type = PS_OPERATOR; func->u.p.code[opptr].u.op = PS_OP_IF; func->u.p.code[opptr+2].type = PS_BLOCK; func->u.p.code[opptr+2].u.block = ifptr; func->u.p.code[opptr+3].type = PS_BLOCK; func->u.p.code[opptr+3].u.block = *codeptr; } else if (!strcmp(buf->scratch, "ifelse")) { if (elseptr < 0) fz_throw(ctx, FZ_ERROR_SYNTAX, "not enough branches for 'ifelse'"); func->u.p.code[opptr].type = PS_OPERATOR; func->u.p.code[opptr].u.op = PS_OP_IFELSE; func->u.p.code[opptr+1].type = PS_BLOCK; func->u.p.code[opptr+1].u.block = elseptr; func->u.p.code[opptr+2].type = PS_BLOCK; func->u.p.code[opptr+2].u.block = ifptr; func->u.p.code[opptr+3].type = PS_BLOCK; func->u.p.code[opptr+3].u.block = *codeptr; } else { fz_throw(ctx, FZ_ERROR_SYNTAX, "unknown keyword in 'if-else' context: '%s'", buf->scratch); } break; case PDF_TOK_CLOSE_BRACE: resize_code(ctx, func, *codeptr); func->u.p.code[*codeptr].type = PS_OPERATOR; func->u.p.code[*codeptr].u.op = PS_OP_RETURN; ++*codeptr; return; case PDF_TOK_KEYWORD: cmp = -1; a = -1; b = nelem(ps_op_names); while (b - a > 1) { mid = (a + b) / 2; cmp = strcmp(buf->scratch, ps_op_names[mid]); if (cmp > 0) a = mid; else if (cmp < 0) b = mid; else a = b = mid; } if (cmp != 0) fz_throw(ctx, FZ_ERROR_SYNTAX, "unknown operator: '%s'", buf->scratch); if (a == PS_OP_IFELSE) fz_throw(ctx, FZ_ERROR_SYNTAX, "illegally positioned ifelse operator in function"); if (a == PS_OP_IF) fz_throw(ctx, FZ_ERROR_SYNTAX, "illegally positioned if operator in function"); resize_code(ctx, func, *codeptr); func->u.p.code[*codeptr].type = PS_OPERATOR; func->u.p.code[*codeptr].u.op = a; ++*codeptr; break; default: fz_throw(ctx, FZ_ERROR_SYNTAX, "calculator function syntax error"); } } } static void load_postscript_func(fz_context *ctx, pdf_function *func, pdf_obj *dict) { fz_stream *stream = NULL; int codeptr; pdf_lexbuf buf; pdf_token tok; int locked = 0; pdf_lexbuf_init(ctx, &buf, PDF_LEXBUF_SMALL); fz_var(stream); fz_var(locked); fz_try(ctx) { stream = pdf_open_stream(ctx, dict); tok = pdf_lex(ctx, stream, &buf); if (tok != PDF_TOK_OPEN_BRACE) { fz_throw(ctx, FZ_ERROR_SYNTAX, "stream is not a calculator function"); } func->u.p.code = NULL; func->u.p.cap = 0; codeptr = 0; parse_code(ctx, func, stream, &codeptr, &buf); } fz_always(ctx) { fz_drop_stream(ctx, stream); pdf_lexbuf_fin(ctx, &buf); } fz_catch(ctx) { fz_rethrow(ctx); } func->size += func->u.p.cap * sizeof(psobj); } static void eval_postscript_func(fz_context *ctx, pdf_function *func, const float *in, float *out) { ps_stack st; float x; int i; ps_init_stack(&st); for (i = 0; i < func->m; i++) { x = fz_clamp(in[i], func->domain[i][0], func->domain[i][1]); ps_push_real(&st, x); } ps_run(ctx, func->u.p.code, &st, 0); for (i = func->n - 1; i >= 0; i--) { x = ps_pop_real(&st); out[i] = fz_clamp(x, func->range[i][0], func->range[i][1]); } } /* * Sample function */ #define MAX_SAMPLE_FUNCTION_SIZE (100 << 20) static void load_sample_func(fz_context *ctx, pdf_function *func, pdf_obj *dict) { fz_stream *stream; pdf_obj *obj; int samplecount; int bps; int i; fz_var(stream); func->u.sa.samples = NULL; obj = pdf_dict_get(ctx, dict, PDF_NAME(Size)); if (pdf_array_len(ctx, obj) < func->m) fz_throw(ctx, FZ_ERROR_SYNTAX, "too few sample function dimension sizes"); if (pdf_array_len(ctx, obj) > func->m) fz_warn(ctx, "too many sample function dimension sizes"); for (i = 0; i < func->m; i++) { func->u.sa.size[i] = pdf_array_get_int(ctx, obj, i); if (func->u.sa.size[i] <= 0) { fz_warn(ctx, "non-positive sample function dimension size"); func->u.sa.size[i] = 1; } } obj = pdf_dict_get(ctx, dict, PDF_NAME(BitsPerSample)); func->u.sa.bps = bps = pdf_to_int(ctx, obj); for (i = 0; i < func->m; i++) { func->u.sa.encode[i][0] = 0; func->u.sa.encode[i][1] = func->u.sa.size[i] - 1; } obj = pdf_dict_get(ctx, dict, PDF_NAME(Encode)); if (pdf_is_array(ctx, obj)) { int ranges = fz_mini(func->m, pdf_array_len(ctx, obj) / 2); if (ranges != func->m) fz_warn(ctx, "wrong number of sample function input mappings"); for (i = 0; i < ranges; i++) { func->u.sa.encode[i][0] = pdf_array_get_real(ctx, obj, i * 2 + 0); func->u.sa.encode[i][1] = pdf_array_get_real(ctx, obj, i * 2 + 1); } } for (i = 0; i < func->n; i++) { func->u.sa.decode[i][0] = func->range[i][0]; func->u.sa.decode[i][1] = func->range[i][1]; } obj = pdf_dict_get(ctx, dict, PDF_NAME(Decode)); if (pdf_is_array(ctx, obj)) { int ranges = fz_mini(func->n, pdf_array_len(ctx, obj) / 2); if (ranges != func->n) fz_warn(ctx, "wrong number of sample function output mappings"); for (i = 0; i < ranges; i++) { func->u.sa.decode[i][0] = pdf_array_get_real(ctx, obj, i * 2 + 0); func->u.sa.decode[i][1] = pdf_array_get_real(ctx, obj, i * 2 + 1); } } for (i = 0, samplecount = func->n; i < func->m; i++) samplecount *= func->u.sa.size[i]; if (samplecount > MAX_SAMPLE_FUNCTION_SIZE) fz_throw(ctx, FZ_ERROR_SYNTAX, "sample function too large"); func->u.sa.samples = fz_malloc_array(ctx, samplecount, sizeof(float)); func->size += samplecount * sizeof(float); stream = pdf_open_stream(ctx, dict); fz_try(ctx) { /* read samples */ for (i = 0; i < samplecount; i++) { float s; if (fz_is_eof_bits(ctx, stream)) fz_throw(ctx, FZ_ERROR_SYNTAX, "truncated sample function stream"); switch (bps) { case 1: s = fz_read_bits(ctx, stream, 1); break; case 2: s = fz_read_bits(ctx, stream, 2) / 3.0f; break; case 4: s = fz_read_bits(ctx, stream, 4) / 15.0f; break; case 8: s = fz_read_byte(ctx, stream) / 255.0f; break; case 12: s = fz_read_bits(ctx, stream, 12) / 4095.0f; break; case 16: s = fz_read_uint16(ctx, stream) / 65535.0f; break; case 24: s = fz_read_uint24(ctx, stream) / 16777215.0f; break; case 32: s = fz_read_uint32(ctx, stream) / 4294967295.0f; break; default: fz_throw(ctx, FZ_ERROR_SYNTAX, "sample stream bit depth %d unsupported", bps); } func->u.sa.samples[i] = s; } } fz_always(ctx) { fz_drop_stream(ctx, stream); } fz_catch(ctx) { fz_rethrow(ctx); } } static float interpolate_sample(pdf_function *func, int *scale, int *e0, int *e1, float *efrac, int dim, int idx) { float a, b; int idx0, idx1; idx0 = e0[dim] * scale[dim] + idx; idx1 = e1[dim] * scale[dim] + idx; if (dim == 0) { a = func->u.sa.samples[idx0]; b = func->u.sa.samples[idx1]; } else { a = interpolate_sample(func, scale, e0, e1, efrac, dim - 1, idx0); b = interpolate_sample(func, scale, e0, e1, efrac, dim - 1, idx1); } return a + (b - a) * efrac[dim]; } static void eval_sample_func(fz_context *ctx, pdf_function *func, const float *in, float *out) { int e0[MAX_M], e1[MAX_M], scale[MAX_M]; float efrac[MAX_M]; float x; int i; /* encode input coordinates */ for (i = 0; i < func->m; i++) { x = fz_clamp(in[i], func->domain[i][0], func->domain[i][1]); x = lerp(x, func->domain[i][0], func->domain[i][1], func->u.sa.encode[i][0], func->u.sa.encode[i][1]); x = fz_clamp(x, 0, func->u.sa.size[i] - 1); e0[i] = floorf(x); e1[i] = ceilf(x); efrac[i] = x - floorf(x); } scale[0] = func->n; for (i = 1; i < func->m; i++) scale[i] = scale[i - 1] * func->u.sa.size[i-1]; for (i = 0; i < func->n; i++) { if (func->m == 1) { float a = func->u.sa.samples[e0[0] * func->n + i]; float b = func->u.sa.samples[e1[0] * func->n + i]; float ab = a + (b - a) * efrac[0]; out[i] = lerp(ab, 0, 1, func->u.sa.decode[i][0], func->u.sa.decode[i][1]); out[i] = fz_clamp(out[i], func->range[i][0], func->range[i][1]); } else if (func->m == 2) { int s0 = func->n; int s1 = s0 * func->u.sa.size[0]; float a = func->u.sa.samples[e0[0] * s0 + e0[1] * s1 + i]; float b = func->u.sa.samples[e1[0] * s0 + e0[1] * s1 + i]; float c = func->u.sa.samples[e0[0] * s0 + e1[1] * s1 + i]; float d = func->u.sa.samples[e1[0] * s0 + e1[1] * s1 + i]; float ab = a + (b - a) * efrac[0]; float cd = c + (d - c) * efrac[0]; float abcd = ab + (cd - ab) * efrac[1]; out[i] = lerp(abcd, 0, 1, func->u.sa.decode[i][0], func->u.sa.decode[i][1]); out[i] = fz_clamp(out[i], func->range[i][0], func->range[i][1]); } else { x = interpolate_sample(func, scale, e0, e1, efrac, func->m - 1, i); out[i] = lerp(x, 0, 1, func->u.sa.decode[i][0], func->u.sa.decode[i][1]); out[i] = fz_clamp(out[i], func->range[i][0], func->range[i][1]); } } } /* * Exponential function */ static void load_exponential_func(fz_context *ctx, pdf_function *func, pdf_obj *dict) { pdf_obj *obj; int i; if (func->m > 1) fz_warn(ctx, "exponential functions have at most one input"); func->m = 1; obj = pdf_dict_get(ctx, dict, PDF_NAME(N)); func->u.e.n = pdf_to_real(ctx, obj); /* See exponential functions (PDF 1.7 section 3.9.2) */ if (func->u.e.n != (int) func->u.e.n) { /* If N is non-integer, input values may never be negative */ for (i = 0; i < func->m; i++) if (func->domain[i][0] < 0 || func->domain[i][1] < 0) fz_warn(ctx, "exponential function input domain includes illegal negative input values"); } else if (func->u.e.n < 0) { /* if N is negative, input values may never be zero */ for (i = 0; i < func->m; i++) if (func->domain[i][0] == 0 || func->domain[i][1] == 0 || (func->domain[i][0] < 0 && func->domain[i][1] > 0)) fz_warn(ctx, "exponential function input domain includes illegal input value zero"); } for (i = 0; i < func->n; i++) { func->u.e.c0[i] = 0; func->u.e.c1[i] = 1; } obj = pdf_dict_get(ctx, dict, PDF_NAME(C0)); if (pdf_is_array(ctx, obj)) { int ranges = fz_mini(func->n, pdf_array_len(ctx, obj)); if (ranges != func->n) fz_warn(ctx, "wrong number of C0 constants for exponential function"); for (i = 0; i < ranges; i++) func->u.e.c0[i] = pdf_array_get_real(ctx, obj, i); } obj = pdf_dict_get(ctx, dict, PDF_NAME(C1)); if (pdf_is_array(ctx, obj)) { int ranges = fz_mini(func->n, pdf_array_len(ctx, obj)); if (ranges != func->n) fz_warn(ctx, "wrong number of C1 constants for exponential function"); for (i = 0; i < ranges; i++) func->u.e.c1[i] = pdf_array_get_real(ctx, obj, i); } } static void eval_exponential_func(fz_context *ctx, pdf_function *func, float in, float *out) { float x = in; float tmp; int i; x = fz_clamp(x, func->domain[0][0], func->domain[0][1]); /* Default output is zero, which is suitable for violated constraints */ if ((func->u.e.n != (int)func->u.e.n && x < 0) || (func->u.e.n < 0 && x == 0)) return; tmp = powf(x, func->u.e.n); for (i = 0; i < func->n; i++) { out[i] = func->u.e.c0[i] + tmp * (func->u.e.c1[i] - func->u.e.c0[i]); if (func->has_range) out[i] = fz_clamp(out[i], func->range[i][0], func->range[i][1]); } } /* * Stitching function */ static void load_stitching_func(fz_context *ctx, pdf_function *func, pdf_obj *dict) { pdf_function **funcs; pdf_obj *obj; pdf_obj *sub; pdf_obj *num; int k; int i; func->u.st.k = 0; if (func->m > 1) fz_warn(ctx, "stitching functions have at most one input"); func->m = 1; obj = pdf_dict_get(ctx, dict, PDF_NAME(Functions)); if (!pdf_is_array(ctx, obj)) fz_throw(ctx, FZ_ERROR_SYNTAX, "stitching function has no input functions"); fz_try(ctx) { if (pdf_mark_obj(ctx, obj)) fz_throw(ctx, FZ_ERROR_SYNTAX, "recursive function"); k = pdf_array_len(ctx, obj); func->u.st.funcs = fz_malloc_array(ctx, k, sizeof(pdf_function*)); func->u.st.bounds = fz_malloc_array(ctx, k - 1, sizeof(float)); func->u.st.encode = fz_malloc_array(ctx, k * 2, sizeof(float)); funcs = func->u.st.funcs; for (i = 0; i < k; i++) { sub = pdf_array_get(ctx, obj, i); funcs[i] = pdf_load_function(ctx, sub, 1, func->n); func->size += pdf_function_size(ctx, funcs[i]); func->u.st.k ++; if (funcs[i]->m != func->m) fz_warn(ctx, "wrong number of inputs for sub function %d", i); if (funcs[i]->n != func->n) fz_warn(ctx, "wrong number of outputs for sub function %d", i); } } fz_always(ctx) { pdf_unmark_obj(ctx, obj); } fz_catch(ctx) { fz_rethrow(ctx); } obj = pdf_dict_get(ctx, dict, PDF_NAME(Bounds)); if (!pdf_is_array(ctx, obj)) fz_throw(ctx, FZ_ERROR_SYNTAX, "stitching function has no bounds"); { if (pdf_array_len(ctx, obj) < k - 1) fz_throw(ctx, FZ_ERROR_SYNTAX, "too few subfunction boundaries"); if (pdf_array_len(ctx, obj) > k) fz_warn(ctx, "too many subfunction boundaries"); for (i = 0; i < k - 1; i++) { num = pdf_array_get(ctx, obj, i); func->u.st.bounds[i] = pdf_to_real(ctx, num); if (i && func->u.st.bounds[i - 1] > func->u.st.bounds[i]) fz_throw(ctx, FZ_ERROR_SYNTAX, "subfunction %d boundary out of range", i); } if (k > 1 && (func->domain[0][0] > func->u.st.bounds[0] || func->domain[0][1] < func->u.st.bounds[k - 2])) fz_warn(ctx, "subfunction boundaries outside of input mapping"); } for (i = 0; i < k; i++) { func->u.st.encode[i * 2 + 0] = 0; func->u.st.encode[i * 2 + 1] = 0; } obj = pdf_dict_get(ctx, dict, PDF_NAME(Encode)); if (pdf_is_array(ctx, obj)) { int ranges = fz_mini(k, pdf_array_len(ctx, obj) / 2); if (ranges != k) fz_warn(ctx, "wrong number of stitching function input mappings"); for (i = 0; i < ranges; i++) { func->u.st.encode[i * 2 + 0] = pdf_array_get_real(ctx, obj, i * 2 + 0); func->u.st.encode[i * 2 + 1] = pdf_array_get_real(ctx, obj, i * 2 + 1); } } } static void eval_stitching_func(fz_context *ctx, pdf_function *func, float in, float *out) { float low, high; int k = func->u.st.k; float *bounds = func->u.st.bounds; int i; in = fz_clamp(in, func->domain[0][0], func->domain[0][1]); for (i = 0; i < k - 1; i++) { if (in < bounds[i]) break; } if (i == 0 && k == 1) { low = func->domain[0][0]; high = func->domain[0][1]; } else if (i == 0) { low = func->domain[0][0]; high = bounds[0]; } else if (i == k - 1) { low = bounds[k - 2]; high = func->domain[0][1]; } else { low = bounds[i - 1]; high = bounds[i]; } in = lerp(in, low, high, func->u.st.encode[i * 2 + 0], func->u.st.encode[i * 2 + 1]); pdf_eval_function(ctx, func->u.st.funcs[i], &in, 1, out, func->u.st.funcs[i]->n); } /* * Common */ static void pdf_drop_function_imp(fz_context *ctx, fz_storable *func_) { pdf_function *func = (pdf_function *)func_; int i; switch (func->type) { case SAMPLE: fz_free(ctx, func->u.sa.samples); break; case EXPONENTIAL: break; case STITCHING: for (i = 0; i < func->u.st.k; i++) pdf_drop_function(ctx, func->u.st.funcs[i]); fz_free(ctx, func->u.st.funcs); fz_free(ctx, func->u.st.bounds); fz_free(ctx, func->u.st.encode); break; case POSTSCRIPT: fz_free(ctx, func->u.p.code); break; } fz_free(ctx, func); } static void pdf_eval_function_imp(fz_context *ctx, pdf_function *func, const float *in, float *out) { switch (func->type) { case SAMPLE: eval_sample_func(ctx, func, in, out); break; case EXPONENTIAL: eval_exponential_func(ctx, func, *in, out); break; case STITCHING: eval_stitching_func(ctx, func, *in, out); break; case POSTSCRIPT: eval_postscript_func(ctx, func, in, out); break; } } void pdf_eval_function(fz_context *ctx, pdf_function *func, const float *in, int inlen, float *out, int outlen) { float fakein[MAX_M]; float fakeout[MAX_N]; int i; if (inlen < func->m) { for (i = 0; i < func->m; ++i) fakein[i] = in[i]; for (; i < inlen; ++i) fakein[i] = 0; in = fakein; } if (outlen < func->n) { pdf_eval_function_imp(ctx, func, in, fakeout); for (i = 0; i < outlen; ++i) out[i] = fakeout[i]; } else { pdf_eval_function_imp(ctx, func, in, out); for (i = func->n; i < outlen; ++i) out[i] = 0; } } pdf_function * pdf_load_function(fz_context *ctx, pdf_obj *dict, int in, int out) { pdf_function *func; pdf_obj *obj; int i; if (pdf_obj_marked(ctx, dict)) fz_throw(ctx, FZ_ERROR_SYNTAX, "Recursion in function definition"); if ((func = pdf_find_item(ctx, pdf_drop_function_imp, dict)) != NULL) return func; func = fz_malloc_struct(ctx, pdf_function); FZ_INIT_STORABLE(func, 1, pdf_drop_function_imp); func->size = sizeof(*func); obj = pdf_dict_get(ctx, dict, PDF_NAME(FunctionType)); func->type = pdf_to_int(ctx, obj); /* required for all */ obj = pdf_dict_get(ctx, dict, PDF_NAME(Domain)); func->m = fz_clampi(pdf_array_len(ctx, obj) / 2, 1, MAX_M); for (i = 0; i < func->m; i++) { func->domain[i][0] = pdf_array_get_real(ctx, obj, i * 2 + 0); func->domain[i][1] = pdf_array_get_real(ctx, obj, i * 2 + 1); } /* required for type0 and type4, optional otherwise */ obj = pdf_dict_get(ctx, dict, PDF_NAME(Range)); if (pdf_is_array(ctx, obj)) { func->has_range = 1; func->n = fz_clampi(pdf_array_len(ctx, obj) / 2, 1, MAX_N); for (i = 0; i < func->n; i++) { func->range[i][0] = pdf_array_get_real(ctx, obj, i * 2 + 0); func->range[i][1] = pdf_array_get_real(ctx, obj, i * 2 + 1); } } else { func->has_range = 0; func->n = out; } if (func->m != in) fz_warn(ctx, "wrong number of function inputs"); if (func->n != out) fz_warn(ctx, "wrong number of function outputs"); fz_try(ctx) { switch (func->type) { case SAMPLE: load_sample_func(ctx, func, dict); break; case EXPONENTIAL: load_exponential_func(ctx, func, dict); break; case STITCHING: load_stitching_func(ctx, func, dict); break; case POSTSCRIPT: load_postscript_func(ctx, func, dict); break; default: fz_throw(ctx, FZ_ERROR_SYNTAX, "unknown function type (%d 0 R)", pdf_to_num(ctx, dict)); } pdf_store_item(ctx, dict, func, func->size); } fz_catch(ctx) { pdf_drop_function(ctx, func); fz_rethrow(ctx); } return func; }