#include "mupdf/fitz.h" #include "svg-imp.h" #include #include int svg_is_whitespace_or_comma(int c) { return (c == 0x20) || (c == 0x9) || (c == 0xD) || (c == 0xA) || (c == ','); } int svg_is_whitespace(int c) { return (c == 0x20) || (c == 0x9) || (c == 0xD) || (c == 0xA); } int svg_is_alpha(int c) { return (c >= 'A' && c <= 'Z') || (c >= 'a' && c <= 'z'); } int svg_is_digit(int c) { return (c >= '0' && c <= '9') || (c == 'e') || (c == 'E') || (c == '+') || (c == '-') || (c == '.'); } const char * svg_lex_number(float *fp, const char *ss) { const char *s = ss; if (*s == '-') ++s; while (*s >= '0' && *s <= '9') ++s; if (*s == '.') { ++s; while (*s >= '0' && *s <= '9') ++s; } if (*s == 'e' || *s == 'E') { ++s; if (*s == '+' || *s == '-') ++s; while (*s >= '0' && *s <= '9') ++s; } *fp = fz_atof(ss); return s; } float svg_parse_number(const char *str, float min, float max, float inherit) { float x; if (!strcmp(str, "inherit")) return inherit; x = fz_atof(str); if (x < min) return min; if (x > max) return max; return x; } /* Return length/coordinate in points */ float svg_parse_length(const char *str, float percent, float font_size) { char *end; float val; val = (float)fz_strtod(str, &end); if (end == str) return 0; /* failed */ if (!strcmp(end, "px")) return val; if (!strcmp(end, "pt")) return val * 1.0; if (!strcmp(end, "pc")) return val * 12.0; if (!strcmp(end, "mm")) return val * 2.83464567; if (!strcmp(end, "cm")) return val * 28.3464567; if (!strcmp(end, "in")) return val * 72.0; if (!strcmp(end, "em")) return val * font_size; if (!strcmp(end, "ex")) return val * font_size * 0.5; if (!strcmp(end, "%")) return val * percent * 0.01; if (end[0] == 0) return val; return 0; } /* Return angle in degrees */ float svg_parse_angle(const char *str) { char *end; float val; val = (float)fz_strtod(str, &end); if (end == str) return 0; /* failed */ if (!strcmp(end, "deg")) return val; if (!strcmp(end, "grad")) return val * 0.9; if (!strcmp(end, "rad")) return val * 57.2957795; return val; } /* Coordinate transformations */ void svg_parse_transform(fz_context *ctx, svg_document *doc, char *str, fz_matrix *transform) { char keyword[20]; int keywordlen; char number[20]; int numberlen; float args[6]; int nargs; int first = 1; nargs = 0; keywordlen = 0; while (*str) { while (svg_is_whitespace(*str)) str ++; if (*str == 0) break; if (!first) { if (*str == ',') str ++; while (svg_is_whitespace(*str)) str ++; } first = 0; /* * Parse keyword and opening parenthesis. */ keywordlen = 0; while (svg_is_alpha(*str) && keywordlen < sizeof(keyword) - 1) keyword[keywordlen++] = *str++; keyword[keywordlen] = 0; if (keywordlen == 0) fz_throw(ctx, FZ_ERROR_SYNTAX, "expected keyword in transform attribute"); while (svg_is_whitespace(*str)) str ++; if (*str != '(') fz_throw(ctx, FZ_ERROR_SYNTAX, "expected opening parenthesis in transform attribute"); str ++; /* * Parse list of numbers until closing parenthesis */ nargs = 0; while (*str && *str != ')' && nargs < 6) { if (nargs > 0 && *str == ',') str ++; while (svg_is_whitespace(*str)) str ++; numberlen = 0; while (svg_is_digit(*str) && numberlen < sizeof(number) - 1) number[numberlen++] = *str++; number[numberlen] = 0; if (numberlen == 0) fz_throw(ctx, FZ_ERROR_SYNTAX, "expected number in transform attribute"); args[nargs++] = fz_atof(number); while (svg_is_whitespace(*str)) str ++; } if (*str != ')') fz_throw(ctx, FZ_ERROR_SYNTAX, "expected closing parenthesis in transform attribute"); str ++; /* * Execute the transform. */ if (!strcmp(keyword, "matrix")) { fz_matrix m; if (nargs != 6) fz_throw(ctx, FZ_ERROR_SYNTAX, "wrong number of arguments to matrix(): %d", nargs); m.a = args[0]; m.b = args[1]; m.c = args[2]; m.d = args[3]; m.e = args[4]; m.f = args[5]; fz_concat(transform, transform, &m); } else if (!strcmp(keyword, "translate")) { if (nargs != 2) fz_throw(ctx, FZ_ERROR_SYNTAX, "wrong number of arguments to translate(): %d", nargs); fz_pre_translate(transform, args[0], args[1]); } else if (!strcmp(keyword, "scale")) { if (nargs == 1) fz_pre_scale(transform, args[0], args[0]); else if (nargs == 2) fz_pre_scale(transform, args[0], args[1]); else fz_throw(ctx, FZ_ERROR_SYNTAX, "wrong number of arguments to scale(): %d", nargs); } else if (!strcmp(keyword, "rotate")) { if (nargs != 1) fz_throw(ctx, FZ_ERROR_SYNTAX, "wrong number of arguments to rotate(): %d", nargs); fz_pre_rotate(transform, args[0]); } else if (!strcmp(keyword, "skewX")) { fz_matrix m; if (nargs != 1) fz_throw(ctx, FZ_ERROR_SYNTAX, "wrong number of arguments to skewX(): %d", nargs); m.a = 1; m.b = 0; m.c = tanf(args[0] * 0.0174532925); m.d = 1; m.e = 0; m.f = 0; fz_concat(transform, transform, &m); } else if (!strcmp(keyword, "skewY")) { fz_matrix m; if (nargs != 1) fz_throw(ctx, FZ_ERROR_SYNTAX, "wrong number of arguments to skewY(): %d", nargs); m.a = 1; m.b = tanf(args[0] * 0.0174532925); m.c = 0; m.d = 1; m.e = 0; m.f = 0; fz_concat(transform, transform, &m); } else { fz_throw(ctx, FZ_ERROR_SYNTAX, "unknown transform function: %s", keyword); } } }