/* ------------------------------------------------------------------------ unicodedata -- Provides access to the Unicode database. Data was extracted from the UnicodeData.txt file. The current version number is reported in the unidata_version constant. Written by Marc-Andre Lemburg (mal@lemburg.com). Modified for Python 2.0 by Fredrik Lundh (fredrik@pythonware.com) Modified by Martin v. Löwis (martin@v.loewis.de) Copyright (c) Corporation for National Research Initiatives. ------------------------------------------------------------------------ */ #include "Python.h" #include "ucnhash.h" #include "structmember.h" /*[clinic input] module unicodedata class unicodedata.UCD [clinic start generated code]*/ /*[clinic end generated code: checksum=da39a3ee5e6b4b0d3255bfef95601890afd80709]*/ /* character properties */ typedef struct { const unsigned char category; /* index into _PyUnicode_CategoryNames */ const unsigned char combining; /* combining class value 0 - 255 */ const unsigned char bidirectional; /* index into _PyUnicode_BidirectionalNames */ const unsigned char mirrored; /* true if mirrored in bidir mode */ const unsigned char east_asian_width; /* index into _PyUnicode_EastAsianWidth */ const unsigned char normalization_quick_check; /* see is_normalized() */ } _PyUnicode_DatabaseRecord; typedef struct change_record { /* sequence of fields should be the same as in merge_old_version */ const unsigned char bidir_changed; const unsigned char category_changed; const unsigned char decimal_changed; const unsigned char mirrored_changed; const double numeric_changed; } change_record; /* data file generated by Tools/unicode/makeunicodedata.py */ #include "unicodedata_db.h" static const _PyUnicode_DatabaseRecord* _getrecord_ex(Py_UCS4 code) { int index; if (code >= 0x110000) index = 0; else { index = index1[(code>>SHIFT)]; index = index2[(index<getrecord)(v)) static PyMemberDef DB_members[] = { {"unidata_version", T_STRING, offsetof(PreviousDBVersion, name), READONLY}, {NULL} }; /* forward declaration */ static PyTypeObject UCD_Type; #define UCD_Check(o) (Py_TYPE(o)==&UCD_Type) static PyObject* new_previous_version(const char*name, const change_record* (*getrecord)(Py_UCS4), Py_UCS4 (*normalization)(Py_UCS4)) { PreviousDBVersion *self; self = PyObject_New(PreviousDBVersion, &UCD_Type); if (self == NULL) return NULL; self->name = name; self->getrecord = getrecord; self->normalization = normalization; return (PyObject*)self; } static Py_UCS4 getuchar(PyUnicodeObject *obj) { if (PyUnicode_READY(obj)) return (Py_UCS4)-1; if (PyUnicode_GET_LENGTH(obj) == 1) { if (PyUnicode_READY(obj)) return (Py_UCS4)-1; return PyUnicode_READ_CHAR(obj, 0); } PyErr_SetString(PyExc_TypeError, "need a single Unicode character as parameter"); return (Py_UCS4)-1; } /* --- Module API --------------------------------------------------------- */ /*[clinic input] unicodedata.UCD.decimal unichr: object(type='PyUnicodeObject *', subclass_of='&PyUnicode_Type') default: object=NULL / Converts a Unicode character into its equivalent decimal value. Returns the decimal value assigned to the Unicode character unichr as integer. If no such value is defined, default is returned, or, if not given, ValueError is raised. [clinic start generated code]*/ PyDoc_STRVAR(unicodedata_UCD_decimal__doc__, "decimal(unichr, default=None)\n" "Converts a Unicode character into its equivalent decimal value.\n" "\n" "Returns the decimal value assigned to the Unicode character unichr\n" "as integer. If no such value is defined, default is returned, or, if\n" "not given, ValueError is raised."); #define UNICODEDATA_UCD_DECIMAL_METHODDEF \ {"decimal", (PyCFunction)unicodedata_UCD_decimal, METH_VARARGS, unicodedata_UCD_decimal__doc__}, static PyObject * unicodedata_UCD_decimal_impl(PyObject *self, PyUnicodeObject *unichr, PyObject *default_value); static PyObject * unicodedata_UCD_decimal(PyObject *self, PyObject *args) { PyObject *return_value = NULL; PyUnicodeObject *unichr; PyObject *default_value = NULL; if (!PyArg_ParseTuple(args, "O!|O:decimal", &PyUnicode_Type, &unichr, &default_value)) goto exit; return_value = unicodedata_UCD_decimal_impl(self, unichr, default_value); exit: return return_value; } static PyObject * unicodedata_UCD_decimal_impl(PyObject *self, PyUnicodeObject *unichr, PyObject *default_value) /*[clinic end generated code: checksum=73edde0e9cd5913ea174c4fa81504369761b7426]*/ { PyUnicodeObject *v = (PyUnicodeObject *)unichr; int have_old = 0; long rc; Py_UCS4 c; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; if (self && UCD_Check(self)) { const change_record *old = get_old_record(self, c); if (old->category_changed == 0) { /* unassigned */ have_old = 1; rc = -1; } else if (old->decimal_changed != 0xFF) { have_old = 1; rc = old->decimal_changed; } } if (!have_old) rc = Py_UNICODE_TODECIMAL(c); if (rc < 0) { if (default_value == NULL) { PyErr_SetString(PyExc_ValueError, "not a decimal"); return NULL; } else { Py_INCREF(default_value); return default_value; } } return PyLong_FromLong(rc); } PyDoc_STRVAR(unicodedata_digit__doc__, "digit(unichr[, default])\n\ \n\ Returns the digit value assigned to the Unicode character unichr as\n\ integer. If no such value is defined, default is returned, or, if\n\ not given, ValueError is raised."); static PyObject * unicodedata_digit(PyObject *self, PyObject *args) { PyUnicodeObject *v; PyObject *defobj = NULL; long rc; Py_UCS4 c; if (!PyArg_ParseTuple(args, "O!|O:digit", &PyUnicode_Type, &v, &defobj)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; rc = Py_UNICODE_TODIGIT(c); if (rc < 0) { if (defobj == NULL) { PyErr_SetString(PyExc_ValueError, "not a digit"); return NULL; } else { Py_INCREF(defobj); return defobj; } } return PyLong_FromLong(rc); } PyDoc_STRVAR(unicodedata_numeric__doc__, "numeric(unichr[, default])\n\ \n\ Returns the numeric value assigned to the Unicode character unichr\n\ as float. If no such value is defined, default is returned, or, if\n\ not given, ValueError is raised."); static PyObject * unicodedata_numeric(PyObject *self, PyObject *args) { PyUnicodeObject *v; PyObject *defobj = NULL; int have_old = 0; double rc; Py_UCS4 c; if (!PyArg_ParseTuple(args, "O!|O:numeric", &PyUnicode_Type, &v, &defobj)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; if (self && UCD_Check(self)) { const change_record *old = get_old_record(self, c); if (old->category_changed == 0) { /* unassigned */ have_old = 1; rc = -1.0; } else if (old->decimal_changed != 0xFF) { have_old = 1; rc = old->decimal_changed; } } if (!have_old) rc = Py_UNICODE_TONUMERIC(c); if (rc == -1.0) { if (defobj == NULL) { PyErr_SetString(PyExc_ValueError, "not a numeric character"); return NULL; } else { Py_INCREF(defobj); return defobj; } } return PyFloat_FromDouble(rc); } PyDoc_STRVAR(unicodedata_category__doc__, "category(unichr)\n\ \n\ Returns the general category assigned to the Unicode character\n\ unichr as string."); static PyObject * unicodedata_category(PyObject *self, PyObject *args) { PyUnicodeObject *v; int index; Py_UCS4 c; if (!PyArg_ParseTuple(args, "O!:category", &PyUnicode_Type, &v)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; index = (int) _getrecord_ex(c)->category; if (self && UCD_Check(self)) { const change_record *old = get_old_record(self, c); if (old->category_changed != 0xFF) index = old->category_changed; } return PyUnicode_FromString(_PyUnicode_CategoryNames[index]); } PyDoc_STRVAR(unicodedata_bidirectional__doc__, "bidirectional(unichr)\n\ \n\ Returns the bidirectional class assigned to the Unicode character\n\ unichr as string. If no such value is defined, an empty string is\n\ returned."); static PyObject * unicodedata_bidirectional(PyObject *self, PyObject *args) { PyUnicodeObject *v; int index; Py_UCS4 c; if (!PyArg_ParseTuple(args, "O!:bidirectional", &PyUnicode_Type, &v)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; index = (int) _getrecord_ex(c)->bidirectional; if (self && UCD_Check(self)) { const change_record *old = get_old_record(self, c); if (old->category_changed == 0) index = 0; /* unassigned */ else if (old->bidir_changed != 0xFF) index = old->bidir_changed; } return PyUnicode_FromString(_PyUnicode_BidirectionalNames[index]); } PyDoc_STRVAR(unicodedata_combining__doc__, "combining(unichr)\n\ \n\ Returns the canonical combining class assigned to the Unicode\n\ character unichr as integer. Returns 0 if no combining class is\n\ defined."); static PyObject * unicodedata_combining(PyObject *self, PyObject *args) { PyUnicodeObject *v; int index; Py_UCS4 c; if (!PyArg_ParseTuple(args, "O!:combining", &PyUnicode_Type, &v)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; index = (int) _getrecord_ex(c)->combining; if (self && UCD_Check(self)) { const change_record *old = get_old_record(self, c); if (old->category_changed == 0) index = 0; /* unassigned */ } return PyLong_FromLong(index); } PyDoc_STRVAR(unicodedata_mirrored__doc__, "mirrored(unichr)\n\ \n\ Returns the mirrored property assigned to the Unicode character\n\ unichr as integer. Returns 1 if the character has been identified as\n\ a \"mirrored\" character in bidirectional text, 0 otherwise."); static PyObject * unicodedata_mirrored(PyObject *self, PyObject *args) { PyUnicodeObject *v; int index; Py_UCS4 c; if (!PyArg_ParseTuple(args, "O!:mirrored", &PyUnicode_Type, &v)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; index = (int) _getrecord_ex(c)->mirrored; if (self && UCD_Check(self)) { const change_record *old = get_old_record(self, c); if (old->category_changed == 0) index = 0; /* unassigned */ else if (old->mirrored_changed != 0xFF) index = old->mirrored_changed; } return PyLong_FromLong(index); } PyDoc_STRVAR(unicodedata_east_asian_width__doc__, "east_asian_width(unichr)\n\ \n\ Returns the east asian width assigned to the Unicode character\n\ unichr as string."); static PyObject * unicodedata_east_asian_width(PyObject *self, PyObject *args) { PyUnicodeObject *v; int index; Py_UCS4 c; if (!PyArg_ParseTuple(args, "O!:east_asian_width", &PyUnicode_Type, &v)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; index = (int) _getrecord_ex(c)->east_asian_width; if (self && UCD_Check(self)) { const change_record *old = get_old_record(self, c); if (old->category_changed == 0) index = 0; /* unassigned */ } return PyUnicode_FromString(_PyUnicode_EastAsianWidthNames[index]); } PyDoc_STRVAR(unicodedata_decomposition__doc__, "decomposition(unichr)\n\ \n\ Returns the character decomposition mapping assigned to the Unicode\n\ character unichr as string. An empty string is returned in case no\n\ such mapping is defined."); static PyObject * unicodedata_decomposition(PyObject *self, PyObject *args) { PyUnicodeObject *v; char decomp[256]; int code, index, count; size_t i; unsigned int prefix_index; Py_UCS4 c; if (!PyArg_ParseTuple(args, "O!:decomposition", &PyUnicode_Type, &v)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; code = (int)c; if (self && UCD_Check(self)) { const change_record *old = get_old_record(self, c); if (old->category_changed == 0) return PyUnicode_FromString(""); /* unassigned */ } if (code < 0 || code >= 0x110000) index = 0; else { index = decomp_index1[(code>>DECOMP_SHIFT)]; index = decomp_index2[(index<> 8; /* XXX: could allocate the PyString up front instead (strlen(prefix) + 5 * count + 1 bytes) */ /* Based on how index is calculated above and decomp_data is generated from Tools/unicode/makeunicodedata.py, it should not be possible to overflow decomp_prefix. */ prefix_index = decomp_data[index] & 255; assert(prefix_index < Py_ARRAY_LENGTH(decomp_prefix)); /* copy prefix */ i = strlen(decomp_prefix[prefix_index]); memcpy(decomp, decomp_prefix[prefix_index], i); while (count-- > 0) { if (i) decomp[i++] = ' '; assert(i < sizeof(decomp)); PyOS_snprintf(decomp + i, sizeof(decomp) - i, "%04X", decomp_data[++index]); i += strlen(decomp + i); } return PyUnicode_FromStringAndSize(decomp, i); } static void get_decomp_record(PyObject *self, Py_UCS4 code, int *index, int *prefix, int *count) { if (code >= 0x110000) { *index = 0; } else if (self && UCD_Check(self) && get_old_record(self, code)->category_changed==0) { /* unassigned in old version */ *index = 0; } else { *index = decomp_index1[(code>>DECOMP_SHIFT)]; *index = decomp_index2[(*index<> 8; *prefix = decomp_data[*index] & 255; (*index)++; } #define SBase 0xAC00 #define LBase 0x1100 #define VBase 0x1161 #define TBase 0x11A7 #define LCount 19 #define VCount 21 #define TCount 28 #define NCount (VCount*TCount) #define SCount (LCount*NCount) static PyObject* nfd_nfkd(PyObject *self, PyObject *input, int k) { PyObject *result; Py_UCS4 *output; Py_ssize_t i, o, osize; int kind; void *data; /* Longest decomposition in Unicode 3.2: U+FDFA */ Py_UCS4 stack[20]; Py_ssize_t space, isize; int index, prefix, count, stackptr; unsigned char prev, cur; stackptr = 0; isize = PyUnicode_GET_LENGTH(input); /* Overallocate at most 10 characters. */ space = (isize > 10 ? 10 : isize) + isize; osize = space; output = PyMem_Malloc(space * sizeof(Py_UCS4)); if (!output) { PyErr_NoMemory(); return NULL; } i = o = 0; kind = PyUnicode_KIND(input); data = PyUnicode_DATA(input); while (i < isize) { stack[stackptr++] = PyUnicode_READ(kind, data, i++); while(stackptr) { Py_UCS4 code = stack[--stackptr]; /* Hangul Decomposition adds three characters in a single step, so we need at least that much room. */ if (space < 3) { Py_UCS4 *new_output; osize += 10; space += 10; new_output = PyMem_Realloc(output, osize*sizeof(Py_UCS4)); if (new_output == NULL) { PyMem_Free(output); PyErr_NoMemory(); return NULL; } output = new_output; } /* Hangul Decomposition. */ if (SBase <= code && code < (SBase+SCount)) { int SIndex = code - SBase; int L = LBase + SIndex / NCount; int V = VBase + (SIndex % NCount) / TCount; int T = TBase + SIndex % TCount; output[o++] = L; output[o++] = V; space -= 2; if (T != TBase) { output[o++] = T; space --; } continue; } /* normalization changes */ if (self && UCD_Check(self)) { Py_UCS4 value = ((PreviousDBVersion*)self)->normalization(code); if (value != 0) { stack[stackptr++] = value; continue; } } /* Other decompositions. */ get_decomp_record(self, code, &index, &prefix, &count); /* Copy character if it is not decomposable, or has a compatibility decomposition, but we do NFD. */ if (!count || (prefix && !k)) { output[o++] = code; space--; continue; } /* Copy decomposition onto the stack, in reverse order. */ while(count) { code = decomp_data[index + (--count)]; stack[stackptr++] = code; } } } result = PyUnicode_FromKindAndData(PyUnicode_4BYTE_KIND, output, o); PyMem_Free(output); if (!result) return NULL; /* result is guaranteed to be ready, as it is compact. */ kind = PyUnicode_KIND(result); data = PyUnicode_DATA(result); /* Sort canonically. */ i = 0; prev = _getrecord_ex(PyUnicode_READ(kind, data, i))->combining; for (i++; i < PyUnicode_GET_LENGTH(result); i++) { cur = _getrecord_ex(PyUnicode_READ(kind, data, i))->combining; if (prev == 0 || cur == 0 || prev <= cur) { prev = cur; continue; } /* Non-canonical order. Need to switch *i with previous. */ o = i - 1; while (1) { Py_UCS4 tmp = PyUnicode_READ(kind, data, o+1); PyUnicode_WRITE(kind, data, o+1, PyUnicode_READ(kind, data, o)); PyUnicode_WRITE(kind, data, o, tmp); o--; if (o < 0) break; prev = _getrecord_ex(PyUnicode_READ(kind, data, o))->combining; if (prev == 0 || prev <= cur) break; } prev = _getrecord_ex(PyUnicode_READ(kind, data, i))->combining; } return result; } static int find_nfc_index(PyObject *self, struct reindex* nfc, Py_UCS4 code) { unsigned int index; for (index = 0; nfc[index].start; index++) { unsigned int start = nfc[index].start; if (code < start) return -1; if (code <= start + nfc[index].count) { unsigned int delta = code - start; return nfc[index].index + delta; } } return -1; } static PyObject* nfc_nfkc(PyObject *self, PyObject *input, int k) { PyObject *result; int kind; void *data; Py_UCS4 *output; Py_ssize_t i, i1, o, len; int f,l,index,index1,comb; Py_UCS4 code; Py_ssize_t skipped[20]; int cskipped = 0; result = nfd_nfkd(self, input, k); if (!result) return NULL; /* result will be "ready". */ kind = PyUnicode_KIND(result); data = PyUnicode_DATA(result); len = PyUnicode_GET_LENGTH(result); /* We allocate a buffer for the output. If we find that we made no changes, we still return the NFD result. */ output = PyMem_Malloc(len * sizeof(Py_UCS4)); if (!output) { PyErr_NoMemory(); Py_DECREF(result); return 0; } i = o = 0; again: while (i < len) { for (index = 0; index < cskipped; index++) { if (skipped[index] == i) { /* *i character is skipped. Remove from list. */ skipped[index] = skipped[cskipped-1]; cskipped--; i++; goto again; /* continue while */ } } /* Hangul Composition. We don't need to check for pairs, since we always have decomposed data. */ code = PyUnicode_READ(kind, data, i); if (LBase <= code && code < (LBase+LCount) && i + 1 < len && VBase <= PyUnicode_READ(kind, data, i+1) && PyUnicode_READ(kind, data, i+1) <= (VBase+VCount)) { int LIndex, VIndex; LIndex = code - LBase; VIndex = PyUnicode_READ(kind, data, i+1) - VBase; code = SBase + (LIndex*VCount+VIndex)*TCount; i+=2; if (i < len && TBase <= PyUnicode_READ(kind, data, i) && PyUnicode_READ(kind, data, i) <= (TBase+TCount)) { code += PyUnicode_READ(kind, data, i)-TBase; i++; } output[o++] = code; continue; } /* code is still input[i] here */ f = find_nfc_index(self, nfc_first, code); if (f == -1) { output[o++] = code; i++; continue; } /* Find next unblocked character. */ i1 = i+1; comb = 0; /* output base character for now; might be updated later. */ output[o] = PyUnicode_READ(kind, data, i); while (i1 < len) { Py_UCS4 code1 = PyUnicode_READ(kind, data, i1); int comb1 = _getrecord_ex(code1)->combining; if (comb) { if (comb1 == 0) break; if (comb >= comb1) { /* Character is blocked. */ i1++; continue; } } l = find_nfc_index(self, nfc_last, code1); /* i1 cannot be combined with i. If i1 is a starter, we don't need to look further. Otherwise, record the combining class. */ if (l == -1) { not_combinable: if (comb1 == 0) break; comb = comb1; i1++; continue; } index = f*TOTAL_LAST + l; index1 = comp_index[index >> COMP_SHIFT]; code = comp_data[(index1<combining; unsigned char quickcheck = record->normalization_quick_check; if (quickcheck & quickcheck_mask) return 0; /* this string might need normalization */ if (combining && prev_combining > combining) return 0; /* non-canonical sort order, not normalized */ prev_combining = combining; } return 1; /* certainly normalized */ } PyDoc_STRVAR(unicodedata_normalize__doc__, "normalize(form, unistr)\n\ \n\ Return the normal form 'form' for the Unicode string unistr. Valid\n\ values for form are 'NFC', 'NFKC', 'NFD', and 'NFKD'."); static PyObject* unicodedata_normalize(PyObject *self, PyObject *args) { char *form; PyObject *input; if(!PyArg_ParseTuple(args, "sO!:normalize", &form, &PyUnicode_Type, &input)) return NULL; if (PyUnicode_READY(input) == -1) return NULL; if (PyUnicode_GET_LENGTH(input) == 0) { /* Special case empty input strings, since resizing them later would cause internal errors. */ Py_INCREF(input); return input; } if (strcmp(form, "NFC") == 0) { if (is_normalized(self, input, 1, 0)) { Py_INCREF(input); return input; } return nfc_nfkc(self, input, 0); } if (strcmp(form, "NFKC") == 0) { if (is_normalized(self, input, 1, 1)) { Py_INCREF(input); return input; } return nfc_nfkc(self, input, 1); } if (strcmp(form, "NFD") == 0) { if (is_normalized(self, input, 0, 0)) { Py_INCREF(input); return input; } return nfd_nfkd(self, input, 0); } if (strcmp(form, "NFKD") == 0) { if (is_normalized(self, input, 0, 1)) { Py_INCREF(input); return input; } return nfd_nfkd(self, input, 1); } PyErr_SetString(PyExc_ValueError, "invalid normalization form"); return NULL; } /* -------------------------------------------------------------------- */ /* unicode character name tables */ /* data file generated by Tools/unicode/makeunicodedata.py */ #include "unicodename_db.h" /* -------------------------------------------------------------------- */ /* database code (cut and pasted from the unidb package) */ static unsigned long _gethash(const char *s, int len, int scale) { int i; unsigned long h = 0; unsigned long ix; for (i = 0; i < len; i++) { h = (h * scale) + (unsigned char) Py_TOUPPER(Py_CHARMASK(s[i])); ix = h & 0xff000000; if (ix) h = (h ^ ((ix>>24) & 0xff)) & 0x00ffffff; } return h; } static char *hangul_syllables[][3] = { { "G", "A", "" }, { "GG", "AE", "G" }, { "N", "YA", "GG" }, { "D", "YAE", "GS" }, { "DD", "EO", "N", }, { "R", "E", "NJ" }, { "M", "YEO", "NH" }, { "B", "YE", "D" }, { "BB", "O", "L" }, { "S", "WA", "LG" }, { "SS", "WAE", "LM" }, { "", "OE", "LB" }, { "J", "YO", "LS" }, { "JJ", "U", "LT" }, { "C", "WEO", "LP" }, { "K", "WE", "LH" }, { "T", "WI", "M" }, { "P", "YU", "B" }, { "H", "EU", "BS" }, { 0, "YI", "S" }, { 0, "I", "SS" }, { 0, 0, "NG" }, { 0, 0, "J" }, { 0, 0, "C" }, { 0, 0, "K" }, { 0, 0, "T" }, { 0, 0, "P" }, { 0, 0, "H" } }; /* These ranges need to match makeunicodedata.py:cjk_ranges. */ static int is_unified_ideograph(Py_UCS4 code) { return (0x3400 <= code && code <= 0x4DB5) || /* CJK Ideograph Extension A */ (0x4E00 <= code && code <= 0x9FCC) || /* CJK Ideograph */ (0x20000 <= code && code <= 0x2A6D6) || /* CJK Ideograph Extension B */ (0x2A700 <= code && code <= 0x2B734) || /* CJK Ideograph Extension C */ (0x2B740 <= code && code <= 0x2B81D); /* CJK Ideograph Extension D */ } /* macros used to determine if the given codepoint is in the PUA range that * we are using to store aliases and named sequences */ #define IS_ALIAS(cp) ((cp >= aliases_start) && (cp < aliases_end)) #define IS_NAMED_SEQ(cp) ((cp >= named_sequences_start) && \ (cp < named_sequences_end)) static int _getucname(PyObject *self, Py_UCS4 code, char* buffer, int buflen, int with_alias_and_seq) { /* Find the name associated with the given codepoint. * If with_alias_and_seq is 1, check for names in the Private Use Area 15 * that we are using for aliases and named sequences. */ int offset; int i; int word; unsigned char* w; if (code >= 0x110000) return 0; /* XXX should we just skip all the codepoints in the PUAs here? */ if (!with_alias_and_seq && (IS_ALIAS(code) || IS_NAMED_SEQ(code))) return 0; if (self && UCD_Check(self)) { /* in 3.2.0 there are no aliases and named sequences */ const change_record *old; if (IS_ALIAS(code) || IS_NAMED_SEQ(code)) return 0; old = get_old_record(self, code); if (old->category_changed == 0) { /* unassigned */ return 0; } } if (SBase <= code && code < SBase+SCount) { /* Hangul syllable. */ int SIndex = code - SBase; int L = SIndex / NCount; int V = (SIndex % NCount) / TCount; int T = SIndex % TCount; if (buflen < 27) /* Worst case: HANGUL SYLLABLE <10chars>. */ return 0; strcpy(buffer, "HANGUL SYLLABLE "); buffer += 16; strcpy(buffer, hangul_syllables[L][0]); buffer += strlen(hangul_syllables[L][0]); strcpy(buffer, hangul_syllables[V][1]); buffer += strlen(hangul_syllables[V][1]); strcpy(buffer, hangul_syllables[T][2]); buffer += strlen(hangul_syllables[T][2]); *buffer = '\0'; return 1; } if (is_unified_ideograph(code)) { if (buflen < 28) /* Worst case: CJK UNIFIED IDEOGRAPH-20000 */ return 0; sprintf(buffer, "CJK UNIFIED IDEOGRAPH-%X", code); return 1; } /* get offset into phrasebook */ offset = phrasebook_offset1[(code>>phrasebook_shift)]; offset = phrasebook_offset2[(offset<= 0) { word = (word << 8) + phrasebook[offset+1]; offset += 2; } else word = phrasebook[offset++]; if (i) { if (i > buflen) return 0; /* buffer overflow */ buffer[i++] = ' '; } /* copy word string from lexicon. the last character in the word has bit 7 set. the last word in a string ends with 0x80 */ w = lexicon + lexicon_offset[word]; while (*w < 128) { if (i >= buflen) return 0; /* buffer overflow */ buffer[i++] = *w++; } if (i >= buflen) return 0; /* buffer overflow */ buffer[i++] = *w & 127; if (*w == 128) break; /* end of word */ } return 1; } static int _cmpname(PyObject *self, int code, const char* name, int namelen) { /* check if code corresponds to the given name */ int i; char buffer[NAME_MAXLEN]; if (!_getucname(self, code, buffer, sizeof(buffer), 1)) return 0; for (i = 0; i < namelen; i++) { if (Py_TOUPPER(Py_CHARMASK(name[i])) != buffer[i]) return 0; } return buffer[namelen] == '\0'; } static void find_syllable(const char *str, int *len, int *pos, int count, int column) { int i, len1; *len = -1; for (i = 0; i < count; i++) { char *s = hangul_syllables[i][column]; len1 = Py_SAFE_DOWNCAST(strlen(s), size_t, int); if (len1 <= *len) continue; if (strncmp(str, s, len1) == 0) { *len = len1; *pos = i; } } if (*len == -1) { *len = 0; } } static int _check_alias_and_seq(unsigned int cp, Py_UCS4* code, int with_named_seq) { /* check if named sequences are allowed */ if (!with_named_seq && IS_NAMED_SEQ(cp)) return 0; /* if the codepoint is in the PUA range that we use for aliases, * convert it to obtain the right codepoint */ if (IS_ALIAS(cp)) *code = name_aliases[cp-aliases_start]; else *code = cp; return 1; } static int _getcode(PyObject* self, const char* name, int namelen, Py_UCS4* code, int with_named_seq) { /* Return the codepoint associated with the given name. * Named aliases are resolved too (unless self != NULL (i.e. we are using * 3.2.0)). If with_named_seq is 1, returns the PUA codepoint that we are * using for the named sequence, and the caller must then convert it. */ unsigned int h, v; unsigned int mask = code_size-1; unsigned int i, incr; /* Check for hangul syllables. */ if (strncmp(name, "HANGUL SYLLABLE ", 16) == 0) { int len, L = -1, V = -1, T = -1; const char *pos = name + 16; find_syllable(pos, &len, &L, LCount, 0); pos += len; find_syllable(pos, &len, &V, VCount, 1); pos += len; find_syllable(pos, &len, &T, TCount, 2); pos += len; if (L != -1 && V != -1 && T != -1 && pos-name == namelen) { *code = SBase + (L*VCount+V)*TCount + T; return 1; } /* Otherwise, it's an illegal syllable name. */ return 0; } /* Check for unified ideographs. */ if (strncmp(name, "CJK UNIFIED IDEOGRAPH-", 22) == 0) { /* Four or five hexdigits must follow. */ v = 0; name += 22; namelen -= 22; if (namelen != 4 && namelen != 5) return 0; while (namelen--) { v *= 16; if (*name >= '0' && *name <= '9') v += *name - '0'; else if (*name >= 'A' && *name <= 'F') v += *name - 'A' + 10; else return 0; name++; } if (!is_unified_ideograph(v)) return 0; *code = v; return 1; } /* the following is the same as python's dictionary lookup, with only minor changes. see the makeunicodedata script for more details */ h = (unsigned int) _gethash(name, namelen, code_magic); i = (~h) & mask; v = code_hash[i]; if (!v) return 0; if (_cmpname(self, v, name, namelen)) return _check_alias_and_seq(v, code, with_named_seq); incr = (h ^ (h >> 3)) & mask; if (!incr) incr = mask; for (;;) { i = (i + incr) & mask; v = code_hash[i]; if (!v) return 0; if (_cmpname(self, v, name, namelen)) return _check_alias_and_seq(v, code, with_named_seq); incr = incr << 1; if (incr > mask) incr = incr ^ code_poly; } } static const _PyUnicode_Name_CAPI hashAPI = { sizeof(_PyUnicode_Name_CAPI), _getucname, _getcode }; /* -------------------------------------------------------------------- */ /* Python bindings */ PyDoc_STRVAR(unicodedata_name__doc__, "name(unichr[, default])\n\ Returns the name assigned to the Unicode character unichr as a\n\ string. If no name is defined, default is returned, or, if not\n\ given, ValueError is raised."); static PyObject * unicodedata_name(PyObject* self, PyObject* args) { char name[NAME_MAXLEN]; Py_UCS4 c; PyUnicodeObject* v; PyObject* defobj = NULL; if (!PyArg_ParseTuple(args, "O!|O:name", &PyUnicode_Type, &v, &defobj)) return NULL; c = getuchar(v); if (c == (Py_UCS4)-1) return NULL; if (!_getucname(self, c, name, sizeof(name), 0)) { if (defobj == NULL) { PyErr_SetString(PyExc_ValueError, "no such name"); return NULL; } else { Py_INCREF(defobj); return defobj; } } return PyUnicode_FromString(name); } PyDoc_STRVAR(unicodedata_lookup__doc__, "lookup(name)\n\ \n\ Look up character by name. If a character with the\n\ given name is found, return the corresponding Unicode\n\ character. If not found, KeyError is raised."); static PyObject * unicodedata_lookup(PyObject* self, PyObject* args) { Py_UCS4 code; char* name; int namelen; unsigned int index; if (!PyArg_ParseTuple(args, "s#:lookup", &name, &namelen)) return NULL; if (!_getcode(self, name, namelen, &code, 1)) { PyErr_Format(PyExc_KeyError, "undefined character name '%s'", name); return NULL; } /* check if code is in the PUA range that we use for named sequences and convert it */ if (IS_NAMED_SEQ(code)) { index = code-named_sequences_start; return PyUnicode_FromKindAndData(PyUnicode_2BYTE_KIND, named_sequences[index].seq, named_sequences[index].seqlen); } return PyUnicode_FromOrdinal(code); } /* XXX Add doc strings. */ static PyMethodDef unicodedata_functions[] = { UNICODEDATA_UCD_DECIMAL_METHODDEF {"digit", unicodedata_digit, METH_VARARGS, unicodedata_digit__doc__}, {"numeric", unicodedata_numeric, METH_VARARGS, unicodedata_numeric__doc__}, {"category", unicodedata_category, METH_VARARGS, unicodedata_category__doc__}, {"bidirectional", unicodedata_bidirectional, METH_VARARGS, unicodedata_bidirectional__doc__}, {"combining", unicodedata_combining, METH_VARARGS, unicodedata_combining__doc__}, {"mirrored", unicodedata_mirrored, METH_VARARGS, unicodedata_mirrored__doc__}, {"east_asian_width", unicodedata_east_asian_width, METH_VARARGS, unicodedata_east_asian_width__doc__}, {"decomposition", unicodedata_decomposition, METH_VARARGS, unicodedata_decomposition__doc__}, {"name", unicodedata_name, METH_VARARGS, unicodedata_name__doc__}, {"lookup", unicodedata_lookup, METH_VARARGS, unicodedata_lookup__doc__}, {"normalize", unicodedata_normalize, METH_VARARGS, unicodedata_normalize__doc__}, {NULL, NULL} /* sentinel */ }; static PyTypeObject UCD_Type = { /* The ob_type field must be initialized in the module init function * to be portable to Windows without using C++. */ PyVarObject_HEAD_INIT(NULL, 0) "unicodedata.UCD", /*tp_name*/ sizeof(PreviousDBVersion), /*tp_basicsize*/ 0, /*tp_itemsize*/ /* methods */ (destructor)PyObject_Del, /*tp_dealloc*/ 0, /*tp_print*/ 0, /*tp_getattr*/ 0, /*tp_setattr*/ 0, /*tp_reserved*/ 0, /*tp_repr*/ 0, /*tp_as_number*/ 0, /*tp_as_sequence*/ 0, /*tp_as_mapping*/ 0, /*tp_hash*/ 0, /*tp_call*/ 0, /*tp_str*/ PyObject_GenericGetAttr,/*tp_getattro*/ 0, /*tp_setattro*/ 0, /*tp_as_buffer*/ Py_TPFLAGS_DEFAULT, /*tp_flags*/ 0, /*tp_doc*/ 0, /*tp_traverse*/ 0, /*tp_clear*/ 0, /*tp_richcompare*/ 0, /*tp_weaklistoffset*/ 0, /*tp_iter*/ 0, /*tp_iternext*/ unicodedata_functions, /*tp_methods*/ DB_members, /*tp_members*/ 0, /*tp_getset*/ 0, /*tp_base*/ 0, /*tp_dict*/ 0, /*tp_descr_get*/ 0, /*tp_descr_set*/ 0, /*tp_dictoffset*/ 0, /*tp_init*/ 0, /*tp_alloc*/ 0, /*tp_new*/ 0, /*tp_free*/ 0, /*tp_is_gc*/ }; PyDoc_STRVAR(unicodedata_docstring, "This module provides access to the Unicode Character Database which\n\ defines character properties for all Unicode characters. The data in\n\ this database is based on the UnicodeData.txt file version\n\ " UNIDATA_VERSION " which is publically available from ftp://ftp.unicode.org/.\n\ \n\ The module uses the same names and symbols as defined by the\n\ UnicodeData File Format " UNIDATA_VERSION "."); static struct PyModuleDef unicodedatamodule = { PyModuleDef_HEAD_INIT, "unicodedata", unicodedata_docstring, -1, unicodedata_functions, NULL, NULL, NULL, NULL }; PyMODINIT_FUNC PyInit_unicodedata(void) { PyObject *m, *v; Py_TYPE(&UCD_Type) = &PyType_Type; m = PyModule_Create(&unicodedatamodule); if (!m) return NULL; PyModule_AddStringConstant(m, "unidata_version", UNIDATA_VERSION); Py_INCREF(&UCD_Type); PyModule_AddObject(m, "UCD", (PyObject*)&UCD_Type); /* Previous versions */ v = new_previous_version("3.2.0", get_change_3_2_0, normalization_3_2_0); if (v != NULL) PyModule_AddObject(m, "ucd_3_2_0", v); /* Export C API */ v = PyCapsule_New((void *)&hashAPI, PyUnicodeData_CAPSULE_NAME, NULL); if (v != NULL) PyModule_AddObject(m, "ucnhash_CAPI", v); return m; } /* Local variables: c-basic-offset: 4 indent-tabs-mode: nil End: */