/*------------------------------------------------------------------------- * * varlena.c * Functions for the variable-length built-in types. * * Portions Copyright (c) 1996-2021, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * src/backend/utils/adt/varlena.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include #include #include "access/detoast.h" #include "access/toast_compression.h" #include "catalog/pg_collation.h" #include "catalog/pg_type.h" #include "common/hashfn.h" #include "common/int.h" #include "common/unicode_norm.h" #include "lib/hyperloglog.h" #include "libpq/pqformat.h" #include "miscadmin.h" #include "nodes/execnodes.h" #include "parser/scansup.h" #include "port/pg_bswap.h" #include "regex/regex.h" #include "utils/builtins.h" #include "utils/bytea.h" #include "utils/lsyscache.h" #include "utils/memutils.h" #include "utils/pg_locale.h" #include "utils/sortsupport.h" #include "utils/varlena.h" /* GUC variable */ int bytea_output = BYTEA_OUTPUT_HEX; typedef struct varlena unknown; typedef struct varlena VarString; /* * State for text_position_* functions. */ typedef struct { bool is_multibyte; /* T if multibyte encoding */ bool is_multibyte_char_in_char; /* need to check char boundaries? */ char *str1; /* haystack string */ char *str2; /* needle string */ int len1; /* string lengths in bytes */ int len2; /* Skip table for Boyer-Moore-Horspool search algorithm: */ int skiptablemask; /* mask for ANDing with skiptable subscripts */ int skiptable[256]; /* skip distance for given mismatched char */ char *last_match; /* pointer to last match in 'str1' */ /* * Sometimes we need to convert the byte position of a match to a * character position. These store the last position that was converted, * so that on the next call, we can continue from that point, rather than * count characters from the very beginning. */ char *refpoint; /* pointer within original haystack string */ int refpos; /* 0-based character offset of the same point */ } TextPositionState; typedef struct { char *buf1; /* 1st string, or abbreviation original string * buf */ char *buf2; /* 2nd string, or abbreviation strxfrm() buf */ int buflen1; int buflen2; int last_len1; /* Length of last buf1 string/strxfrm() input */ int last_len2; /* Length of last buf2 string/strxfrm() blob */ int last_returned; /* Last comparison result (cache) */ bool cache_blob; /* Does buf2 contain strxfrm() blob, etc? */ bool collate_c; Oid typid; /* Actual datatype (text/bpchar/bytea/name) */ hyperLogLogState abbr_card; /* Abbreviated key cardinality state */ hyperLogLogState full_card; /* Full key cardinality state */ double prop_card; /* Required cardinality proportion */ pg_locale_t locale; } VarStringSortSupport; /* * Output data for split_text(): we output either to an array or a table. * tupstore and tupdesc must be set up in advance to output to a table. */ typedef struct { ArrayBuildState *astate; Tuplestorestate *tupstore; TupleDesc tupdesc; } SplitTextOutputData; /* * This should be large enough that most strings will fit, but small enough * that we feel comfortable putting it on the stack */ #define TEXTBUFLEN 1024 #define DatumGetUnknownP(X) ((unknown *) PG_DETOAST_DATUM(X)) #define DatumGetUnknownPCopy(X) ((unknown *) PG_DETOAST_DATUM_COPY(X)) #define PG_GETARG_UNKNOWN_P(n) DatumGetUnknownP(PG_GETARG_DATUM(n)) #define PG_GETARG_UNKNOWN_P_COPY(n) DatumGetUnknownPCopy(PG_GETARG_DATUM(n)) #define PG_RETURN_UNKNOWN_P(x) PG_RETURN_POINTER(x) #define DatumGetVarStringP(X) ((VarString *) PG_DETOAST_DATUM(X)) #define DatumGetVarStringPP(X) ((VarString *) PG_DETOAST_DATUM_PACKED(X)) static int varstrfastcmp_c(Datum x, Datum y, SortSupport ssup); static int bpcharfastcmp_c(Datum x, Datum y, SortSupport ssup); static int namefastcmp_c(Datum x, Datum y, SortSupport ssup); static int varlenafastcmp_locale(Datum x, Datum y, SortSupport ssup); static int namefastcmp_locale(Datum x, Datum y, SortSupport ssup); static int varstrfastcmp_locale(char *a1p, int len1, char *a2p, int len2, SortSupport ssup); static int varstrcmp_abbrev(Datum x, Datum y, SortSupport ssup); static Datum varstr_abbrev_convert(Datum original, SortSupport ssup); static bool varstr_abbrev_abort(int memtupcount, SortSupport ssup); static int32 text_length(Datum str); static text *text_catenate(text *t1, text *t2); static text *text_substring(Datum str, int32 start, int32 length, bool length_not_specified); static text *text_overlay(text *t1, text *t2, int sp, int sl); static int text_position(text *t1, text *t2, Oid collid); static void text_position_setup(text *t1, text *t2, Oid collid, TextPositionState *state); static bool text_position_next(TextPositionState *state); static char *text_position_next_internal(char *start_ptr, TextPositionState *state); static char *text_position_get_match_ptr(TextPositionState *state); static int text_position_get_match_pos(TextPositionState *state); static void text_position_cleanup(TextPositionState *state); static void check_collation_set(Oid collid); static int text_cmp(text *arg1, text *arg2, Oid collid); static bytea *bytea_catenate(bytea *t1, bytea *t2); static bytea *bytea_substring(Datum str, int S, int L, bool length_not_specified); static bytea *bytea_overlay(bytea *t1, bytea *t2, int sp, int sl); static void appendStringInfoText(StringInfo str, const text *t); static bool split_text(FunctionCallInfo fcinfo, SplitTextOutputData *tstate); static void split_text_accum_result(SplitTextOutputData *tstate, text *field_value, text *null_string, Oid collation); static text *array_to_text_internal(FunctionCallInfo fcinfo, ArrayType *v, const char *fldsep, const char *null_string); static StringInfo makeStringAggState(FunctionCallInfo fcinfo); static bool text_format_parse_digits(const char **ptr, const char *end_ptr, int *value); static const char *text_format_parse_format(const char *start_ptr, const char *end_ptr, int *argpos, int *widthpos, int *flags, int *width); static void text_format_string_conversion(StringInfo buf, char conversion, FmgrInfo *typOutputInfo, Datum value, bool isNull, int flags, int width); static void text_format_append_string(StringInfo buf, const char *str, int flags, int width); /***************************************************************************** * CONVERSION ROUTINES EXPORTED FOR USE BY C CODE * *****************************************************************************/ /* * cstring_to_text * * Create a text value from a null-terminated C string. * * The new text value is freshly palloc'd with a full-size VARHDR. */ text * cstring_to_text(const char *s) { return cstring_to_text_with_len(s, strlen(s)); } /* * cstring_to_text_with_len * * Same as cstring_to_text except the caller specifies the string length; * the string need not be null_terminated. */ text * cstring_to_text_with_len(const char *s, int len) { text *result = (text *) palloc(len + VARHDRSZ); SET_VARSIZE(result, len + VARHDRSZ); memcpy(VARDATA(result), s, len); return result; } /* * text_to_cstring * * Create a palloc'd, null-terminated C string from a text value. * * We support being passed a compressed or toasted text value. * This is a bit bogus since such values shouldn't really be referred to as * "text *", but it seems useful for robustness. If we didn't handle that * case here, we'd need another routine that did, anyway. */ char * text_to_cstring(const text *t) { /* must cast away the const, unfortunately */ text *tunpacked = pg_detoast_datum_packed(unconstify(text *, t)); int len = VARSIZE_ANY_EXHDR(tunpacked); char *result; result = (char *) palloc(len + 1); memcpy(result, VARDATA_ANY(tunpacked), len); result[len] = '\0'; if (tunpacked != t) pfree(tunpacked); return result; } /* * text_to_cstring_buffer * * Copy a text value into a caller-supplied buffer of size dst_len. * * The text string is truncated if necessary to fit. The result is * guaranteed null-terminated (unless dst_len == 0). * * We support being passed a compressed or toasted text value. * This is a bit bogus since such values shouldn't really be referred to as * "text *", but it seems useful for robustness. If we didn't handle that * case here, we'd need another routine that did, anyway. */ void text_to_cstring_buffer(const text *src, char *dst, size_t dst_len) { /* must cast away the const, unfortunately */ text *srcunpacked = pg_detoast_datum_packed(unconstify(text *, src)); size_t src_len = VARSIZE_ANY_EXHDR(srcunpacked); if (dst_len > 0) { dst_len--; if (dst_len >= src_len) dst_len = src_len; else /* ensure truncation is encoding-safe */ dst_len = pg_mbcliplen(VARDATA_ANY(srcunpacked), src_len, dst_len); memcpy(dst, VARDATA_ANY(srcunpacked), dst_len); dst[dst_len] = '\0'; } if (srcunpacked != src) pfree(srcunpacked); } /***************************************************************************** * USER I/O ROUTINES * *****************************************************************************/ #define VAL(CH) ((CH) - '0') #define DIG(VAL) ((VAL) + '0') /* * byteain - converts from printable representation of byte array * * Non-printable characters must be passed as '\nnn' (octal) and are * converted to internal form. '\' must be passed as '\\'. * ereport(ERROR, ...) if bad form. * * BUGS: * The input is scanned twice. * The error checking of input is minimal. */ Datum byteain(PG_FUNCTION_ARGS) { char *inputText = PG_GETARG_CSTRING(0); char *tp; char *rp; int bc; bytea *result; /* Recognize hex input */ if (inputText[0] == '\\' && inputText[1] == 'x') { size_t len = strlen(inputText); bc = (len - 2) / 2 + VARHDRSZ; /* maximum possible length */ result = palloc(bc); bc = hex_decode(inputText + 2, len - 2, VARDATA(result)); SET_VARSIZE(result, bc + VARHDRSZ); /* actual length */ PG_RETURN_BYTEA_P(result); } /* Else, it's the traditional escaped style */ for (bc = 0, tp = inputText; *tp != '\0'; bc++) { if (tp[0] != '\\') tp++; else if ((tp[0] == '\\') && (tp[1] >= '0' && tp[1] <= '3') && (tp[2] >= '0' && tp[2] <= '7') && (tp[3] >= '0' && tp[3] <= '7')) tp += 4; else if ((tp[0] == '\\') && (tp[1] == '\\')) tp += 2; else { /* * one backslash, not followed by another or ### valid octal */ ereport(ERROR, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s", "bytea"))); } } bc += VARHDRSZ; result = (bytea *) palloc(bc); SET_VARSIZE(result, bc); tp = inputText; rp = VARDATA(result); while (*tp != '\0') { if (tp[0] != '\\') *rp++ = *tp++; else if ((tp[0] == '\\') && (tp[1] >= '0' && tp[1] <= '3') && (tp[2] >= '0' && tp[2] <= '7') && (tp[3] >= '0' && tp[3] <= '7')) { bc = VAL(tp[1]); bc <<= 3; bc += VAL(tp[2]); bc <<= 3; *rp++ = bc + VAL(tp[3]); tp += 4; } else if ((tp[0] == '\\') && (tp[1] == '\\')) { *rp++ = '\\'; tp += 2; } else { /* * We should never get here. The first pass should not allow it. */ ereport(ERROR, (errcode(ERRCODE_INVALID_TEXT_REPRESENTATION), errmsg("invalid input syntax for type %s", "bytea"))); } } PG_RETURN_BYTEA_P(result); } /* * byteaout - converts to printable representation of byte array * * In the traditional escaped format, non-printable characters are * printed as '\nnn' (octal) and '\' as '\\'. */ Datum byteaout(PG_FUNCTION_ARGS) { bytea *vlena = PG_GETARG_BYTEA_PP(0); char *result; char *rp; if (bytea_output == BYTEA_OUTPUT_HEX) { /* Print hex format */ rp = result = palloc(VARSIZE_ANY_EXHDR(vlena) * 2 + 2 + 1); *rp++ = '\\'; *rp++ = 'x'; rp += hex_encode(VARDATA_ANY(vlena), VARSIZE_ANY_EXHDR(vlena), rp); } else if (bytea_output == BYTEA_OUTPUT_ESCAPE) { /* Print traditional escaped format */ char *vp; uint64 len; int i; len = 1; /* empty string has 1 char */ vp = VARDATA_ANY(vlena); for (i = VARSIZE_ANY_EXHDR(vlena); i != 0; i--, vp++) { if (*vp == '\\') len += 2; else if ((unsigned char) *vp < 0x20 || (unsigned char) *vp > 0x7e) len += 4; else len++; } /* * In principle len can't overflow uint32 if the input fit in 1GB, but * for safety let's check rather than relying on palloc's internal * check. */ if (len > MaxAllocSize) ereport(ERROR, (errcode(ERRCODE_PROGRAM_LIMIT_EXCEEDED), errmsg_internal("result of bytea output conversion is too large"))); rp = result = (char *) palloc(len); vp = VARDATA_ANY(vlena); for (i = VARSIZE_ANY_EXHDR(vlena); i != 0; i--, vp++) { if (*vp == '\\') { *rp++ = '\\'; *rp++ = '\\'; } else if ((unsigned char) *vp < 0x20 || (unsigned char) *vp > 0x7e) { int val; /* holds unprintable chars */ val = *vp; rp[0] = '\\'; rp[3] = DIG(val & 07); val >>= 3; rp[2] = DIG(val & 07); val >>= 3; rp[1] = DIG(val & 03); rp += 4; } else *rp++ = *vp; } } else { elog(ERROR, "unrecognized bytea_output setting: %d", bytea_output); rp = result = NULL; /* keep compiler quiet */ } *rp = '\0'; PG_RETURN_CSTRING(result); } /* * bytearecv - converts external binary format to bytea */ Datum bytearecv(PG_FUNCTION_ARGS) { StringInfo buf = (StringInfo) PG_GETARG_POINTER(0); bytea *result; int nbytes; nbytes = buf->len - buf->cursor; result = (bytea *) palloc(nbytes + VARHDRSZ); SET_VARSIZE(result, nbytes + VARHDRSZ); pq_copymsgbytes(buf, VARDATA(result), nbytes); PG_RETURN_BYTEA_P(result); } /* * byteasend - converts bytea to binary format * * This is a special case: just copy the input... */ Datum byteasend(PG_FUNCTION_ARGS) { bytea *vlena = PG_GETARG_BYTEA_P_COPY(0); PG_RETURN_BYTEA_P(vlena); } Datum bytea_string_agg_transfn(PG_FUNCTION_ARGS) { StringInfo state; state = PG_ARGISNULL(0) ? NULL : (StringInfo) PG_GETARG_POINTER(0); /* Append the value unless null. */ if (!PG_ARGISNULL(1)) { bytea *value = PG_GETARG_BYTEA_PP(1); /* On the first time through, we ignore the delimiter. */ if (state == NULL) state = makeStringAggState(fcinfo); else if (!PG_ARGISNULL(2)) { bytea *delim = PG_GETARG_BYTEA_PP(2); appendBinaryStringInfo(state, VARDATA_ANY(delim), VARSIZE_ANY_EXHDR(delim)); } appendBinaryStringInfo(state, VARDATA_ANY(value), VARSIZE_ANY_EXHDR(value)); } /* * The transition type for string_agg() is declared to be "internal", * which is a pass-by-value type the same size as a pointer. */ PG_RETURN_POINTER(state); } Datum bytea_string_agg_finalfn(PG_FUNCTION_ARGS) { StringInfo state; /* cannot be called directly because of internal-type argument */ Assert(AggCheckCallContext(fcinfo, NULL)); state = PG_ARGISNULL(0) ? NULL : (StringInfo) PG_GETARG_POINTER(0); if (state != NULL) { bytea *result; result = (bytea *) palloc(state->len + VARHDRSZ); SET_VARSIZE(result, state->len + VARHDRSZ); memcpy(VARDATA(result), state->data, state->len); PG_RETURN_BYTEA_P(result); } else PG_RETURN_NULL(); } /* * textin - converts "..." to internal representation */ Datum textin(PG_FUNCTION_ARGS) { char *inputText = PG_GETARG_CSTRING(0); PG_RETURN_TEXT_P(cstring_to_text(inputText)); } /* * textout - converts internal representation to "..." */ Datum textout(PG_FUNCTION_ARGS) { Datum txt = PG_GETARG_DATUM(0); PG_RETURN_CSTRING(TextDatumGetCString(txt)); } /* * textrecv - converts external binary format to text */ Datum textrecv(PG_FUNCTION_ARGS) { StringInfo buf = (StringInfo) PG_GETARG_POINTER(0); text *result; char *str; int nbytes; str = pq_getmsgtext(buf, buf->len - buf->cursor, &nbytes); result = cstring_to_text_with_len(str, nbytes); pfree(str); PG_RETURN_TEXT_P(result); } /* * textsend - converts text to binary format */ Datum textsend(PG_FUNCTION_ARGS) { text *t = PG_GETARG_TEXT_PP(0); StringInfoData buf; pq_begintypsend(&buf); pq_sendtext(&buf, VARDATA_ANY(t), VARSIZE_ANY_EXHDR(t)); PG_RETURN_BYTEA_P(pq_endtypsend(&buf)); } /* * unknownin - converts "..." to internal representation */ Datum unknownin(PG_FUNCTION_ARGS) { char *str = PG_GETARG_CSTRING(0); /* representation is same as cstring */ PG_RETURN_CSTRING(pstrdup(str)); } /* * unknownout - converts internal representation to "..." */ Datum unknownout(PG_FUNCTION_ARGS) { /* representation is same as cstring */ char *str = PG_GETARG_CSTRING(0); PG_RETURN_CSTRING(pstrdup(str)); } /* * unknownrecv - converts external binary format to unknown */ Datum unknownrecv(PG_FUNCTION_ARGS) { StringInfo buf = (StringInfo) PG_GETARG_POINTER(0); char *str; int nbytes; str = pq_getmsgtext(buf, buf->len - buf->cursor, &nbytes); /* representation is same as cstring */ PG_RETURN_CSTRING(str); } /* * unknownsend - converts unknown to binary format */ Datum unknownsend(PG_FUNCTION_ARGS) { /* representation is same as cstring */ char *str = PG_GETARG_CSTRING(0); StringInfoData buf; pq_begintypsend(&buf); pq_sendtext(&buf, str, strlen(str)); PG_RETURN_BYTEA_P(pq_endtypsend(&buf)); } /* ========== PUBLIC ROUTINES ========== */ /* * textlen - * returns the logical length of a text* * (which is less than the VARSIZE of the text*) */ Datum textlen(PG_FUNCTION_ARGS) { Datum str = PG_GETARG_DATUM(0); /* try to avoid decompressing argument */ PG_RETURN_INT32(text_length(str)); } /* * text_length - * Does the real work for textlen() * * This is broken out so it can be called directly by other string processing * functions. Note that the argument is passed as a Datum, to indicate that * it may still be in compressed form. We can avoid decompressing it at all * in some cases. */ static int32 text_length(Datum str) { /* fastpath when max encoding length is one */ if (pg_database_encoding_max_length() == 1) PG_RETURN_INT32(toast_raw_datum_size(str) - VARHDRSZ); else { text *t = DatumGetTextPP(str); PG_RETURN_INT32(pg_mbstrlen_with_len(VARDATA_ANY(t), VARSIZE_ANY_EXHDR(t))); } } /* * textoctetlen - * returns the physical length of a text* * (which is less than the VARSIZE of the text*) */ Datum textoctetlen(PG_FUNCTION_ARGS) { Datum str = PG_GETARG_DATUM(0); /* We need not detoast the input at all */ PG_RETURN_INT32(toast_raw_datum_size(str) - VARHDRSZ); } /* * textcat - * takes two text* and returns a text* that is the concatenation of * the two. * * Rewritten by Sapa, sapa@hq.icb.chel.su. 8-Jul-96. * Updated by Thomas, Thomas.Lockhart@jpl.nasa.gov 1997-07-10. * Allocate space for output in all cases. * XXX - thomas 1997-07-10 */ Datum textcat(PG_FUNCTION_ARGS) { text *t1 = PG_GETARG_TEXT_PP(0); text *t2 = PG_GETARG_TEXT_PP(1); PG_RETURN_TEXT_P(text_catenate(t1, t2)); } /* * text_catenate * Guts of textcat(), broken out so it can be used by other functions * * Arguments can be in short-header form, but not compressed or out-of-line */ static text * text_catenate(text *t1, text *t2) { text *result; int len1, len2, len; char *ptr; len1 = VARSIZE_ANY_EXHDR(t1); len2 = VARSIZE_ANY_EXHDR(t2); /* paranoia ... probably should throw error instead? */ if (len1 < 0) len1 = 0; if (len2 < 0) len2 = 0; len = len1 + len2 + VARHDRSZ; result = (text *) palloc(len); /* Set size of result string... */ SET_VARSIZE(result, len); /* Fill data field of result string... */ ptr = VARDATA(result); if (len1 > 0) memcpy(ptr, VARDATA_ANY(t1), len1); if (len2 > 0) memcpy(ptr + len1, VARDATA_ANY(t2), len2); return result; } /* * charlen_to_bytelen() * Compute the number of bytes occupied by n characters starting at *p * * It is caller's responsibility that there actually are n characters; * the string need not be null-terminated. */ static int charlen_to_bytelen(const char *p, int n) { if (pg_database_encoding_max_length() == 1) { /* Optimization for single-byte encodings */ return n; } else { const char *s; for (s = p; n > 0; n--) s += pg_mblen(s); return s - p; } } /* * text_substr() * Return a substring starting at the specified position. * - thomas 1997-12-31 * * Input: * - string * - starting position (is one-based) * - string length * * If the starting position is zero or less, then return from the start of the string * adjusting the length to be consistent with the "negative start" per SQL. * If the length is less than zero, return the remaining string. * * Added multibyte support. * - Tatsuo Ishii 1998-4-21 * Changed behavior if starting position is less than one to conform to SQL behavior. * Formerly returned the entire string; now returns a portion. * - Thomas Lockhart 1998-12-10 * Now uses faster TOAST-slicing interface * - John Gray 2002-02-22 * Remove "#ifdef MULTIBYTE" and test for encoding_max_length instead. Change * behaviors conflicting with SQL to meet SQL (if E = S + L < S throw * error; if E < 1, return '', not entire string). Fixed MB related bug when * S > LC and < LC + 4 sometimes garbage characters are returned. * - Joe Conway 2002-08-10 */ Datum text_substr(PG_FUNCTION_ARGS) { PG_RETURN_TEXT_P(text_substring(PG_GETARG_DATUM(0), PG_GETARG_INT32(1), PG_GETARG_INT32(2), false)); } /* * text_substr_no_len - * Wrapper to avoid opr_sanity failure due to * one function accepting a different number of args. */ Datum text_substr_no_len(PG_FUNCTION_ARGS) { PG_RETURN_TEXT_P(text_substring(PG_GETARG_DATUM(0), PG_GETARG_INT32(1), -1, true)); } /* * text_substring - * Does the real work for text_substr() and text_substr_no_len() * * This is broken out so it can be called directly by other string processing * functions. Note that the argument is passed as a Datum, to indicate that * it may still be in compressed/toasted form. We can avoid detoasting all * of it in some cases. * * The result is always a freshly palloc'd datum. */ static text * text_substring(Datum str, int32 start, int32 length, bool length_not_specified) { int32 eml = pg_database_encoding_max_length(); int32 S = start; /* start position */ int32 S1; /* adjusted start position */ int32 L1; /* adjusted substring length */ int32 E; /* end position */ /* * SQL99 says S can be zero or negative, but we still must fetch from the * start of the string. */ S1 = Max(S, 1); /* life is easy if the encoding max length is 1 */ if (eml == 1) { if (length_not_specified) /* special case - get length to end of * string */ L1 = -1; else if (length < 0) { /* SQL99 says to throw an error for E < S, i.e., negative length */ ereport(ERROR, (errcode(ERRCODE_SUBSTRING_ERROR), errmsg("negative substring length not allowed"))); L1 = -1; /* silence stupider compilers */ } else if (pg_add_s32_overflow(S, length, &E)) { /* * L could be large enough for S + L to overflow, in which case * the substring must run to end of string. */ L1 = -1; } else { /* * A zero or negative value for the end position can happen if the * start was negative or one. SQL99 says to return a zero-length * string. */ if (E < 1) return cstring_to_text(""); L1 = E - S1; } /* * If the start position is past the end of the string, SQL99 says to * return a zero-length string -- DatumGetTextPSlice() will do that * for us. We need only convert S1 to zero-based starting position. */ return DatumGetTextPSlice(str, S1 - 1, L1); } else if (eml > 1) { /* * When encoding max length is > 1, we can't get LC without * detoasting, so we'll grab a conservatively large slice now and go * back later to do the right thing */ int32 slice_start; int32 slice_size; int32 slice_strlen; text *slice; int32 E1; int32 i; char *p; char *s; text *ret; /* * We need to start at position zero because there is no way to know * in advance which byte offset corresponds to the supplied start * position. */ slice_start = 0; if (length_not_specified) /* special case - get length to end of * string */ slice_size = L1 = -1; else if (length < 0) { /* SQL99 says to throw an error for E < S, i.e., negative length */ ereport(ERROR, (errcode(ERRCODE_SUBSTRING_ERROR), errmsg("negative substring length not allowed"))); slice_size = L1 = -1; /* silence stupider compilers */ } else if (pg_add_s32_overflow(S, length, &E)) { /* * L could be large enough for S + L to overflow, in which case * the substring must run to end of string. */ slice_size = L1 = -1; } else { /* * A zero or negative value for the end position can happen if the * start was negative or one. SQL99 says to return a zero-length * string. */ if (E < 1) return cstring_to_text(""); /* * if E is past the end of the string, the tuple toaster will * truncate the length for us */ L1 = E - S1; /* * Total slice size in bytes can't be any longer than the start * position plus substring length times the encoding max length. * If that overflows, we can just use -1. */ if (pg_mul_s32_overflow(E, eml, &slice_size)) slice_size = -1; } /* * If we're working with an untoasted source, no need to do an extra * copying step. */ if (VARATT_IS_COMPRESSED(DatumGetPointer(str)) || VARATT_IS_EXTERNAL(DatumGetPointer(str))) slice = DatumGetTextPSlice(str, slice_start, slice_size); else slice = (text *) DatumGetPointer(str); /* see if we got back an empty string */ if (VARSIZE_ANY_EXHDR(slice) == 0) { if (slice != (text *) DatumGetPointer(str)) pfree(slice); return cstring_to_text(""); } /* Now we can get the actual length of the slice in MB characters */ slice_strlen = pg_mbstrlen_with_len(VARDATA_ANY(slice), VARSIZE_ANY_EXHDR(slice)); /* * Check that the start position wasn't > slice_strlen. If so, SQL99 * says to return a zero-length string. */ if (S1 > slice_strlen) { if (slice != (text *) DatumGetPointer(str)) pfree(slice); return cstring_to_text(""); } /* * Adjust L1 and E1 now that we know the slice string length. Again * remember that S1 is one based, and slice_start is zero based. */ if (L1 > -1) E1 = Min(S1 + L1, slice_start + 1 + slice_strlen); else E1 = slice_start + 1 + slice_strlen; /* * Find the start position in the slice; remember S1 is not zero based */ p = VARDATA_ANY(slice); for (i = 0; i < S1 - 1; i++) p += pg_mblen(p); /* hang onto a pointer to our start position */ s = p; /* * Count the actual bytes used by the substring of the requested * length. */ for (i = S1; i < E1; i++) p += pg_mblen(p); ret = (text *) palloc(VARHDRSZ + (p - s)); SET_VARSIZE(ret, VARHDRSZ + (p - s)); memcpy(VARDATA(ret), s, (p - s)); if (slice != (text *) DatumGetPointer(str)) pfree(slice); return ret; } else elog(ERROR, "invalid backend encoding: encoding max length < 1"); /* not reached: suppress compiler warning */ return NULL; } /* * textoverlay * Replace specified substring of first string with second * * The SQL standard defines OVERLAY() in terms of substring and concatenation. * This code is a direct implementation of what the standard says. */ Datum textoverlay(PG_FUNCTION_ARGS) { text *t1 = PG_GETARG_TEXT_PP(0); text *t2 = PG_GETARG_TEXT_PP(1); int sp = PG_GETARG_INT32(2); /* substring start position */ int sl = PG_GETARG_INT32(3); /* substring length */ PG_RETURN_TEXT_P(text_overlay(t1, t2, sp, sl)); } Datum textoverlay_no_len(PG_FUNCTION_ARGS) { text *t1 = PG_GETARG_TEXT_PP(0); text *t2 = PG_GETARG_TEXT_PP(1); int sp = PG_GETARG_INT32(2); /* substring start position */ int sl; sl = text_length(PointerGetDatum(t2)); /* defaults to length(t2) */ PG_RETURN_TEXT_P(text_overlay(t1, t2, sp, sl)); } static text * text_overlay(text *t1, text *t2, int sp, int sl) { text *result; text *s1; text *s2; int sp_pl_sl; /* * Check for possible integer-overflow cases. For negative sp, throw a * "substring length" error because that's what should be expected * according to the spec's definition of OVERLAY(). */ if (sp <= 0) ereport(ERROR, (errcode(ERRCODE_SUBSTRING_ERROR), errmsg("negative substring length not allowed"))); if (pg_add_s32_overflow(sp, sl, &sp_pl_sl)) ereport(ERROR, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("integer out of range"))); s1 = text_substring(PointerGetDatum(t1), 1, sp - 1, false); s2 = text_substring(PointerGetDatum(t1), sp_pl_sl, -1, true); result = text_catenate(s1, t2); result = text_catenate(result, s2); return result; } /* * textpos - * Return the position of the specified substring. * Implements the SQL POSITION() function. * Ref: A Guide To The SQL Standard, Date & Darwen, 1997 * - thomas 1997-07-27 */ Datum textpos(PG_FUNCTION_ARGS) { text *str = PG_GETARG_TEXT_PP(0); text *search_str = PG_GETARG_TEXT_PP(1); PG_RETURN_INT32((int32) text_position(str, search_str, PG_GET_COLLATION())); } /* * text_position - * Does the real work for textpos() * * Inputs: * t1 - string to be searched * t2 - pattern to match within t1 * Result: * Character index of the first matched char, starting from 1, * or 0 if no match. * * This is broken out so it can be called directly by other string processing * functions. */ static int text_position(text *t1, text *t2, Oid collid) { TextPositionState state; int result; /* Empty needle always matches at position 1 */ if (VARSIZE_ANY_EXHDR(t2) < 1) return 1; /* Otherwise, can't match if haystack is shorter than needle */ if (VARSIZE_ANY_EXHDR(t1) < VARSIZE_ANY_EXHDR(t2)) return 0; text_position_setup(t1, t2, collid, &state); if (!text_position_next(&state)) result = 0; else result = text_position_get_match_pos(&state); text_position_cleanup(&state); return result; } /* * text_position_setup, text_position_next, text_position_cleanup - * Component steps of text_position() * * These are broken out so that a string can be efficiently searched for * multiple occurrences of the same pattern. text_position_next may be * called multiple times, and it advances to the next match on each call. * text_position_get_match_ptr() and text_position_get_match_pos() return * a pointer or 1-based character position of the last match, respectively. * * The "state" variable is normally just a local variable in the caller. * * NOTE: text_position_next skips over the matched portion. For example, * searching for "xx" in "xxx" returns only one match, not two. */ static void text_position_setup(text *t1, text *t2, Oid collid, TextPositionState *state) { int len1 = VARSIZE_ANY_EXHDR(t1); int len2 = VARSIZE_ANY_EXHDR(t2); pg_locale_t mylocale = 0; check_collation_set(collid); if (!lc_collate_is_c(collid) && collid != DEFAULT_COLLATION_OID) mylocale = pg_newlocale_from_collation(collid); if (mylocale && !mylocale->deterministic) ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), errmsg("nondeterministic collations are not supported for substring searches"))); Assert(len1 > 0); Assert(len2 > 0); /* * Even with a multi-byte encoding, we perform the search using the raw * byte sequence, ignoring multibyte issues. For UTF-8, that works fine, * because in UTF-8 the byte sequence of one character cannot contain * another character. For other multi-byte encodings, we do the search * initially as a simple byte search, ignoring multibyte issues, but * verify afterwards that the match we found is at a character boundary, * and continue the search if it was a false match. */ if (pg_database_encoding_max_length() == 1) { state->is_multibyte = false; state->is_multibyte_char_in_char = false; } else if (GetDatabaseEncoding() == PG_UTF8) { state->is_multibyte = true; state->is_multibyte_char_in_char = false; } else { state->is_multibyte = true; state->is_multibyte_char_in_char = true; } state->str1 = VARDATA_ANY(t1); state->str2 = VARDATA_ANY(t2); state->len1 = len1; state->len2 = len2; state->last_match = NULL; state->refpoint = state->str1; state->refpos = 0; /* * Prepare the skip table for Boyer-Moore-Horspool searching. In these * notes we use the terminology that the "haystack" is the string to be * searched (t1) and the "needle" is the pattern being sought (t2). * * If the needle is empty or bigger than the haystack then there is no * point in wasting cycles initializing the table. We also choose not to * use B-M-H for needles of length 1, since the skip table can't possibly * save anything in that case. */ if (len1 >= len2 && len2 > 1) { int searchlength = len1 - len2; int skiptablemask; int last; int i; const char *str2 = state->str2; /* * First we must determine how much of the skip table to use. The * declaration of TextPositionState allows up to 256 elements, but for * short search problems we don't really want to have to initialize so * many elements --- it would take too long in comparison to the * actual search time. So we choose a useful skip table size based on * the haystack length minus the needle length. The closer the needle * length is to the haystack length the less useful skipping becomes. * * Note: since we use bit-masking to select table elements, the skip * table size MUST be a power of 2, and so the mask must be 2^N-1. */ if (searchlength < 16) skiptablemask = 3; else if (searchlength < 64) skiptablemask = 7; else if (searchlength < 128) skiptablemask = 15; else if (searchlength < 512) skiptablemask = 31; else if (searchlength < 2048) skiptablemask = 63; else if (searchlength < 4096) skiptablemask = 127; else skiptablemask = 255; state->skiptablemask = skiptablemask; /* * Initialize the skip table. We set all elements to the needle * length, since this is the correct skip distance for any character * not found in the needle. */ for (i = 0; i <= skiptablemask; i++) state->skiptable[i] = len2; /* * Now examine the needle. For each character except the last one, * set the corresponding table element to the appropriate skip * distance. Note that when two characters share the same skip table * entry, the one later in the needle must determine the skip * distance. */ last = len2 - 1; for (i = 0; i < last; i++) state->skiptable[(unsigned char) str2[i] & skiptablemask] = last - i; } } /* * Advance to the next match, starting from the end of the previous match * (or the beginning of the string, on first call). Returns true if a match * is found. * * Note that this refuses to match an empty-string needle. Most callers * will have handled that case specially and we'll never see it here. */ static bool text_position_next(TextPositionState *state) { int needle_len = state->len2; char *start_ptr; char *matchptr; if (needle_len <= 0) return false; /* result for empty pattern */ /* Start from the point right after the previous match. */ if (state->last_match) start_ptr = state->last_match + needle_len; else start_ptr = state->str1; retry: matchptr = text_position_next_internal(start_ptr, state); if (!matchptr) return false; /* * Found a match for the byte sequence. If this is a multibyte encoding, * where one character's byte sequence can appear inside a longer * multi-byte character, we need to verify that the match was at a * character boundary, not in the middle of a multi-byte character. */ if (state->is_multibyte_char_in_char) { /* Walk one character at a time, until we reach the match. */ /* the search should never move backwards. */ Assert(state->refpoint <= matchptr); while (state->refpoint < matchptr) { /* step to next character. */ state->refpoint += pg_mblen(state->refpoint); state->refpos++; /* * If we stepped over the match's start position, then it was a * false positive, where the byte sequence appeared in the middle * of a multi-byte character. Skip it, and continue the search at * the next character boundary. */ if (state->refpoint > matchptr) { start_ptr = state->refpoint; goto retry; } } } state->last_match = matchptr; return true; } /* * Subroutine of text_position_next(). This searches for the raw byte * sequence, ignoring any multi-byte encoding issues. Returns the first * match starting at 'start_ptr', or NULL if no match is found. */ static char * text_position_next_internal(char *start_ptr, TextPositionState *state) { int haystack_len = state->len1; int needle_len = state->len2; int skiptablemask = state->skiptablemask; const char *haystack = state->str1; const char *needle = state->str2; const char *haystack_end = &haystack[haystack_len]; const char *hptr; Assert(start_ptr >= haystack && start_ptr <= haystack_end); if (needle_len == 1) { /* No point in using B-M-H for a one-character needle */ char nchar = *needle; hptr = start_ptr; while (hptr < haystack_end) { if (*hptr == nchar) return (char *) hptr; hptr++; } } else { const char *needle_last = &needle[needle_len - 1]; /* Start at startpos plus the length of the needle */ hptr = start_ptr + needle_len - 1; while (hptr < haystack_end) { /* Match the needle scanning *backward* */ const char *nptr; const char *p; nptr = needle_last; p = hptr; while (*nptr == *p) { /* Matched it all? If so, return 1-based position */ if (nptr == needle) return (char *) p; nptr--, p--; } /* * No match, so use the haystack char at hptr to decide how far to * advance. If the needle had any occurrence of that character * (or more precisely, one sharing the same skiptable entry) * before its last character, then we advance far enough to align * the last such needle character with that haystack position. * Otherwise we can advance by the whole needle length. */ hptr += state->skiptable[(unsigned char) *hptr & skiptablemask]; } } return 0; /* not found */ } /* * Return a pointer to the current match. * * The returned pointer points into the original haystack string. */ static char * text_position_get_match_ptr(TextPositionState *state) { return state->last_match; } /* * Return the offset of the current match. * * The offset is in characters, 1-based. */ static int text_position_get_match_pos(TextPositionState *state) { if (!state->is_multibyte) return state->last_match - state->str1 + 1; else { /* Convert the byte position to char position. */ while (state->refpoint < state->last_match) { state->refpoint += pg_mblen(state->refpoint); state->refpos++; } Assert(state->refpoint == state->last_match); return state->refpos + 1; } } /* * Reset search state to the initial state installed by text_position_setup. * * The next call to text_position_next will search from the beginning * of the string. */ static void text_position_reset(TextPositionState *state) { state->last_match = NULL; state->refpoint = state->str1; state->refpos = 0; } static void text_position_cleanup(TextPositionState *state) { /* no cleanup needed */ } static void check_collation_set(Oid collid) { if (!OidIsValid(collid)) { /* * This typically means that the parser could not resolve a conflict * of implicit collations, so report it that way. */ ereport(ERROR, (errcode(ERRCODE_INDETERMINATE_COLLATION), errmsg("could not determine which collation to use for string comparison"), errhint("Use the COLLATE clause to set the collation explicitly."))); } } /* varstr_cmp() * Comparison function for text strings with given lengths. * Includes locale support, but must copy strings to temporary memory * to allow null-termination for inputs to strcoll(). * Returns an integer less than, equal to, or greater than zero, indicating * whether arg1 is less than, equal to, or greater than arg2. * * Note: many functions that depend on this are marked leakproof; therefore, * avoid reporting the actual contents of the input when throwing errors. * All errors herein should be things that can't happen except on corrupt * data, anyway; otherwise we will have trouble with indexing strings that * would cause them. */ int varstr_cmp(const char *arg1, int len1, const char *arg2, int len2, Oid collid) { int result; check_collation_set(collid); /* * Unfortunately, there is no strncoll(), so in the non-C locale case we * have to do some memory copying. This turns out to be significantly * slower, so we optimize the case where LC_COLLATE is C. We also try to * optimize relatively-short strings by avoiding palloc/pfree overhead. */ if (lc_collate_is_c(collid)) { result = memcmp(arg1, arg2, Min(len1, len2)); if ((result == 0) && (len1 != len2)) result = (len1 < len2) ? -1 : 1; } else { char a1buf[TEXTBUFLEN]; char a2buf[TEXTBUFLEN]; char *a1p, *a2p; pg_locale_t mylocale = 0; if (collid != DEFAULT_COLLATION_OID) mylocale = pg_newlocale_from_collation(collid); /* * memcmp() can't tell us which of two unequal strings sorts first, * but it's a cheap way to tell if they're equal. Testing shows that * memcmp() followed by strcoll() is only trivially slower than * strcoll() by itself, so we don't lose much if this doesn't work out * very often, and if it does - for example, because there are many * equal strings in the input - then we win big by avoiding expensive * collation-aware comparisons. */ if (len1 == len2 && memcmp(arg1, arg2, len1) == 0) return 0; #ifdef WIN32 /* Win32 does not have UTF-8, so we need to map to UTF-16 */ if (GetDatabaseEncoding() == PG_UTF8 && (!mylocale || mylocale->provider == COLLPROVIDER_LIBC)) { int a1len; int a2len; int r; if (len1 >= TEXTBUFLEN / 2) { a1len = len1 * 2 + 2; a1p = palloc(a1len); } else { a1len = TEXTBUFLEN; a1p = a1buf; } if (len2 >= TEXTBUFLEN / 2) { a2len = len2 * 2 + 2; a2p = palloc(a2len); } else { a2len = TEXTBUFLEN; a2p = a2buf; } /* stupid Microsloth API does not work for zero-length input */ if (len1 == 0) r = 0; else { r = MultiByteToWideChar(CP_UTF8, 0, arg1, len1, (LPWSTR) a1p, a1len / 2); if (!r) ereport(ERROR, (errmsg("could not convert string to UTF-16: error code %lu", GetLastError()))); } ((LPWSTR) a1p)[r] = 0; if (len2 == 0) r = 0; else { r = MultiByteToWideChar(CP_UTF8, 0, arg2, len2, (LPWSTR) a2p, a2len / 2); if (!r) ereport(ERROR, (errmsg("could not convert string to UTF-16: error code %lu", GetLastError()))); } ((LPWSTR) a2p)[r] = 0; errno = 0; #ifdef HAVE_LOCALE_T if (mylocale) result = wcscoll_l((LPWSTR) a1p, (LPWSTR) a2p, mylocale->info.lt); else #endif result = wcscoll((LPWSTR) a1p, (LPWSTR) a2p); if (result == 2147483647) /* _NLSCMPERROR; missing from mingw * headers */ ereport(ERROR, (errmsg("could not compare Unicode strings: %m"))); /* Break tie if necessary. */ if (result == 0 && (!mylocale || mylocale->deterministic)) { result = memcmp(arg1, arg2, Min(len1, len2)); if ((result == 0) && (len1 != len2)) result = (len1 < len2) ? -1 : 1; } if (a1p != a1buf) pfree(a1p); if (a2p != a2buf) pfree(a2p); return result; } #endif /* WIN32 */ if (len1 >= TEXTBUFLEN) a1p = (char *) palloc(len1 + 1); else a1p = a1buf; if (len2 >= TEXTBUFLEN) a2p = (char *) palloc(len2 + 1); else a2p = a2buf; memcpy(a1p, arg1, len1); a1p[len1] = '\0'; memcpy(a2p, arg2, len2); a2p[len2] = '\0'; if (mylocale) { if (mylocale->provider == COLLPROVIDER_ICU) { #ifdef USE_ICU #ifdef HAVE_UCOL_STRCOLLUTF8 if (GetDatabaseEncoding() == PG_UTF8) { UErrorCode status; status = U_ZERO_ERROR; result = ucol_strcollUTF8(mylocale->info.icu.ucol, arg1, len1, arg2, len2, &status); if (U_FAILURE(status)) ereport(ERROR, (errmsg("collation failed: %s", u_errorName(status)))); } else #endif { int32_t ulen1, ulen2; UChar *uchar1, *uchar2; ulen1 = icu_to_uchar(&uchar1, arg1, len1); ulen2 = icu_to_uchar(&uchar2, arg2, len2); result = ucol_strcoll(mylocale->info.icu.ucol, uchar1, ulen1, uchar2, ulen2); pfree(uchar1); pfree(uchar2); } #else /* not USE_ICU */ /* shouldn't happen */ elog(ERROR, "unsupported collprovider: %c", mylocale->provider); #endif /* not USE_ICU */ } else { #ifdef HAVE_LOCALE_T result = strcoll_l(a1p, a2p, mylocale->info.lt); #else /* shouldn't happen */ elog(ERROR, "unsupported collprovider: %c", mylocale->provider); #endif } } else result = strcoll(a1p, a2p); /* Break tie if necessary. */ if (result == 0 && (!mylocale || mylocale->deterministic)) result = strcmp(a1p, a2p); if (a1p != a1buf) pfree(a1p); if (a2p != a2buf) pfree(a2p); } return result; } /* text_cmp() * Internal comparison function for text strings. * Returns -1, 0 or 1 */ static int text_cmp(text *arg1, text *arg2, Oid collid) { char *a1p, *a2p; int len1, len2; a1p = VARDATA_ANY(arg1); a2p = VARDATA_ANY(arg2); len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); return varstr_cmp(a1p, len1, a2p, len2, collid); } /* * Comparison functions for text strings. * * Note: btree indexes need these routines not to leak memory; therefore, * be careful to free working copies of toasted datums. Most places don't * need to be so careful. */ Datum texteq(PG_FUNCTION_ARGS) { Oid collid = PG_GET_COLLATION(); bool result; check_collation_set(collid); if (lc_collate_is_c(collid) || collid == DEFAULT_COLLATION_OID || pg_newlocale_from_collation(collid)->deterministic) { Datum arg1 = PG_GETARG_DATUM(0); Datum arg2 = PG_GETARG_DATUM(1); Size len1, len2; /* * Since we only care about equality or not-equality, we can avoid all * the expense of strcoll() here, and just do bitwise comparison. In * fact, we don't even have to do a bitwise comparison if we can show * the lengths of the strings are unequal; which might save us from * having to detoast one or both values. */ len1 = toast_raw_datum_size(arg1); len2 = toast_raw_datum_size(arg2); if (len1 != len2) result = false; else { text *targ1 = DatumGetTextPP(arg1); text *targ2 = DatumGetTextPP(arg2); result = (memcmp(VARDATA_ANY(targ1), VARDATA_ANY(targ2), len1 - VARHDRSZ) == 0); PG_FREE_IF_COPY(targ1, 0); PG_FREE_IF_COPY(targ2, 1); } } else { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); result = (text_cmp(arg1, arg2, collid) == 0); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); } PG_RETURN_BOOL(result); } Datum textne(PG_FUNCTION_ARGS) { Oid collid = PG_GET_COLLATION(); bool result; check_collation_set(collid); if (lc_collate_is_c(collid) || collid == DEFAULT_COLLATION_OID || pg_newlocale_from_collation(collid)->deterministic) { Datum arg1 = PG_GETARG_DATUM(0); Datum arg2 = PG_GETARG_DATUM(1); Size len1, len2; /* See comment in texteq() */ len1 = toast_raw_datum_size(arg1); len2 = toast_raw_datum_size(arg2); if (len1 != len2) result = true; else { text *targ1 = DatumGetTextPP(arg1); text *targ2 = DatumGetTextPP(arg2); result = (memcmp(VARDATA_ANY(targ1), VARDATA_ANY(targ2), len1 - VARHDRSZ) != 0); PG_FREE_IF_COPY(targ1, 0); PG_FREE_IF_COPY(targ2, 1); } } else { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); result = (text_cmp(arg1, arg2, collid) != 0); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); } PG_RETURN_BOOL(result); } Datum text_lt(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); bool result; result = (text_cmp(arg1, arg2, PG_GET_COLLATION()) < 0); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result); } Datum text_le(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); bool result; result = (text_cmp(arg1, arg2, PG_GET_COLLATION()) <= 0); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result); } Datum text_gt(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); bool result; result = (text_cmp(arg1, arg2, PG_GET_COLLATION()) > 0); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result); } Datum text_ge(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); bool result; result = (text_cmp(arg1, arg2, PG_GET_COLLATION()) >= 0); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result); } Datum text_starts_with(PG_FUNCTION_ARGS) { Datum arg1 = PG_GETARG_DATUM(0); Datum arg2 = PG_GETARG_DATUM(1); Oid collid = PG_GET_COLLATION(); pg_locale_t mylocale = 0; bool result; Size len1, len2; check_collation_set(collid); if (!lc_collate_is_c(collid) && collid != DEFAULT_COLLATION_OID) mylocale = pg_newlocale_from_collation(collid); if (mylocale && !mylocale->deterministic) ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), errmsg("nondeterministic collations are not supported for substring searches"))); len1 = toast_raw_datum_size(arg1); len2 = toast_raw_datum_size(arg2); if (len2 > len1) result = false; else { text *targ1 = text_substring(arg1, 1, len2, false); text *targ2 = DatumGetTextPP(arg2); result = (memcmp(VARDATA_ANY(targ1), VARDATA_ANY(targ2), VARSIZE_ANY_EXHDR(targ2)) == 0); PG_FREE_IF_COPY(targ1, 0); PG_FREE_IF_COPY(targ2, 1); } PG_RETURN_BOOL(result); } Datum bttextcmp(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); int32 result; result = text_cmp(arg1, arg2, PG_GET_COLLATION()); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_INT32(result); } Datum bttextsortsupport(PG_FUNCTION_ARGS) { SortSupport ssup = (SortSupport) PG_GETARG_POINTER(0); Oid collid = ssup->ssup_collation; MemoryContext oldcontext; oldcontext = MemoryContextSwitchTo(ssup->ssup_cxt); /* Use generic string SortSupport */ varstr_sortsupport(ssup, TEXTOID, collid); MemoryContextSwitchTo(oldcontext); PG_RETURN_VOID(); } /* * Generic sortsupport interface for character type's operator classes. * Includes locale support, and support for BpChar semantics (i.e. removing * trailing spaces before comparison). * * Relies on the assumption that text, VarChar, BpChar, and bytea all have the * same representation. Callers that always use the C collation (e.g. * non-collatable type callers like bytea) may have NUL bytes in their strings; * this will not work with any other collation, though. */ void varstr_sortsupport(SortSupport ssup, Oid typid, Oid collid) { bool abbreviate = ssup->abbreviate; bool collate_c = false; VarStringSortSupport *sss; pg_locale_t locale = 0; check_collation_set(collid); /* * If possible, set ssup->comparator to a function which can be used to * directly compare two datums. If we can do this, we'll avoid the * overhead of a trip through the fmgr layer for every comparison, which * can be substantial. * * Most typically, we'll set the comparator to varlenafastcmp_locale, * which uses strcoll() to perform comparisons. We use that for the * BpChar case too, but type NAME uses namefastcmp_locale. However, if * LC_COLLATE = C, we can make things quite a bit faster with * varstrfastcmp_c, bpcharfastcmp_c, or namefastcmp_c, all of which use * memcmp() rather than strcoll(). */ if (lc_collate_is_c(collid)) { if (typid == BPCHAROID) ssup->comparator = bpcharfastcmp_c; else if (typid == NAMEOID) { ssup->comparator = namefastcmp_c; /* Not supporting abbreviation with type NAME, for now */ abbreviate = false; } else ssup->comparator = varstrfastcmp_c; collate_c = true; } else { /* * We need a collation-sensitive comparison. To make things faster, * we'll figure out the collation based on the locale id and cache the * result. */ if (collid != DEFAULT_COLLATION_OID) locale = pg_newlocale_from_collation(collid); /* * There is a further exception on Windows. When the database * encoding is UTF-8 and we are not using the C collation, complex * hacks are required. We don't currently have a comparator that * handles that case, so we fall back on the slow method of having the * sort code invoke bttextcmp() (in the case of text) via the fmgr * trampoline. ICU locales work just the same on Windows, however. */ #ifdef WIN32 if (GetDatabaseEncoding() == PG_UTF8 && !(locale && locale->provider == COLLPROVIDER_ICU)) return; #endif /* * We use varlenafastcmp_locale except for type NAME. */ if (typid == NAMEOID) { ssup->comparator = namefastcmp_locale; /* Not supporting abbreviation with type NAME, for now */ abbreviate = false; } else ssup->comparator = varlenafastcmp_locale; } /* * Unfortunately, it seems that abbreviation for non-C collations is * broken on many common platforms; testing of multiple versions of glibc * reveals that, for many locales, strcoll() and strxfrm() do not return * consistent results, which is fatal to this optimization. While no * other libc other than Cygwin has so far been shown to have a problem, * we take the conservative course of action for right now and disable * this categorically. (Users who are certain this isn't a problem on * their system can define TRUST_STRXFRM.) * * Even apart from the risk of broken locales, it's possible that there * are platforms where the use of abbreviated keys should be disabled at * compile time. Having only 4 byte datums could make worst-case * performance drastically more likely, for example. Moreover, macOS's * strxfrm() implementation is known to not effectively concentrate a * significant amount of entropy from the original string in earlier * transformed blobs. It's possible that other supported platforms are * similarly encumbered. So, if we ever get past disabling this * categorically, we may still want or need to disable it for particular * platforms. */ #ifndef TRUST_STRXFRM if (!collate_c && !(locale && locale->provider == COLLPROVIDER_ICU)) abbreviate = false; #endif /* * If we're using abbreviated keys, or if we're using a locale-aware * comparison, we need to initialize a VarStringSortSupport object. Both * cases will make use of the temporary buffers we initialize here for * scratch space (and to detect requirement for BpChar semantics from * caller), and the abbreviation case requires additional state. */ if (abbreviate || !collate_c) { sss = palloc(sizeof(VarStringSortSupport)); sss->buf1 = palloc(TEXTBUFLEN); sss->buflen1 = TEXTBUFLEN; sss->buf2 = palloc(TEXTBUFLEN); sss->buflen2 = TEXTBUFLEN; /* Start with invalid values */ sss->last_len1 = -1; sss->last_len2 = -1; /* Initialize */ sss->last_returned = 0; sss->locale = locale; /* * To avoid somehow confusing a strxfrm() blob and an original string, * constantly keep track of the variety of data that buf1 and buf2 * currently contain. * * Comparisons may be interleaved with conversion calls. Frequently, * conversions and comparisons are batched into two distinct phases, * but the correctness of caching cannot hinge upon this. For * comparison caching, buffer state is only trusted if cache_blob is * found set to false, whereas strxfrm() caching only trusts the state * when cache_blob is found set to true. * * Arbitrarily initialize cache_blob to true. */ sss->cache_blob = true; sss->collate_c = collate_c; sss->typid = typid; ssup->ssup_extra = sss; /* * If possible, plan to use the abbreviated keys optimization. The * core code may switch back to authoritative comparator should * abbreviation be aborted. */ if (abbreviate) { sss->prop_card = 0.20; initHyperLogLog(&sss->abbr_card, 10); initHyperLogLog(&sss->full_card, 10); ssup->abbrev_full_comparator = ssup->comparator; ssup->comparator = varstrcmp_abbrev; ssup->abbrev_converter = varstr_abbrev_convert; ssup->abbrev_abort = varstr_abbrev_abort; } } } /* * sortsupport comparison func (for C locale case) */ static int varstrfastcmp_c(Datum x, Datum y, SortSupport ssup) { VarString *arg1 = DatumGetVarStringPP(x); VarString *arg2 = DatumGetVarStringPP(y); char *a1p, *a2p; int len1, len2, result; a1p = VARDATA_ANY(arg1); a2p = VARDATA_ANY(arg2); len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); result = memcmp(a1p, a2p, Min(len1, len2)); if ((result == 0) && (len1 != len2)) result = (len1 < len2) ? -1 : 1; /* We can't afford to leak memory here. */ if (PointerGetDatum(arg1) != x) pfree(arg1); if (PointerGetDatum(arg2) != y) pfree(arg2); return result; } /* * sortsupport comparison func (for BpChar C locale case) * * BpChar outsources its sortsupport to this module. Specialization for the * varstr_sortsupport BpChar case, modeled on * internal_bpchar_pattern_compare(). */ static int bpcharfastcmp_c(Datum x, Datum y, SortSupport ssup) { BpChar *arg1 = DatumGetBpCharPP(x); BpChar *arg2 = DatumGetBpCharPP(y); char *a1p, *a2p; int len1, len2, result; a1p = VARDATA_ANY(arg1); a2p = VARDATA_ANY(arg2); len1 = bpchartruelen(a1p, VARSIZE_ANY_EXHDR(arg1)); len2 = bpchartruelen(a2p, VARSIZE_ANY_EXHDR(arg2)); result = memcmp(a1p, a2p, Min(len1, len2)); if ((result == 0) && (len1 != len2)) result = (len1 < len2) ? -1 : 1; /* We can't afford to leak memory here. */ if (PointerGetDatum(arg1) != x) pfree(arg1); if (PointerGetDatum(arg2) != y) pfree(arg2); return result; } /* * sortsupport comparison func (for NAME C locale case) */ static int namefastcmp_c(Datum x, Datum y, SortSupport ssup) { Name arg1 = DatumGetName(x); Name arg2 = DatumGetName(y); return strncmp(NameStr(*arg1), NameStr(*arg2), NAMEDATALEN); } /* * sortsupport comparison func (for locale case with all varlena types) */ static int varlenafastcmp_locale(Datum x, Datum y, SortSupport ssup) { VarString *arg1 = DatumGetVarStringPP(x); VarString *arg2 = DatumGetVarStringPP(y); char *a1p, *a2p; int len1, len2, result; a1p = VARDATA_ANY(arg1); a2p = VARDATA_ANY(arg2); len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); result = varstrfastcmp_locale(a1p, len1, a2p, len2, ssup); /* We can't afford to leak memory here. */ if (PointerGetDatum(arg1) != x) pfree(arg1); if (PointerGetDatum(arg2) != y) pfree(arg2); return result; } /* * sortsupport comparison func (for locale case with NAME type) */ static int namefastcmp_locale(Datum x, Datum y, SortSupport ssup) { Name arg1 = DatumGetName(x); Name arg2 = DatumGetName(y); return varstrfastcmp_locale(NameStr(*arg1), strlen(NameStr(*arg1)), NameStr(*arg2), strlen(NameStr(*arg2)), ssup); } /* * sortsupport comparison func for locale cases */ static int varstrfastcmp_locale(char *a1p, int len1, char *a2p, int len2, SortSupport ssup) { VarStringSortSupport *sss = (VarStringSortSupport *) ssup->ssup_extra; int result; bool arg1_match; /* Fast pre-check for equality, as discussed in varstr_cmp() */ if (len1 == len2 && memcmp(a1p, a2p, len1) == 0) { /* * No change in buf1 or buf2 contents, so avoid changing last_len1 or * last_len2. Existing contents of buffers might still be used by * next call. * * It's fine to allow the comparison of BpChar padding bytes here, * even though that implies that the memcmp() will usually be * performed for BpChar callers (though multibyte characters could * still prevent that from occurring). The memcmp() is still very * cheap, and BpChar's funny semantics have us remove trailing spaces * (not limited to padding), so we need make no distinction between * padding space characters and "real" space characters. */ return 0; } if (sss->typid == BPCHAROID) { /* Get true number of bytes, ignoring trailing spaces */ len1 = bpchartruelen(a1p, len1); len2 = bpchartruelen(a2p, len2); } if (len1 >= sss->buflen1) { pfree(sss->buf1); sss->buflen1 = Max(len1 + 1, Min(sss->buflen1 * 2, MaxAllocSize)); sss->buf1 = MemoryContextAlloc(ssup->ssup_cxt, sss->buflen1); } if (len2 >= sss->buflen2) { pfree(sss->buf2); sss->buflen2 = Max(len2 + 1, Min(sss->buflen2 * 2, MaxAllocSize)); sss->buf2 = MemoryContextAlloc(ssup->ssup_cxt, sss->buflen2); } /* * We're likely to be asked to compare the same strings repeatedly, and * memcmp() is so much cheaper than strcoll() that it pays to try to cache * comparisons, even though in general there is no reason to think that * that will work out (every string datum may be unique). Caching does * not slow things down measurably when it doesn't work out, and can speed * things up by rather a lot when it does. In part, this is because the * memcmp() compares data from cachelines that are needed in L1 cache even * when the last comparison's result cannot be reused. */ arg1_match = true; if (len1 != sss->last_len1 || memcmp(sss->buf1, a1p, len1) != 0) { arg1_match = false; memcpy(sss->buf1, a1p, len1); sss->buf1[len1] = '\0'; sss->last_len1 = len1; } /* * If we're comparing the same two strings as last time, we can return the * same answer without calling strcoll() again. This is more likely than * it seems (at least with moderate to low cardinality sets), because * quicksort compares the same pivot against many values. */ if (len2 != sss->last_len2 || memcmp(sss->buf2, a2p, len2) != 0) { memcpy(sss->buf2, a2p, len2); sss->buf2[len2] = '\0'; sss->last_len2 = len2; } else if (arg1_match && !sss->cache_blob) { /* Use result cached following last actual strcoll() call */ return sss->last_returned; } if (sss->locale) { if (sss->locale->provider == COLLPROVIDER_ICU) { #ifdef USE_ICU #ifdef HAVE_UCOL_STRCOLLUTF8 if (GetDatabaseEncoding() == PG_UTF8) { UErrorCode status; status = U_ZERO_ERROR; result = ucol_strcollUTF8(sss->locale->info.icu.ucol, a1p, len1, a2p, len2, &status); if (U_FAILURE(status)) ereport(ERROR, (errmsg("collation failed: %s", u_errorName(status)))); } else #endif { int32_t ulen1, ulen2; UChar *uchar1, *uchar2; ulen1 = icu_to_uchar(&uchar1, a1p, len1); ulen2 = icu_to_uchar(&uchar2, a2p, len2); result = ucol_strcoll(sss->locale->info.icu.ucol, uchar1, ulen1, uchar2, ulen2); pfree(uchar1); pfree(uchar2); } #else /* not USE_ICU */ /* shouldn't happen */ elog(ERROR, "unsupported collprovider: %c", sss->locale->provider); #endif /* not USE_ICU */ } else { #ifdef HAVE_LOCALE_T result = strcoll_l(sss->buf1, sss->buf2, sss->locale->info.lt); #else /* shouldn't happen */ elog(ERROR, "unsupported collprovider: %c", sss->locale->provider); #endif } } else result = strcoll(sss->buf1, sss->buf2); /* Break tie if necessary. */ if (result == 0 && (!sss->locale || sss->locale->deterministic)) result = strcmp(sss->buf1, sss->buf2); /* Cache result, perhaps saving an expensive strcoll() call next time */ sss->cache_blob = false; sss->last_returned = result; return result; } /* * Abbreviated key comparison func */ static int varstrcmp_abbrev(Datum x, Datum y, SortSupport ssup) { /* * When 0 is returned, the core system will call varstrfastcmp_c() * (bpcharfastcmp_c() in BpChar case) or varlenafastcmp_locale(). Even a * strcmp() on two non-truncated strxfrm() blobs cannot indicate *equality* * authoritatively, for the same reason that there is a strcoll() * tie-breaker call to strcmp() in varstr_cmp(). */ if (x > y) return 1; else if (x == y) return 0; else return -1; } /* * Conversion routine for sortsupport. Converts original to abbreviated key * representation. Our encoding strategy is simple -- pack the first 8 bytes * of a strxfrm() blob into a Datum (on little-endian machines, the 8 bytes are * stored in reverse order), and treat it as an unsigned integer. When the "C" * locale is used, or in case of bytea, just memcpy() from original instead. */ static Datum varstr_abbrev_convert(Datum original, SortSupport ssup) { VarStringSortSupport *sss = (VarStringSortSupport *) ssup->ssup_extra; VarString *authoritative = DatumGetVarStringPP(original); char *authoritative_data = VARDATA_ANY(authoritative); /* working state */ Datum res; char *pres; int len; uint32 hash; pres = (char *) &res; /* memset(), so any non-overwritten bytes are NUL */ memset(pres, 0, sizeof(Datum)); len = VARSIZE_ANY_EXHDR(authoritative); /* Get number of bytes, ignoring trailing spaces */ if (sss->typid == BPCHAROID) len = bpchartruelen(authoritative_data, len); /* * If we're using the C collation, use memcpy(), rather than strxfrm(), to * abbreviate keys. The full comparator for the C locale is always * memcmp(). It would be incorrect to allow bytea callers (callers that * always force the C collation -- bytea isn't a collatable type, but this * approach is convenient) to use strxfrm(). This is because bytea * strings may contain NUL bytes. Besides, this should be faster, too. * * More generally, it's okay that bytea callers can have NUL bytes in * strings because varstrcmp_abbrev() need not make a distinction between * terminating NUL bytes, and NUL bytes representing actual NULs in the * authoritative representation. Hopefully a comparison at or past one * abbreviated key's terminating NUL byte will resolve the comparison * without consulting the authoritative representation; specifically, some * later non-NUL byte in the longer string can resolve the comparison * against a subsequent terminating NUL in the shorter string. There will * usually be what is effectively a "length-wise" resolution there and * then. * * If that doesn't work out -- if all bytes in the longer string * positioned at or past the offset of the smaller string's (first) * terminating NUL are actually representative of NUL bytes in the * authoritative binary string (perhaps with some *terminating* NUL bytes * towards the end of the longer string iff it happens to still be small) * -- then an authoritative tie-breaker will happen, and do the right * thing: explicitly consider string length. */ if (sss->collate_c) memcpy(pres, authoritative_data, Min(len, sizeof(Datum))); else { Size bsize; #ifdef USE_ICU int32_t ulen = -1; UChar *uchar = NULL; #endif /* * We're not using the C collation, so fall back on strxfrm or ICU * analogs. */ /* By convention, we use buffer 1 to store and NUL-terminate */ if (len >= sss->buflen1) { pfree(sss->buf1); sss->buflen1 = Max(len + 1, Min(sss->buflen1 * 2, MaxAllocSize)); sss->buf1 = palloc(sss->buflen1); } /* Might be able to reuse strxfrm() blob from last call */ if (sss->last_len1 == len && sss->cache_blob && memcmp(sss->buf1, authoritative_data, len) == 0) { memcpy(pres, sss->buf2, Min(sizeof(Datum), sss->last_len2)); /* No change affecting cardinality, so no hashing required */ goto done; } memcpy(sss->buf1, authoritative_data, len); /* * Just like strcoll(), strxfrm() expects a NUL-terminated string. Not * necessary for ICU, but doesn't hurt. */ sss->buf1[len] = '\0'; sss->last_len1 = len; #ifdef USE_ICU /* When using ICU and not UTF8, convert string to UChar. */ if (sss->locale && sss->locale->provider == COLLPROVIDER_ICU && GetDatabaseEncoding() != PG_UTF8) ulen = icu_to_uchar(&uchar, sss->buf1, len); #endif /* * Loop: Call strxfrm() or ucol_getSortKey(), possibly enlarge buffer, * and try again. Both of these functions have the result buffer * content undefined if the result did not fit, so we need to retry * until everything fits, even though we only need the first few bytes * in the end. When using ucol_nextSortKeyPart(), however, we only * ask for as many bytes as we actually need. */ for (;;) { #ifdef USE_ICU if (sss->locale && sss->locale->provider == COLLPROVIDER_ICU) { /* * When using UTF8, use the iteration interface so we only * need to produce as many bytes as we actually need. */ if (GetDatabaseEncoding() == PG_UTF8) { UCharIterator iter; uint32_t state[2]; UErrorCode status; uiter_setUTF8(&iter, sss->buf1, len); state[0] = state[1] = 0; /* won't need that again */ status = U_ZERO_ERROR; bsize = ucol_nextSortKeyPart(sss->locale->info.icu.ucol, &iter, state, (uint8_t *) sss->buf2, Min(sizeof(Datum), sss->buflen2), &status); if (U_FAILURE(status)) ereport(ERROR, (errmsg("sort key generation failed: %s", u_errorName(status)))); } else bsize = ucol_getSortKey(sss->locale->info.icu.ucol, uchar, ulen, (uint8_t *) sss->buf2, sss->buflen2); } else #endif #ifdef HAVE_LOCALE_T if (sss->locale && sss->locale->provider == COLLPROVIDER_LIBC) bsize = strxfrm_l(sss->buf2, sss->buf1, sss->buflen2, sss->locale->info.lt); else #endif bsize = strxfrm(sss->buf2, sss->buf1, sss->buflen2); sss->last_len2 = bsize; if (bsize < sss->buflen2) break; /* * Grow buffer and retry. */ pfree(sss->buf2); sss->buflen2 = Max(bsize + 1, Min(sss->buflen2 * 2, MaxAllocSize)); sss->buf2 = palloc(sss->buflen2); } /* * Every Datum byte is always compared. This is safe because the * strxfrm() blob is itself NUL terminated, leaving no danger of * misinterpreting any NUL bytes not intended to be interpreted as * logically representing termination. * * (Actually, even if there were NUL bytes in the blob it would be * okay. See remarks on bytea case above.) */ memcpy(pres, sss->buf2, Min(sizeof(Datum), bsize)); #ifdef USE_ICU if (uchar) pfree(uchar); #endif } /* * Maintain approximate cardinality of both abbreviated keys and original, * authoritative keys using HyperLogLog. Used as cheap insurance against * the worst case, where we do many string transformations for no saving * in full strcoll()-based comparisons. These statistics are used by * varstr_abbrev_abort(). * * First, Hash key proper, or a significant fraction of it. Mix in length * in order to compensate for cases where differences are past * PG_CACHE_LINE_SIZE bytes, so as to limit the overhead of hashing. */ hash = DatumGetUInt32(hash_any((unsigned char *) authoritative_data, Min(len, PG_CACHE_LINE_SIZE))); if (len > PG_CACHE_LINE_SIZE) hash ^= DatumGetUInt32(hash_uint32((uint32) len)); addHyperLogLog(&sss->full_card, hash); /* Hash abbreviated key */ #if SIZEOF_DATUM == 8 { uint32 lohalf, hihalf; lohalf = (uint32) res; hihalf = (uint32) (res >> 32); hash = DatumGetUInt32(hash_uint32(lohalf ^ hihalf)); } #else /* SIZEOF_DATUM != 8 */ hash = DatumGetUInt32(hash_uint32((uint32) res)); #endif addHyperLogLog(&sss->abbr_card, hash); /* Cache result, perhaps saving an expensive strxfrm() call next time */ sss->cache_blob = true; done: /* * Byteswap on little-endian machines. * * This is needed so that varstrcmp_abbrev() (an unsigned integer 3-way * comparator) works correctly on all platforms. If we didn't do this, * the comparator would have to call memcmp() with a pair of pointers to * the first byte of each abbreviated key, which is slower. */ res = DatumBigEndianToNative(res); /* Don't leak memory here */ if (PointerGetDatum(authoritative) != original) pfree(authoritative); return res; } /* * Callback for estimating effectiveness of abbreviated key optimization, using * heuristic rules. Returns value indicating if the abbreviation optimization * should be aborted, based on its projected effectiveness. */ static bool varstr_abbrev_abort(int memtupcount, SortSupport ssup) { VarStringSortSupport *sss = (VarStringSortSupport *) ssup->ssup_extra; double abbrev_distinct, key_distinct; Assert(ssup->abbreviate); /* Have a little patience */ if (memtupcount < 100) return false; abbrev_distinct = estimateHyperLogLog(&sss->abbr_card); key_distinct = estimateHyperLogLog(&sss->full_card); /* * Clamp cardinality estimates to at least one distinct value. While * NULLs are generally disregarded, if only NULL values were seen so far, * that might misrepresent costs if we failed to clamp. */ if (abbrev_distinct <= 1.0) abbrev_distinct = 1.0; if (key_distinct <= 1.0) key_distinct = 1.0; /* * In the worst case all abbreviated keys are identical, while at the same * time there are differences within full key strings not captured in * abbreviations. */ #ifdef TRACE_SORT if (trace_sort) { double norm_abbrev_card = abbrev_distinct / (double) memtupcount; elog(LOG, "varstr_abbrev: abbrev_distinct after %d: %f " "(key_distinct: %f, norm_abbrev_card: %f, prop_card: %f)", memtupcount, abbrev_distinct, key_distinct, norm_abbrev_card, sss->prop_card); } #endif /* * If the number of distinct abbreviated keys approximately matches the * number of distinct authoritative original keys, that's reason enough to * proceed. We can win even with a very low cardinality set if most * tie-breakers only memcmp(). This is by far the most important * consideration. * * While comparisons that are resolved at the abbreviated key level are * considerably cheaper than tie-breakers resolved with memcmp(), both of * those two outcomes are so much cheaper than a full strcoll() once * sorting is underway that it doesn't seem worth it to weigh abbreviated * cardinality against the overall size of the set in order to more * accurately model costs. Assume that an abbreviated comparison, and an * abbreviated comparison with a cheap memcmp()-based authoritative * resolution are equivalent. */ if (abbrev_distinct > key_distinct * sss->prop_card) { /* * When we have exceeded 10,000 tuples, decay required cardinality * aggressively for next call. * * This is useful because the number of comparisons required on * average increases at a linearithmic rate, and at roughly 10,000 * tuples that factor will start to dominate over the linear costs of * string transformation (this is a conservative estimate). The decay * rate is chosen to be a little less aggressive than halving -- which * (since we're called at points at which memtupcount has doubled) * would never see the cost model actually abort past the first call * following a decay. This decay rate is mostly a precaution against * a sudden, violent swing in how well abbreviated cardinality tracks * full key cardinality. The decay also serves to prevent a marginal * case from being aborted too late, when too much has already been * invested in string transformation. * * It's possible for sets of several million distinct strings with * mere tens of thousands of distinct abbreviated keys to still * benefit very significantly. This will generally occur provided * each abbreviated key is a proxy for a roughly uniform number of the * set's full keys. If it isn't so, we hope to catch that early and * abort. If it isn't caught early, by the time the problem is * apparent it's probably not worth aborting. */ if (memtupcount > 10000) sss->prop_card *= 0.65; return false; } /* * Abort abbreviation strategy. * * The worst case, where all abbreviated keys are identical while all * original strings differ will typically only see a regression of about * 10% in execution time for small to medium sized lists of strings. * Whereas on modern CPUs where cache stalls are the dominant cost, we can * often expect very large improvements, particularly with sets of strings * of moderately high to high abbreviated cardinality. There is little to * lose but much to gain, which our strategy reflects. */ #ifdef TRACE_SORT if (trace_sort) elog(LOG, "varstr_abbrev: aborted abbreviation at %d " "(abbrev_distinct: %f, key_distinct: %f, prop_card: %f)", memtupcount, abbrev_distinct, key_distinct, sss->prop_card); #endif return true; } /* * Generic equalimage support function for character type's operator classes. * Disables the use of deduplication with nondeterministic collations. */ Datum btvarstrequalimage(PG_FUNCTION_ARGS) { /* Oid opcintype = PG_GETARG_OID(0); */ Oid collid = PG_GET_COLLATION(); check_collation_set(collid); if (lc_collate_is_c(collid) || collid == DEFAULT_COLLATION_OID || get_collation_isdeterministic(collid)) PG_RETURN_BOOL(true); else PG_RETURN_BOOL(false); } Datum text_larger(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); text *result; result = ((text_cmp(arg1, arg2, PG_GET_COLLATION()) > 0) ? arg1 : arg2); PG_RETURN_TEXT_P(result); } Datum text_smaller(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); text *result; result = ((text_cmp(arg1, arg2, PG_GET_COLLATION()) < 0) ? arg1 : arg2); PG_RETURN_TEXT_P(result); } /* * Cross-type comparison functions for types text and name. */ Datum nameeqtext(PG_FUNCTION_ARGS) { Name arg1 = PG_GETARG_NAME(0); text *arg2 = PG_GETARG_TEXT_PP(1); size_t len1 = strlen(NameStr(*arg1)); size_t len2 = VARSIZE_ANY_EXHDR(arg2); Oid collid = PG_GET_COLLATION(); bool result; check_collation_set(collid); if (collid == C_COLLATION_OID) result = (len1 == len2 && memcmp(NameStr(*arg1), VARDATA_ANY(arg2), len1) == 0); else result = (varstr_cmp(NameStr(*arg1), len1, VARDATA_ANY(arg2), len2, collid) == 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result); } Datum texteqname(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); Name arg2 = PG_GETARG_NAME(1); size_t len1 = VARSIZE_ANY_EXHDR(arg1); size_t len2 = strlen(NameStr(*arg2)); Oid collid = PG_GET_COLLATION(); bool result; check_collation_set(collid); if (collid == C_COLLATION_OID) result = (len1 == len2 && memcmp(VARDATA_ANY(arg1), NameStr(*arg2), len1) == 0); else result = (varstr_cmp(VARDATA_ANY(arg1), len1, NameStr(*arg2), len2, collid) == 0); PG_FREE_IF_COPY(arg1, 0); PG_RETURN_BOOL(result); } Datum namenetext(PG_FUNCTION_ARGS) { Name arg1 = PG_GETARG_NAME(0); text *arg2 = PG_GETARG_TEXT_PP(1); size_t len1 = strlen(NameStr(*arg1)); size_t len2 = VARSIZE_ANY_EXHDR(arg2); Oid collid = PG_GET_COLLATION(); bool result; check_collation_set(collid); if (collid == C_COLLATION_OID) result = !(len1 == len2 && memcmp(NameStr(*arg1), VARDATA_ANY(arg2), len1) == 0); else result = !(varstr_cmp(NameStr(*arg1), len1, VARDATA_ANY(arg2), len2, collid) == 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result); } Datum textnename(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); Name arg2 = PG_GETARG_NAME(1); size_t len1 = VARSIZE_ANY_EXHDR(arg1); size_t len2 = strlen(NameStr(*arg2)); Oid collid = PG_GET_COLLATION(); bool result; check_collation_set(collid); if (collid == C_COLLATION_OID) result = !(len1 == len2 && memcmp(VARDATA_ANY(arg1), NameStr(*arg2), len1) == 0); else result = !(varstr_cmp(VARDATA_ANY(arg1), len1, NameStr(*arg2), len2, collid) == 0); PG_FREE_IF_COPY(arg1, 0); PG_RETURN_BOOL(result); } Datum btnametextcmp(PG_FUNCTION_ARGS) { Name arg1 = PG_GETARG_NAME(0); text *arg2 = PG_GETARG_TEXT_PP(1); int32 result; result = varstr_cmp(NameStr(*arg1), strlen(NameStr(*arg1)), VARDATA_ANY(arg2), VARSIZE_ANY_EXHDR(arg2), PG_GET_COLLATION()); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_INT32(result); } Datum bttextnamecmp(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); Name arg2 = PG_GETARG_NAME(1); int32 result; result = varstr_cmp(VARDATA_ANY(arg1), VARSIZE_ANY_EXHDR(arg1), NameStr(*arg2), strlen(NameStr(*arg2)), PG_GET_COLLATION()); PG_FREE_IF_COPY(arg1, 0); PG_RETURN_INT32(result); } #define CmpCall(cmpfunc) \ DatumGetInt32(DirectFunctionCall2Coll(cmpfunc, \ PG_GET_COLLATION(), \ PG_GETARG_DATUM(0), \ PG_GETARG_DATUM(1))) Datum namelttext(PG_FUNCTION_ARGS) { PG_RETURN_BOOL(CmpCall(btnametextcmp) < 0); } Datum nameletext(PG_FUNCTION_ARGS) { PG_RETURN_BOOL(CmpCall(btnametextcmp) <= 0); } Datum namegttext(PG_FUNCTION_ARGS) { PG_RETURN_BOOL(CmpCall(btnametextcmp) > 0); } Datum namegetext(PG_FUNCTION_ARGS) { PG_RETURN_BOOL(CmpCall(btnametextcmp) >= 0); } Datum textltname(PG_FUNCTION_ARGS) { PG_RETURN_BOOL(CmpCall(bttextnamecmp) < 0); } Datum textlename(PG_FUNCTION_ARGS) { PG_RETURN_BOOL(CmpCall(bttextnamecmp) <= 0); } Datum textgtname(PG_FUNCTION_ARGS) { PG_RETURN_BOOL(CmpCall(bttextnamecmp) > 0); } Datum textgename(PG_FUNCTION_ARGS) { PG_RETURN_BOOL(CmpCall(bttextnamecmp) >= 0); } #undef CmpCall /* * The following operators support character-by-character comparison * of text datums, to allow building indexes suitable for LIKE clauses. * Note that the regular texteq/textne comparison operators, and regular * support functions 1 and 2 with "C" collation are assumed to be * compatible with these! */ static int internal_text_pattern_compare(text *arg1, text *arg2) { int result; int len1, len2; len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); result = memcmp(VARDATA_ANY(arg1), VARDATA_ANY(arg2), Min(len1, len2)); if (result != 0) return result; else if (len1 < len2) return -1; else if (len1 > len2) return 1; else return 0; } Datum text_pattern_lt(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); int result; result = internal_text_pattern_compare(arg1, arg2); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result < 0); } Datum text_pattern_le(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); int result; result = internal_text_pattern_compare(arg1, arg2); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result <= 0); } Datum text_pattern_ge(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); int result; result = internal_text_pattern_compare(arg1, arg2); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result >= 0); } Datum text_pattern_gt(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); int result; result = internal_text_pattern_compare(arg1, arg2); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL(result > 0); } Datum bttext_pattern_cmp(PG_FUNCTION_ARGS) { text *arg1 = PG_GETARG_TEXT_PP(0); text *arg2 = PG_GETARG_TEXT_PP(1); int result; result = internal_text_pattern_compare(arg1, arg2); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_INT32(result); } Datum bttext_pattern_sortsupport(PG_FUNCTION_ARGS) { SortSupport ssup = (SortSupport) PG_GETARG_POINTER(0); MemoryContext oldcontext; oldcontext = MemoryContextSwitchTo(ssup->ssup_cxt); /* Use generic string SortSupport, forcing "C" collation */ varstr_sortsupport(ssup, TEXTOID, C_COLLATION_OID); MemoryContextSwitchTo(oldcontext); PG_RETURN_VOID(); } /*------------------------------------------------------------- * byteaoctetlen * * get the number of bytes contained in an instance of type 'bytea' *------------------------------------------------------------- */ Datum byteaoctetlen(PG_FUNCTION_ARGS) { Datum str = PG_GETARG_DATUM(0); /* We need not detoast the input at all */ PG_RETURN_INT32(toast_raw_datum_size(str) - VARHDRSZ); } /* * byteacat - * takes two bytea* and returns a bytea* that is the concatenation of * the two. * * Cloned from textcat and modified as required. */ Datum byteacat(PG_FUNCTION_ARGS) { bytea *t1 = PG_GETARG_BYTEA_PP(0); bytea *t2 = PG_GETARG_BYTEA_PP(1); PG_RETURN_BYTEA_P(bytea_catenate(t1, t2)); } /* * bytea_catenate * Guts of byteacat(), broken out so it can be used by other functions * * Arguments can be in short-header form, but not compressed or out-of-line */ static bytea * bytea_catenate(bytea *t1, bytea *t2) { bytea *result; int len1, len2, len; char *ptr; len1 = VARSIZE_ANY_EXHDR(t1); len2 = VARSIZE_ANY_EXHDR(t2); /* paranoia ... probably should throw error instead? */ if (len1 < 0) len1 = 0; if (len2 < 0) len2 = 0; len = len1 + len2 + VARHDRSZ; result = (bytea *) palloc(len); /* Set size of result string... */ SET_VARSIZE(result, len); /* Fill data field of result string... */ ptr = VARDATA(result); if (len1 > 0) memcpy(ptr, VARDATA_ANY(t1), len1); if (len2 > 0) memcpy(ptr + len1, VARDATA_ANY(t2), len2); return result; } #define PG_STR_GET_BYTEA(str_) \ DatumGetByteaPP(DirectFunctionCall1(byteain, CStringGetDatum(str_))) /* * bytea_substr() * Return a substring starting at the specified position. * Cloned from text_substr and modified as required. * * Input: * - string * - starting position (is one-based) * - string length (optional) * * If the starting position is zero or less, then return from the start of the string * adjusting the length to be consistent with the "negative start" per SQL. * If the length is less than zero, an ERROR is thrown. If no third argument * (length) is provided, the length to the end of the string is assumed. */ Datum bytea_substr(PG_FUNCTION_ARGS) { PG_RETURN_BYTEA_P(bytea_substring(PG_GETARG_DATUM(0), PG_GETARG_INT32(1), PG_GETARG_INT32(2), false)); } /* * bytea_substr_no_len - * Wrapper to avoid opr_sanity failure due to * one function accepting a different number of args. */ Datum bytea_substr_no_len(PG_FUNCTION_ARGS) { PG_RETURN_BYTEA_P(bytea_substring(PG_GETARG_DATUM(0), PG_GETARG_INT32(1), -1, true)); } static bytea * bytea_substring(Datum str, int S, int L, bool length_not_specified) { int32 S1; /* adjusted start position */ int32 L1; /* adjusted substring length */ int32 E; /* end position */ /* * The logic here should generally match text_substring(). */ S1 = Max(S, 1); if (length_not_specified) { /* * Not passed a length - DatumGetByteaPSlice() grabs everything to the * end of the string if we pass it a negative value for length. */ L1 = -1; } else if (L < 0) { /* SQL99 says to throw an error for E < S, i.e., negative length */ ereport(ERROR, (errcode(ERRCODE_SUBSTRING_ERROR), errmsg("negative substring length not allowed"))); L1 = -1; /* silence stupider compilers */ } else if (pg_add_s32_overflow(S, L, &E)) { /* * L could be large enough for S + L to overflow, in which case the * substring must run to end of string. */ L1 = -1; } else { /* * A zero or negative value for the end position can happen if the * start was negative or one. SQL99 says to return a zero-length * string. */ if (E < 1) return PG_STR_GET_BYTEA(""); L1 = E - S1; } /* * If the start position is past the end of the string, SQL99 says to * return a zero-length string -- DatumGetByteaPSlice() will do that for * us. We need only convert S1 to zero-based starting position. */ return DatumGetByteaPSlice(str, S1 - 1, L1); } /* * byteaoverlay * Replace specified substring of first string with second * * The SQL standard defines OVERLAY() in terms of substring and concatenation. * This code is a direct implementation of what the standard says. */ Datum byteaoverlay(PG_FUNCTION_ARGS) { bytea *t1 = PG_GETARG_BYTEA_PP(0); bytea *t2 = PG_GETARG_BYTEA_PP(1); int sp = PG_GETARG_INT32(2); /* substring start position */ int sl = PG_GETARG_INT32(3); /* substring length */ PG_RETURN_BYTEA_P(bytea_overlay(t1, t2, sp, sl)); } Datum byteaoverlay_no_len(PG_FUNCTION_ARGS) { bytea *t1 = PG_GETARG_BYTEA_PP(0); bytea *t2 = PG_GETARG_BYTEA_PP(1); int sp = PG_GETARG_INT32(2); /* substring start position */ int sl; sl = VARSIZE_ANY_EXHDR(t2); /* defaults to length(t2) */ PG_RETURN_BYTEA_P(bytea_overlay(t1, t2, sp, sl)); } static bytea * bytea_overlay(bytea *t1, bytea *t2, int sp, int sl) { bytea *result; bytea *s1; bytea *s2; int sp_pl_sl; /* * Check for possible integer-overflow cases. For negative sp, throw a * "substring length" error because that's what should be expected * according to the spec's definition of OVERLAY(). */ if (sp <= 0) ereport(ERROR, (errcode(ERRCODE_SUBSTRING_ERROR), errmsg("negative substring length not allowed"))); if (pg_add_s32_overflow(sp, sl, &sp_pl_sl)) ereport(ERROR, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("integer out of range"))); s1 = bytea_substring(PointerGetDatum(t1), 1, sp - 1, false); s2 = bytea_substring(PointerGetDatum(t1), sp_pl_sl, -1, true); result = bytea_catenate(s1, t2); result = bytea_catenate(result, s2); return result; } /* * bit_count */ Datum bytea_bit_count(PG_FUNCTION_ARGS) { bytea *t1 = PG_GETARG_BYTEA_PP(0); PG_RETURN_INT64(pg_popcount(VARDATA_ANY(t1), VARSIZE_ANY_EXHDR(t1))); } /* * byteapos - * Return the position of the specified substring. * Implements the SQL POSITION() function. * Cloned from textpos and modified as required. */ Datum byteapos(PG_FUNCTION_ARGS) { bytea *t1 = PG_GETARG_BYTEA_PP(0); bytea *t2 = PG_GETARG_BYTEA_PP(1); int pos; int px, p; int len1, len2; char *p1, *p2; len1 = VARSIZE_ANY_EXHDR(t1); len2 = VARSIZE_ANY_EXHDR(t2); if (len2 <= 0) PG_RETURN_INT32(1); /* result for empty pattern */ p1 = VARDATA_ANY(t1); p2 = VARDATA_ANY(t2); pos = 0; px = (len1 - len2); for (p = 0; p <= px; p++) { if ((*p2 == *p1) && (memcmp(p1, p2, len2) == 0)) { pos = p + 1; break; }; p1++; }; PG_RETURN_INT32(pos); } /*------------------------------------------------------------- * byteaGetByte * * this routine treats "bytea" as an array of bytes. * It returns the Nth byte (a number between 0 and 255). *------------------------------------------------------------- */ Datum byteaGetByte(PG_FUNCTION_ARGS) { bytea *v = PG_GETARG_BYTEA_PP(0); int32 n = PG_GETARG_INT32(1); int len; int byte; len = VARSIZE_ANY_EXHDR(v); if (n < 0 || n >= len) ereport(ERROR, (errcode(ERRCODE_ARRAY_SUBSCRIPT_ERROR), errmsg("index %d out of valid range, 0..%d", n, len - 1))); byte = ((unsigned char *) VARDATA_ANY(v))[n]; PG_RETURN_INT32(byte); } /*------------------------------------------------------------- * byteaGetBit * * This routine treats a "bytea" type like an array of bits. * It returns the value of the Nth bit (0 or 1). * *------------------------------------------------------------- */ Datum byteaGetBit(PG_FUNCTION_ARGS) { bytea *v = PG_GETARG_BYTEA_PP(0); int64 n = PG_GETARG_INT64(1); int byteNo, bitNo; int len; int byte; len = VARSIZE_ANY_EXHDR(v); if (n < 0 || n >= (int64) len * 8) ereport(ERROR, (errcode(ERRCODE_ARRAY_SUBSCRIPT_ERROR), errmsg("index %lld out of valid range, 0..%lld", (long long) n, (long long) len * 8 - 1))); /* n/8 is now known < len, so safe to cast to int */ byteNo = (int) (n / 8); bitNo = (int) (n % 8); byte = ((unsigned char *) VARDATA_ANY(v))[byteNo]; if (byte & (1 << bitNo)) PG_RETURN_INT32(1); else PG_RETURN_INT32(0); } /*------------------------------------------------------------- * byteaSetByte * * Given an instance of type 'bytea' creates a new one with * the Nth byte set to the given value. * *------------------------------------------------------------- */ Datum byteaSetByte(PG_FUNCTION_ARGS) { bytea *res = PG_GETARG_BYTEA_P_COPY(0); int32 n = PG_GETARG_INT32(1); int32 newByte = PG_GETARG_INT32(2); int len; len = VARSIZE(res) - VARHDRSZ; if (n < 0 || n >= len) ereport(ERROR, (errcode(ERRCODE_ARRAY_SUBSCRIPT_ERROR), errmsg("index %d out of valid range, 0..%d", n, len - 1))); /* * Now set the byte. */ ((unsigned char *) VARDATA(res))[n] = newByte; PG_RETURN_BYTEA_P(res); } /*------------------------------------------------------------- * byteaSetBit * * Given an instance of type 'bytea' creates a new one with * the Nth bit set to the given value. * *------------------------------------------------------------- */ Datum byteaSetBit(PG_FUNCTION_ARGS) { bytea *res = PG_GETARG_BYTEA_P_COPY(0); int64 n = PG_GETARG_INT64(1); int32 newBit = PG_GETARG_INT32(2); int len; int oldByte, newByte; int byteNo, bitNo; len = VARSIZE(res) - VARHDRSZ; if (n < 0 || n >= (int64) len * 8) ereport(ERROR, (errcode(ERRCODE_ARRAY_SUBSCRIPT_ERROR), errmsg("index %lld out of valid range, 0..%lld", (long long) n, (long long) len * 8 - 1))); /* n/8 is now known < len, so safe to cast to int */ byteNo = (int) (n / 8); bitNo = (int) (n % 8); /* * sanity check! */ if (newBit != 0 && newBit != 1) ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("new bit must be 0 or 1"))); /* * Update the byte. */ oldByte = ((unsigned char *) VARDATA(res))[byteNo]; if (newBit == 0) newByte = oldByte & (~(1 << bitNo)); else newByte = oldByte | (1 << bitNo); ((unsigned char *) VARDATA(res))[byteNo] = newByte; PG_RETURN_BYTEA_P(res); } /* text_name() * Converts a text type to a Name type. */ Datum text_name(PG_FUNCTION_ARGS) { text *s = PG_GETARG_TEXT_PP(0); Name result; int len; len = VARSIZE_ANY_EXHDR(s); /* Truncate oversize input */ if (len >= NAMEDATALEN) len = pg_mbcliplen(VARDATA_ANY(s), len, NAMEDATALEN - 1); /* We use palloc0 here to ensure result is zero-padded */ result = (Name) palloc0(NAMEDATALEN); memcpy(NameStr(*result), VARDATA_ANY(s), len); PG_RETURN_NAME(result); } /* name_text() * Converts a Name type to a text type. */ Datum name_text(PG_FUNCTION_ARGS) { Name s = PG_GETARG_NAME(0); PG_RETURN_TEXT_P(cstring_to_text(NameStr(*s))); } /* * textToQualifiedNameList - convert a text object to list of names * * This implements the input parsing needed by nextval() and other * functions that take a text parameter representing a qualified name. * We split the name at dots, downcase if not double-quoted, and * truncate names if they're too long. */ List * textToQualifiedNameList(text *textval) { char *rawname; List *result = NIL; List *namelist; ListCell *l; /* Convert to C string (handles possible detoasting). */ /* Note we rely on being able to modify rawname below. */ rawname = text_to_cstring(textval); if (!SplitIdentifierString(rawname, '.', &namelist)) ereport(ERROR, (errcode(ERRCODE_INVALID_NAME), errmsg("invalid name syntax"))); if (namelist == NIL) ereport(ERROR, (errcode(ERRCODE_INVALID_NAME), errmsg("invalid name syntax"))); foreach(l, namelist) { char *curname = (char *) lfirst(l); result = lappend(result, makeString(pstrdup(curname))); } pfree(rawname); list_free(namelist); return result; } /* * SplitIdentifierString --- parse a string containing identifiers * * This is the guts of textToQualifiedNameList, and is exported for use in * other situations such as parsing GUC variables. In the GUC case, it's * important to avoid memory leaks, so the API is designed to minimize the * amount of stuff that needs to be allocated and freed. * * Inputs: * rawstring: the input string; must be overwritable! On return, it's * been modified to contain the separated identifiers. * separator: the separator punctuation expected between identifiers * (typically '.' or ','). Whitespace may also appear around * identifiers. * Outputs: * namelist: filled with a palloc'd list of pointers to identifiers within * rawstring. Caller should list_free() this even on error return. * * Returns true if okay, false if there is a syntax error in the string. * * Note that an empty string is considered okay here, though not in * textToQualifiedNameList. */ bool SplitIdentifierString(char *rawstring, char separator, List **namelist) { char *nextp = rawstring; bool done = false; *namelist = NIL; while (scanner_isspace(*nextp)) nextp++; /* skip leading whitespace */ if (*nextp == '\0') return true; /* allow empty string */ /* At the top of the loop, we are at start of a new identifier. */ do { char *curname; char *endp; if (*nextp == '"') { /* Quoted name --- collapse quote-quote pairs, no downcasing */ curname = nextp + 1; for (;;) { endp = strchr(nextp + 1, '"'); if (endp == NULL) return false; /* mismatched quotes */ if (endp[1] != '"') break; /* found end of quoted name */ /* Collapse adjacent quotes into one quote, and look again */ memmove(endp, endp + 1, strlen(endp)); nextp = endp; } /* endp now points at the terminating quote */ nextp = endp + 1; } else { /* Unquoted name --- extends to separator or whitespace */ char *downname; int len; curname = nextp; while (*nextp && *nextp != separator && !scanner_isspace(*nextp)) nextp++; endp = nextp; if (curname == nextp) return false; /* empty unquoted name not allowed */ /* * Downcase the identifier, using same code as main lexer does. * * XXX because we want to overwrite the input in-place, we cannot * support a downcasing transformation that increases the string * length. This is not a problem given the current implementation * of downcase_truncate_identifier, but we'll probably have to do * something about this someday. */ len = endp - curname; downname = downcase_truncate_identifier(curname, len, false); Assert(strlen(downname) <= len); strncpy(curname, downname, len); /* strncpy is required here */ pfree(downname); } while (scanner_isspace(*nextp)) nextp++; /* skip trailing whitespace */ if (*nextp == separator) { nextp++; while (scanner_isspace(*nextp)) nextp++; /* skip leading whitespace for next */ /* we expect another name, so done remains false */ } else if (*nextp == '\0') done = true; else return false; /* invalid syntax */ /* Now safe to overwrite separator with a null */ *endp = '\0'; /* Truncate name if it's overlength */ truncate_identifier(curname, strlen(curname), false); /* * Finished isolating current name --- add it to list */ *namelist = lappend(*namelist, curname); /* Loop back if we didn't reach end of string */ } while (!done); return true; } /* * SplitDirectoriesString --- parse a string containing file/directory names * * This works fine on file names too; the function name is historical. * * This is similar to SplitIdentifierString, except that the parsing * rules are meant to handle pathnames instead of identifiers: there is * no downcasing, embedded spaces are allowed, the max length is MAXPGPATH-1, * and we apply canonicalize_path() to each extracted string. Because of the * last, the returned strings are separately palloc'd rather than being * pointers into rawstring --- but we still scribble on rawstring. * * Inputs: * rawstring: the input string; must be modifiable! * separator: the separator punctuation expected between directories * (typically ',' or ';'). Whitespace may also appear around * directories. * Outputs: * namelist: filled with a palloc'd list of directory names. * Caller should list_free_deep() this even on error return. * * Returns true if okay, false if there is a syntax error in the string. * * Note that an empty string is considered okay here. */ bool SplitDirectoriesString(char *rawstring, char separator, List **namelist) { char *nextp = rawstring; bool done = false; *namelist = NIL; while (scanner_isspace(*nextp)) nextp++; /* skip leading whitespace */ if (*nextp == '\0') return true; /* allow empty string */ /* At the top of the loop, we are at start of a new directory. */ do { char *curname; char *endp; if (*nextp == '"') { /* Quoted name --- collapse quote-quote pairs */ curname = nextp + 1; for (;;) { endp = strchr(nextp + 1, '"'); if (endp == NULL) return false; /* mismatched quotes */ if (endp[1] != '"') break; /* found end of quoted name */ /* Collapse adjacent quotes into one quote, and look again */ memmove(endp, endp + 1, strlen(endp)); nextp = endp; } /* endp now points at the terminating quote */ nextp = endp + 1; } else { /* Unquoted name --- extends to separator or end of string */ curname = endp = nextp; while (*nextp && *nextp != separator) { /* trailing whitespace should not be included in name */ if (!scanner_isspace(*nextp)) endp = nextp + 1; nextp++; } if (curname == endp) return false; /* empty unquoted name not allowed */ } while (scanner_isspace(*nextp)) nextp++; /* skip trailing whitespace */ if (*nextp == separator) { nextp++; while (scanner_isspace(*nextp)) nextp++; /* skip leading whitespace for next */ /* we expect another name, so done remains false */ } else if (*nextp == '\0') done = true; else return false; /* invalid syntax */ /* Now safe to overwrite separator with a null */ *endp = '\0'; /* Truncate path if it's overlength */ if (strlen(curname) >= MAXPGPATH) curname[MAXPGPATH - 1] = '\0'; /* * Finished isolating current name --- add it to list */ curname = pstrdup(curname); canonicalize_path(curname); *namelist = lappend(*namelist, curname); /* Loop back if we didn't reach end of string */ } while (!done); return true; } /* * SplitGUCList --- parse a string containing identifiers or file names * * This is used to split the value of a GUC_LIST_QUOTE GUC variable, without * presuming whether the elements will be taken as identifiers or file names. * We assume the input has already been through flatten_set_variable_args(), * so that we need never downcase (if appropriate, that was done already). * Nor do we ever truncate, since we don't know the correct max length. * We disallow embedded whitespace for simplicity (it shouldn't matter, * because any embedded whitespace should have led to double-quoting). * Otherwise the API is identical to SplitIdentifierString. * * XXX it's annoying to have so many copies of this string-splitting logic. * However, it's not clear that having one function with a bunch of option * flags would be much better. * * XXX there is a version of this function in src/bin/pg_dump/dumputils.c. * Be sure to update that if you have to change this. * * Inputs: * rawstring: the input string; must be overwritable! On return, it's * been modified to contain the separated identifiers. * separator: the separator punctuation expected between identifiers * (typically '.' or ','). Whitespace may also appear around * identifiers. * Outputs: * namelist: filled with a palloc'd list of pointers to identifiers within * rawstring. Caller should list_free() this even on error return. * * Returns true if okay, false if there is a syntax error in the string. */ bool SplitGUCList(char *rawstring, char separator, List **namelist) { char *nextp = rawstring; bool done = false; *namelist = NIL; while (scanner_isspace(*nextp)) nextp++; /* skip leading whitespace */ if (*nextp == '\0') return true; /* allow empty string */ /* At the top of the loop, we are at start of a new identifier. */ do { char *curname; char *endp; if (*nextp == '"') { /* Quoted name --- collapse quote-quote pairs */ curname = nextp + 1; for (;;) { endp = strchr(nextp + 1, '"'); if (endp == NULL) return false; /* mismatched quotes */ if (endp[1] != '"') break; /* found end of quoted name */ /* Collapse adjacent quotes into one quote, and look again */ memmove(endp, endp + 1, strlen(endp)); nextp = endp; } /* endp now points at the terminating quote */ nextp = endp + 1; } else { /* Unquoted name --- extends to separator or whitespace */ curname = nextp; while (*nextp && *nextp != separator && !scanner_isspace(*nextp)) nextp++; endp = nextp; if (curname == nextp) return false; /* empty unquoted name not allowed */ } while (scanner_isspace(*nextp)) nextp++; /* skip trailing whitespace */ if (*nextp == separator) { nextp++; while (scanner_isspace(*nextp)) nextp++; /* skip leading whitespace for next */ /* we expect another name, so done remains false */ } else if (*nextp == '\0') done = true; else return false; /* invalid syntax */ /* Now safe to overwrite separator with a null */ *endp = '\0'; /* * Finished isolating current name --- add it to list */ *namelist = lappend(*namelist, curname); /* Loop back if we didn't reach end of string */ } while (!done); return true; } /***************************************************************************** * Comparison Functions used for bytea * * Note: btree indexes need these routines not to leak memory; therefore, * be careful to free working copies of toasted datums. Most places don't * need to be so careful. *****************************************************************************/ Datum byteaeq(PG_FUNCTION_ARGS) { Datum arg1 = PG_GETARG_DATUM(0); Datum arg2 = PG_GETARG_DATUM(1); bool result; Size len1, len2; /* * We can use a fast path for unequal lengths, which might save us from * having to detoast one or both values. */ len1 = toast_raw_datum_size(arg1); len2 = toast_raw_datum_size(arg2); if (len1 != len2) result = false; else { bytea *barg1 = DatumGetByteaPP(arg1); bytea *barg2 = DatumGetByteaPP(arg2); result = (memcmp(VARDATA_ANY(barg1), VARDATA_ANY(barg2), len1 - VARHDRSZ) == 0); PG_FREE_IF_COPY(barg1, 0); PG_FREE_IF_COPY(barg2, 1); } PG_RETURN_BOOL(result); } Datum byteane(PG_FUNCTION_ARGS) { Datum arg1 = PG_GETARG_DATUM(0); Datum arg2 = PG_GETARG_DATUM(1); bool result; Size len1, len2; /* * We can use a fast path for unequal lengths, which might save us from * having to detoast one or both values. */ len1 = toast_raw_datum_size(arg1); len2 = toast_raw_datum_size(arg2); if (len1 != len2) result = true; else { bytea *barg1 = DatumGetByteaPP(arg1); bytea *barg2 = DatumGetByteaPP(arg2); result = (memcmp(VARDATA_ANY(barg1), VARDATA_ANY(barg2), len1 - VARHDRSZ) != 0); PG_FREE_IF_COPY(barg1, 0); PG_FREE_IF_COPY(barg2, 1); } PG_RETURN_BOOL(result); } Datum bytealt(PG_FUNCTION_ARGS) { bytea *arg1 = PG_GETARG_BYTEA_PP(0); bytea *arg2 = PG_GETARG_BYTEA_PP(1); int len1, len2; int cmp; len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); cmp = memcmp(VARDATA_ANY(arg1), VARDATA_ANY(arg2), Min(len1, len2)); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL((cmp < 0) || ((cmp == 0) && (len1 < len2))); } Datum byteale(PG_FUNCTION_ARGS) { bytea *arg1 = PG_GETARG_BYTEA_PP(0); bytea *arg2 = PG_GETARG_BYTEA_PP(1); int len1, len2; int cmp; len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); cmp = memcmp(VARDATA_ANY(arg1), VARDATA_ANY(arg2), Min(len1, len2)); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL((cmp < 0) || ((cmp == 0) && (len1 <= len2))); } Datum byteagt(PG_FUNCTION_ARGS) { bytea *arg1 = PG_GETARG_BYTEA_PP(0); bytea *arg2 = PG_GETARG_BYTEA_PP(1); int len1, len2; int cmp; len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); cmp = memcmp(VARDATA_ANY(arg1), VARDATA_ANY(arg2), Min(len1, len2)); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL((cmp > 0) || ((cmp == 0) && (len1 > len2))); } Datum byteage(PG_FUNCTION_ARGS) { bytea *arg1 = PG_GETARG_BYTEA_PP(0); bytea *arg2 = PG_GETARG_BYTEA_PP(1); int len1, len2; int cmp; len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); cmp = memcmp(VARDATA_ANY(arg1), VARDATA_ANY(arg2), Min(len1, len2)); PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_BOOL((cmp > 0) || ((cmp == 0) && (len1 >= len2))); } Datum byteacmp(PG_FUNCTION_ARGS) { bytea *arg1 = PG_GETARG_BYTEA_PP(0); bytea *arg2 = PG_GETARG_BYTEA_PP(1); int len1, len2; int cmp; len1 = VARSIZE_ANY_EXHDR(arg1); len2 = VARSIZE_ANY_EXHDR(arg2); cmp = memcmp(VARDATA_ANY(arg1), VARDATA_ANY(arg2), Min(len1, len2)); if ((cmp == 0) && (len1 != len2)) cmp = (len1 < len2) ? -1 : 1; PG_FREE_IF_COPY(arg1, 0); PG_FREE_IF_COPY(arg2, 1); PG_RETURN_INT32(cmp); } Datum bytea_sortsupport(PG_FUNCTION_ARGS) { SortSupport ssup = (SortSupport) PG_GETARG_POINTER(0); MemoryContext oldcontext; oldcontext = MemoryContextSwitchTo(ssup->ssup_cxt); /* Use generic string SortSupport, forcing "C" collation */ varstr_sortsupport(ssup, BYTEAOID, C_COLLATION_OID); MemoryContextSwitchTo(oldcontext); PG_RETURN_VOID(); } /* * appendStringInfoText * * Append a text to str. * Like appendStringInfoString(str, text_to_cstring(t)) but faster. */ static void appendStringInfoText(StringInfo str, const text *t) { appendBinaryStringInfo(str, VARDATA_ANY(t), VARSIZE_ANY_EXHDR(t)); } /* * replace_text * replace all occurrences of 'old_sub_str' in 'orig_str' * with 'new_sub_str' to form 'new_str' * * returns 'orig_str' if 'old_sub_str' == '' or 'orig_str' == '' * otherwise returns 'new_str' */ Datum replace_text(PG_FUNCTION_ARGS) { text *src_text = PG_GETARG_TEXT_PP(0); text *from_sub_text = PG_GETARG_TEXT_PP(1); text *to_sub_text = PG_GETARG_TEXT_PP(2); int src_text_len; int from_sub_text_len; TextPositionState state; text *ret_text; int chunk_len; char *curr_ptr; char *start_ptr; StringInfoData str; bool found; src_text_len = VARSIZE_ANY_EXHDR(src_text); from_sub_text_len = VARSIZE_ANY_EXHDR(from_sub_text); /* Return unmodified source string if empty source or pattern */ if (src_text_len < 1 || from_sub_text_len < 1) { PG_RETURN_TEXT_P(src_text); } text_position_setup(src_text, from_sub_text, PG_GET_COLLATION(), &state); found = text_position_next(&state); /* When the from_sub_text is not found, there is nothing to do. */ if (!found) { text_position_cleanup(&state); PG_RETURN_TEXT_P(src_text); } curr_ptr = text_position_get_match_ptr(&state); start_ptr = VARDATA_ANY(src_text); initStringInfo(&str); do { CHECK_FOR_INTERRUPTS(); /* copy the data skipped over by last text_position_next() */ chunk_len = curr_ptr - start_ptr; appendBinaryStringInfo(&str, start_ptr, chunk_len); appendStringInfoText(&str, to_sub_text); start_ptr = curr_ptr + from_sub_text_len; found = text_position_next(&state); if (found) curr_ptr = text_position_get_match_ptr(&state); } while (found); /* copy trailing data */ chunk_len = ((char *) src_text + VARSIZE_ANY(src_text)) - start_ptr; appendBinaryStringInfo(&str, start_ptr, chunk_len); text_position_cleanup(&state); ret_text = cstring_to_text_with_len(str.data, str.len); pfree(str.data); PG_RETURN_TEXT_P(ret_text); } /* * check_replace_text_has_escape_char * * check whether replace_text contains escape char. */ static bool check_replace_text_has_escape_char(const text *replace_text) { const char *p = VARDATA_ANY(replace_text); const char *p_end = p + VARSIZE_ANY_EXHDR(replace_text); if (pg_database_encoding_max_length() == 1) { for (; p < p_end; p++) { if (*p == '\\') return true; } } else { for (; p < p_end; p += pg_mblen(p)) { if (*p == '\\') return true; } } return false; } /* * appendStringInfoRegexpSubstr * * Append replace_text to str, substituting regexp back references for * \n escapes. start_ptr is the start of the match in the source string, * at logical character position data_pos. */ static void appendStringInfoRegexpSubstr(StringInfo str, text *replace_text, regmatch_t *pmatch, char *start_ptr, int data_pos) { const char *p = VARDATA_ANY(replace_text); const char *p_end = p + VARSIZE_ANY_EXHDR(replace_text); int eml = pg_database_encoding_max_length(); for (;;) { const char *chunk_start = p; int so; int eo; /* Find next escape char. */ if (eml == 1) { for (; p < p_end && *p != '\\'; p++) /* nothing */ ; } else { for (; p < p_end && *p != '\\'; p += pg_mblen(p)) /* nothing */ ; } /* Copy the text we just scanned over, if any. */ if (p > chunk_start) appendBinaryStringInfo(str, chunk_start, p - chunk_start); /* Done if at end of string, else advance over escape char. */ if (p >= p_end) break; p++; if (p >= p_end) { /* Escape at very end of input. Treat same as unexpected char */ appendStringInfoChar(str, '\\'); break; } if (*p >= '1' && *p <= '9') { /* Use the back reference of regexp. */ int idx = *p - '0'; so = pmatch[idx].rm_so; eo = pmatch[idx].rm_eo; p++; } else if (*p == '&') { /* Use the entire matched string. */ so = pmatch[0].rm_so; eo = pmatch[0].rm_eo; p++; } else if (*p == '\\') { /* \\ means transfer one \ to output. */ appendStringInfoChar(str, '\\'); p++; continue; } else { /* * If escape char is not followed by any expected char, just treat * it as ordinary data to copy. (XXX would it be better to throw * an error?) */ appendStringInfoChar(str, '\\'); continue; } if (so != -1 && eo != -1) { /* * Copy the text that is back reference of regexp. Note so and eo * are counted in characters not bytes. */ char *chunk_start; int chunk_len; Assert(so >= data_pos); chunk_start = start_ptr; chunk_start += charlen_to_bytelen(chunk_start, so - data_pos); chunk_len = charlen_to_bytelen(chunk_start, eo - so); appendBinaryStringInfo(str, chunk_start, chunk_len); } } } #define REGEXP_REPLACE_BACKREF_CNT 10 /* * replace_text_regexp * * replace text that matches to regexp in src_text to replace_text. * * Note: to avoid having to include regex.h in builtins.h, we declare * the regexp argument as void *, but really it's regex_t *. */ text * replace_text_regexp(text *src_text, void *regexp, text *replace_text, bool glob) { text *ret_text; regex_t *re = (regex_t *) regexp; int src_text_len = VARSIZE_ANY_EXHDR(src_text); StringInfoData buf; regmatch_t pmatch[REGEXP_REPLACE_BACKREF_CNT]; pg_wchar *data; size_t data_len; int search_start; int data_pos; char *start_ptr; bool have_escape; initStringInfo(&buf); /* Convert data string to wide characters. */ data = (pg_wchar *) palloc((src_text_len + 1) * sizeof(pg_wchar)); data_len = pg_mb2wchar_with_len(VARDATA_ANY(src_text), data, src_text_len); /* Check whether replace_text has escape char. */ have_escape = check_replace_text_has_escape_char(replace_text); /* start_ptr points to the data_pos'th character of src_text */ start_ptr = (char *) VARDATA_ANY(src_text); data_pos = 0; search_start = 0; while (search_start <= data_len) { int regexec_result; CHECK_FOR_INTERRUPTS(); regexec_result = pg_regexec(re, data, data_len, search_start, NULL, /* no details */ REGEXP_REPLACE_BACKREF_CNT, pmatch, 0); if (regexec_result == REG_NOMATCH) break; if (regexec_result != REG_OKAY) { char errMsg[100]; CHECK_FOR_INTERRUPTS(); pg_regerror(regexec_result, re, errMsg, sizeof(errMsg)); ereport(ERROR, (errcode(ERRCODE_INVALID_REGULAR_EXPRESSION), errmsg("regular expression failed: %s", errMsg))); } /* * Copy the text to the left of the match position. Note we are given * character not byte indexes. */ if (pmatch[0].rm_so - data_pos > 0) { int chunk_len; chunk_len = charlen_to_bytelen(start_ptr, pmatch[0].rm_so - data_pos); appendBinaryStringInfo(&buf, start_ptr, chunk_len); /* * Advance start_ptr over that text, to avoid multiple rescans of * it if the replace_text contains multiple back-references. */ start_ptr += chunk_len; data_pos = pmatch[0].rm_so; } /* * Copy the replace_text. Process back references when the * replace_text has escape characters. */ if (have_escape) appendStringInfoRegexpSubstr(&buf, replace_text, pmatch, start_ptr, data_pos); else appendStringInfoText(&buf, replace_text); /* Advance start_ptr and data_pos over the matched text. */ start_ptr += charlen_to_bytelen(start_ptr, pmatch[0].rm_eo - data_pos); data_pos = pmatch[0].rm_eo; /* * When global option is off, replace the first instance only. */ if (!glob) break; /* * Advance search position. Normally we start the next search at the * end of the previous match; but if the match was of zero length, we * have to advance by one character, or we'd just find the same match * again. */ search_start = data_pos; if (pmatch[0].rm_so == pmatch[0].rm_eo) search_start++; } /* * Copy the text to the right of the last match. */ if (data_pos < data_len) { int chunk_len; chunk_len = ((char *) src_text + VARSIZE_ANY(src_text)) - start_ptr; appendBinaryStringInfo(&buf, start_ptr, chunk_len); } ret_text = cstring_to_text_with_len(buf.data, buf.len); pfree(buf.data); pfree(data); return ret_text; } /* * split_part * parse input string based on provided field separator * return N'th item (1 based, negative counts from end) */ Datum split_part(PG_FUNCTION_ARGS) { text *inputstring = PG_GETARG_TEXT_PP(0); text *fldsep = PG_GETARG_TEXT_PP(1); int fldnum = PG_GETARG_INT32(2); int inputstring_len; int fldsep_len; TextPositionState state; char *start_ptr; char *end_ptr; text *result_text; bool found; /* field number is 1 based */ if (fldnum == 0) ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("field position must not be zero"))); inputstring_len = VARSIZE_ANY_EXHDR(inputstring); fldsep_len = VARSIZE_ANY_EXHDR(fldsep); /* return empty string for empty input string */ if (inputstring_len < 1) PG_RETURN_TEXT_P(cstring_to_text("")); /* handle empty field separator */ if (fldsep_len < 1) { /* if first or last field, return input string, else empty string */ if (fldnum == 1 || fldnum == -1) PG_RETURN_TEXT_P(inputstring); else PG_RETURN_TEXT_P(cstring_to_text("")); } /* find the first field separator */ text_position_setup(inputstring, fldsep, PG_GET_COLLATION(), &state); found = text_position_next(&state); /* special case if fldsep not found at all */ if (!found) { text_position_cleanup(&state); /* if first or last field, return input string, else empty string */ if (fldnum == 1 || fldnum == -1) PG_RETURN_TEXT_P(inputstring); else PG_RETURN_TEXT_P(cstring_to_text("")); } /* * take care of a negative field number (i.e. count from the right) by * converting to a positive field number; we need total number of fields */ if (fldnum < 0) { /* we found a fldsep, so there are at least two fields */ int numfields = 2; while (text_position_next(&state)) numfields++; /* special case of last field does not require an extra pass */ if (fldnum == -1) { start_ptr = text_position_get_match_ptr(&state) + fldsep_len; end_ptr = VARDATA_ANY(inputstring) + inputstring_len; text_position_cleanup(&state); PG_RETURN_TEXT_P(cstring_to_text_with_len(start_ptr, end_ptr - start_ptr)); } /* else, convert fldnum to positive notation */ fldnum += numfields + 1; /* if nonexistent field, return empty string */ if (fldnum <= 0) { text_position_cleanup(&state); PG_RETURN_TEXT_P(cstring_to_text("")); } /* reset to pointing at first match, but now with positive fldnum */ text_position_reset(&state); found = text_position_next(&state); Assert(found); } /* identify bounds of first field */ start_ptr = VARDATA_ANY(inputstring); end_ptr = text_position_get_match_ptr(&state); while (found && --fldnum > 0) { /* identify bounds of next field */ start_ptr = end_ptr + fldsep_len; found = text_position_next(&state); if (found) end_ptr = text_position_get_match_ptr(&state); } text_position_cleanup(&state); if (fldnum > 0) { /* N'th field separator not found */ /* if last field requested, return it, else empty string */ if (fldnum == 1) { int last_len = start_ptr - VARDATA_ANY(inputstring); result_text = cstring_to_text_with_len(start_ptr, inputstring_len - last_len); } else result_text = cstring_to_text(""); } else { /* non-last field requested */ result_text = cstring_to_text_with_len(start_ptr, end_ptr - start_ptr); } PG_RETURN_TEXT_P(result_text); } /* * Convenience function to return true when two text params are equal. */ static bool text_isequal(text *txt1, text *txt2, Oid collid) { return DatumGetBool(DirectFunctionCall2Coll(texteq, collid, PointerGetDatum(txt1), PointerGetDatum(txt2))); } /* * text_to_array * parse input string and return text array of elements, * based on provided field separator */ Datum text_to_array(PG_FUNCTION_ARGS) { SplitTextOutputData tstate; /* For array output, tstate should start as all zeroes */ memset(&tstate, 0, sizeof(tstate)); if (!split_text(fcinfo, &tstate)) PG_RETURN_NULL(); if (tstate.astate == NULL) PG_RETURN_ARRAYTYPE_P(construct_empty_array(TEXTOID)); PG_RETURN_ARRAYTYPE_P(makeArrayResult(tstate.astate, CurrentMemoryContext)); } /* * text_to_array_null * parse input string and return text array of elements, * based on provided field separator and null string * * This is a separate entry point only to prevent the regression tests from * complaining about different argument sets for the same internal function. */ Datum text_to_array_null(PG_FUNCTION_ARGS) { return text_to_array(fcinfo); } /* * text_to_table * parse input string and return table of elements, * based on provided field separator */ Datum text_to_table(PG_FUNCTION_ARGS) { ReturnSetInfo *rsi = (ReturnSetInfo *) fcinfo->resultinfo; SplitTextOutputData tstate; MemoryContext old_cxt; /* check to see if caller supports us returning a tuplestore */ if (rsi == NULL || !IsA(rsi, ReturnSetInfo)) ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), errmsg("set-valued function called in context that cannot accept a set"))); if (!(rsi->allowedModes & SFRM_Materialize)) ereport(ERROR, (errcode(ERRCODE_FEATURE_NOT_SUPPORTED), errmsg("materialize mode required, but it is not allowed in this context"))); /* OK, prepare tuplestore in per-query memory */ old_cxt = MemoryContextSwitchTo(rsi->econtext->ecxt_per_query_memory); tstate.astate = NULL; tstate.tupdesc = CreateTupleDescCopy(rsi->expectedDesc); tstate.tupstore = tuplestore_begin_heap(true, false, work_mem); MemoryContextSwitchTo(old_cxt); (void) split_text(fcinfo, &tstate); tuplestore_donestoring(tstate.tupstore); rsi->returnMode = SFRM_Materialize; rsi->setResult = tstate.tupstore; rsi->setDesc = tstate.tupdesc; return (Datum) 0; } /* * text_to_table_null * parse input string and return table of elements, * based on provided field separator and null string * * This is a separate entry point only to prevent the regression tests from * complaining about different argument sets for the same internal function. */ Datum text_to_table_null(PG_FUNCTION_ARGS) { return text_to_table(fcinfo); } /* * Common code for text_to_array, text_to_array_null, text_to_table * and text_to_table_null functions. * * These are not strict so we have to test for null inputs explicitly. * Returns false if result is to be null, else returns true. * * Note that if the result is valid but empty (zero elements), we return * without changing *tstate --- caller must handle that case, too. */ static bool split_text(FunctionCallInfo fcinfo, SplitTextOutputData *tstate) { text *inputstring; text *fldsep; text *null_string; Oid collation = PG_GET_COLLATION(); int inputstring_len; int fldsep_len; char *start_ptr; text *result_text; /* when input string is NULL, then result is NULL too */ if (PG_ARGISNULL(0)) return false; inputstring = PG_GETARG_TEXT_PP(0); /* fldsep can be NULL */ if (!PG_ARGISNULL(1)) fldsep = PG_GETARG_TEXT_PP(1); else fldsep = NULL; /* null_string can be NULL or omitted */ if (PG_NARGS() > 2 && !PG_ARGISNULL(2)) null_string = PG_GETARG_TEXT_PP(2); else null_string = NULL; if (fldsep != NULL) { /* * Normal case with non-null fldsep. Use the text_position machinery * to search for occurrences of fldsep. */ TextPositionState state; inputstring_len = VARSIZE_ANY_EXHDR(inputstring); fldsep_len = VARSIZE_ANY_EXHDR(fldsep); /* return empty set for empty input string */ if (inputstring_len < 1) return true; /* empty field separator: return input string as a one-element set */ if (fldsep_len < 1) { split_text_accum_result(tstate, inputstring, null_string, collation); return true; } text_position_setup(inputstring, fldsep, collation, &state); start_ptr = VARDATA_ANY(inputstring); for (;;) { bool found; char *end_ptr; int chunk_len; CHECK_FOR_INTERRUPTS(); found = text_position_next(&state); if (!found) { /* fetch last field */ chunk_len = ((char *) inputstring + VARSIZE_ANY(inputstring)) - start_ptr; end_ptr = NULL; /* not used, but some compilers complain */ } else { /* fetch non-last field */ end_ptr = text_position_get_match_ptr(&state); chunk_len = end_ptr - start_ptr; } /* build a temp text datum to pass to split_text_accum_result */ result_text = cstring_to_text_with_len(start_ptr, chunk_len); /* stash away this field */ split_text_accum_result(tstate, result_text, null_string, collation); pfree(result_text); if (!found) break; start_ptr = end_ptr + fldsep_len; } text_position_cleanup(&state); } else { /* * When fldsep is NULL, each character in the input string becomes a * separate element in the result set. The separator is effectively * the space between characters. */ inputstring_len = VARSIZE_ANY_EXHDR(inputstring); start_ptr = VARDATA_ANY(inputstring); while (inputstring_len > 0) { int chunk_len = pg_mblen(start_ptr); CHECK_FOR_INTERRUPTS(); /* build a temp text datum to pass to split_text_accum_result */ result_text = cstring_to_text_with_len(start_ptr, chunk_len); /* stash away this field */ split_text_accum_result(tstate, result_text, null_string, collation); pfree(result_text); start_ptr += chunk_len; inputstring_len -= chunk_len; } } return true; } /* * Add text item to result set (table or array). * * This is also responsible for checking to see if the item matches * the null_string, in which case we should emit NULL instead. */ static void split_text_accum_result(SplitTextOutputData *tstate, text *field_value, text *null_string, Oid collation) { bool is_null = false; if (null_string && text_isequal(field_value, null_string, collation)) is_null = true; if (tstate->tupstore) { Datum values[1]; bool nulls[1]; values[0] = PointerGetDatum(field_value); nulls[0] = is_null; tuplestore_putvalues(tstate->tupstore, tstate->tupdesc, values, nulls); } else { tstate->astate = accumArrayResult(tstate->astate, PointerGetDatum(field_value), is_null, TEXTOID, CurrentMemoryContext); } } /* * array_to_text * concatenate Cstring representation of input array elements * using provided field separator */ Datum array_to_text(PG_FUNCTION_ARGS) { ArrayType *v = PG_GETARG_ARRAYTYPE_P(0); char *fldsep = text_to_cstring(PG_GETARG_TEXT_PP(1)); PG_RETURN_TEXT_P(array_to_text_internal(fcinfo, v, fldsep, NULL)); } /* * array_to_text_null * concatenate Cstring representation of input array elements * using provided field separator and null string * * This version is not strict so we have to test for null inputs explicitly. */ Datum array_to_text_null(PG_FUNCTION_ARGS) { ArrayType *v; char *fldsep; char *null_string; /* returns NULL when first or second parameter is NULL */ if (PG_ARGISNULL(0) || PG_ARGISNULL(1)) PG_RETURN_NULL(); v = PG_GETARG_ARRAYTYPE_P(0); fldsep = text_to_cstring(PG_GETARG_TEXT_PP(1)); /* NULL null string is passed through as a null pointer */ if (!PG_ARGISNULL(2)) null_string = text_to_cstring(PG_GETARG_TEXT_PP(2)); else null_string = NULL; PG_RETURN_TEXT_P(array_to_text_internal(fcinfo, v, fldsep, null_string)); } /* * common code for array_to_text and array_to_text_null functions */ static text * array_to_text_internal(FunctionCallInfo fcinfo, ArrayType *v, const char *fldsep, const char *null_string) { text *result; int nitems, *dims, ndims; Oid element_type; int typlen; bool typbyval; char typalign; StringInfoData buf; bool printed = false; char *p; bits8 *bitmap; int bitmask; int i; ArrayMetaState *my_extra; ndims = ARR_NDIM(v); dims = ARR_DIMS(v); nitems = ArrayGetNItems(ndims, dims); /* if there are no elements, return an empty string */ if (nitems == 0) return cstring_to_text_with_len("", 0); element_type = ARR_ELEMTYPE(v); initStringInfo(&buf); /* * We arrange to look up info about element type, including its output * conversion proc, only once per series of calls, assuming the element * type doesn't change underneath us. */ my_extra = (ArrayMetaState *) fcinfo->flinfo->fn_extra; if (my_extra == NULL) { fcinfo->flinfo->fn_extra = MemoryContextAlloc(fcinfo->flinfo->fn_mcxt, sizeof(ArrayMetaState)); my_extra = (ArrayMetaState *) fcinfo->flinfo->fn_extra; my_extra->element_type = ~element_type; } if (my_extra->element_type != element_type) { /* * Get info about element type, including its output conversion proc */ get_type_io_data(element_type, IOFunc_output, &my_extra->typlen, &my_extra->typbyval, &my_extra->typalign, &my_extra->typdelim, &my_extra->typioparam, &my_extra->typiofunc); fmgr_info_cxt(my_extra->typiofunc, &my_extra->proc, fcinfo->flinfo->fn_mcxt); my_extra->element_type = element_type; } typlen = my_extra->typlen; typbyval = my_extra->typbyval; typalign = my_extra->typalign; p = ARR_DATA_PTR(v); bitmap = ARR_NULLBITMAP(v); bitmask = 1; for (i = 0; i < nitems; i++) { Datum itemvalue; char *value; /* Get source element, checking for NULL */ if (bitmap && (*bitmap & bitmask) == 0) { /* if null_string is NULL, we just ignore null elements */ if (null_string != NULL) { if (printed) appendStringInfo(&buf, "%s%s", fldsep, null_string); else appendStringInfoString(&buf, null_string); printed = true; } } else { itemvalue = fetch_att(p, typbyval, typlen); value = OutputFunctionCall(&my_extra->proc, itemvalue); if (printed) appendStringInfo(&buf, "%s%s", fldsep, value); else appendStringInfoString(&buf, value); printed = true; p = att_addlength_pointer(p, typlen, p); p = (char *) att_align_nominal(p, typalign); } /* advance bitmap pointer if any */ if (bitmap) { bitmask <<= 1; if (bitmask == 0x100) { bitmap++; bitmask = 1; } } } result = cstring_to_text_with_len(buf.data, buf.len); pfree(buf.data); return result; } #define HEXBASE 16 /* * Convert an int32 to a string containing a base 16 (hex) representation of * the number. */ Datum to_hex32(PG_FUNCTION_ARGS) { uint32 value = (uint32) PG_GETARG_INT32(0); char *ptr; const char *digits = "0123456789abcdef"; char buf[32]; /* bigger than needed, but reasonable */ ptr = buf + sizeof(buf) - 1; *ptr = '\0'; do { *--ptr = digits[value % HEXBASE]; value /= HEXBASE; } while (ptr > buf && value); PG_RETURN_TEXT_P(cstring_to_text(ptr)); } /* * Convert an int64 to a string containing a base 16 (hex) representation of * the number. */ Datum to_hex64(PG_FUNCTION_ARGS) { uint64 value = (uint64) PG_GETARG_INT64(0); char *ptr; const char *digits = "0123456789abcdef"; char buf[32]; /* bigger than needed, but reasonable */ ptr = buf + sizeof(buf) - 1; *ptr = '\0'; do { *--ptr = digits[value % HEXBASE]; value /= HEXBASE; } while (ptr > buf && value); PG_RETURN_TEXT_P(cstring_to_text(ptr)); } /* * Return the size of a datum, possibly compressed * * Works on any data type */ Datum pg_column_size(PG_FUNCTION_ARGS) { Datum value = PG_GETARG_DATUM(0); int32 result; int typlen; /* On first call, get the input type's typlen, and save at *fn_extra */ if (fcinfo->flinfo->fn_extra == NULL) { /* Lookup the datatype of the supplied argument */ Oid argtypeid = get_fn_expr_argtype(fcinfo->flinfo, 0); typlen = get_typlen(argtypeid); if (typlen == 0) /* should not happen */ elog(ERROR, "cache lookup failed for type %u", argtypeid); fcinfo->flinfo->fn_extra = MemoryContextAlloc(fcinfo->flinfo->fn_mcxt, sizeof(int)); *((int *) fcinfo->flinfo->fn_extra) = typlen; } else typlen = *((int *) fcinfo->flinfo->fn_extra); if (typlen == -1) { /* varlena type, possibly toasted */ result = toast_datum_size(value); } else if (typlen == -2) { /* cstring */ result = strlen(DatumGetCString(value)) + 1; } else { /* ordinary fixed-width type */ result = typlen; } PG_RETURN_INT32(result); } /* * Return the compression method stored in the compressed attribute. Return * NULL for non varlena type or uncompressed data. */ Datum pg_column_compression(PG_FUNCTION_ARGS) { int typlen; char *result; ToastCompressionId cmid; /* On first call, get the input type's typlen, and save at *fn_extra */ if (fcinfo->flinfo->fn_extra == NULL) { /* Lookup the datatype of the supplied argument */ Oid argtypeid = get_fn_expr_argtype(fcinfo->flinfo, 0); typlen = get_typlen(argtypeid); if (typlen == 0) /* should not happen */ elog(ERROR, "cache lookup failed for type %u", argtypeid); fcinfo->flinfo->fn_extra = MemoryContextAlloc(fcinfo->flinfo->fn_mcxt, sizeof(int)); *((int *) fcinfo->flinfo->fn_extra) = typlen; } else typlen = *((int *) fcinfo->flinfo->fn_extra); if (typlen != -1) PG_RETURN_NULL(); /* get the compression method id stored in the compressed varlena */ cmid = toast_get_compression_id((struct varlena *) DatumGetPointer(PG_GETARG_DATUM(0))); if (cmid == TOAST_INVALID_COMPRESSION_ID) PG_RETURN_NULL(); /* convert compression method id to compression method name */ switch (cmid) { case TOAST_PGLZ_COMPRESSION_ID: result = "pglz"; break; case TOAST_LZ4_COMPRESSION_ID: result = "lz4"; break; default: elog(ERROR, "invalid compression method id %d", cmid); } PG_RETURN_TEXT_P(cstring_to_text(result)); } /* * string_agg - Concatenates values and returns string. * * Syntax: string_agg(value text, delimiter text) RETURNS text * * Note: Any NULL values are ignored. The first-call delimiter isn't * actually used at all, and on subsequent calls the delimiter precedes * the associated value. */ /* subroutine to initialize state */ static StringInfo makeStringAggState(FunctionCallInfo fcinfo) { StringInfo state; MemoryContext aggcontext; MemoryContext oldcontext; if (!AggCheckCallContext(fcinfo, &aggcontext)) { /* cannot be called directly because of internal-type argument */ elog(ERROR, "string_agg_transfn called in non-aggregate context"); } /* * Create state in aggregate context. It'll stay there across subsequent * calls. */ oldcontext = MemoryContextSwitchTo(aggcontext); state = makeStringInfo(); MemoryContextSwitchTo(oldcontext); return state; } Datum string_agg_transfn(PG_FUNCTION_ARGS) { StringInfo state; state = PG_ARGISNULL(0) ? NULL : (StringInfo) PG_GETARG_POINTER(0); /* Append the value unless null. */ if (!PG_ARGISNULL(1)) { /* On the first time through, we ignore the delimiter. */ if (state == NULL) state = makeStringAggState(fcinfo); else if (!PG_ARGISNULL(2)) appendStringInfoText(state, PG_GETARG_TEXT_PP(2)); /* delimiter */ appendStringInfoText(state, PG_GETARG_TEXT_PP(1)); /* value */ } /* * The transition type for string_agg() is declared to be "internal", * which is a pass-by-value type the same size as a pointer. */ PG_RETURN_POINTER(state); } Datum string_agg_finalfn(PG_FUNCTION_ARGS) { StringInfo state; /* cannot be called directly because of internal-type argument */ Assert(AggCheckCallContext(fcinfo, NULL)); state = PG_ARGISNULL(0) ? NULL : (StringInfo) PG_GETARG_POINTER(0); if (state != NULL) PG_RETURN_TEXT_P(cstring_to_text_with_len(state->data, state->len)); else PG_RETURN_NULL(); } /* * Prepare cache with fmgr info for the output functions of the datatypes of * the arguments of a concat-like function, beginning with argument "argidx". * (Arguments before that will have corresponding slots in the resulting * FmgrInfo array, but we don't fill those slots.) */ static FmgrInfo * build_concat_foutcache(FunctionCallInfo fcinfo, int argidx) { FmgrInfo *foutcache; int i; /* We keep the info in fn_mcxt so it survives across calls */ foutcache = (FmgrInfo *) MemoryContextAlloc(fcinfo->flinfo->fn_mcxt, PG_NARGS() * sizeof(FmgrInfo)); for (i = argidx; i < PG_NARGS(); i++) { Oid valtype; Oid typOutput; bool typIsVarlena; valtype = get_fn_expr_argtype(fcinfo->flinfo, i); if (!OidIsValid(valtype)) elog(ERROR, "could not determine data type of concat() input"); getTypeOutputInfo(valtype, &typOutput, &typIsVarlena); fmgr_info_cxt(typOutput, &foutcache[i], fcinfo->flinfo->fn_mcxt); } fcinfo->flinfo->fn_extra = foutcache; return foutcache; } /* * Implementation of both concat() and concat_ws(). * * sepstr is the separator string to place between values. * argidx identifies the first argument to concatenate (counting from zero); * note that this must be constant across any one series of calls. * * Returns NULL if result should be NULL, else text value. */ static text * concat_internal(const char *sepstr, int argidx, FunctionCallInfo fcinfo) { text *result; StringInfoData str; FmgrInfo *foutcache; bool first_arg = true; int i; /* * concat(VARIADIC some-array) is essentially equivalent to * array_to_text(), ie concat the array elements with the given separator. * So we just pass the case off to that code. */ if (get_fn_expr_variadic(fcinfo->flinfo)) { ArrayType *arr; /* Should have just the one argument */ Assert(argidx == PG_NARGS() - 1); /* concat(VARIADIC NULL) is defined as NULL */ if (PG_ARGISNULL(argidx)) return NULL; /* * Non-null argument had better be an array. We assume that any call * context that could let get_fn_expr_variadic return true will have * checked that a VARIADIC-labeled parameter actually is an array. So * it should be okay to just Assert that it's an array rather than * doing a full-fledged error check. */ Assert(OidIsValid(get_base_element_type(get_fn_expr_argtype(fcinfo->flinfo, argidx)))); /* OK, safe to fetch the array value */ arr = PG_GETARG_ARRAYTYPE_P(argidx); /* * And serialize the array. We tell array_to_text to ignore null * elements, which matches the behavior of the loop below. */ return array_to_text_internal(fcinfo, arr, sepstr, NULL); } /* Normal case without explicit VARIADIC marker */ initStringInfo(&str); /* Get output function info, building it if first time through */ foutcache = (FmgrInfo *) fcinfo->flinfo->fn_extra; if (foutcache == NULL) foutcache = build_concat_foutcache(fcinfo, argidx); for (i = argidx; i < PG_NARGS(); i++) { if (!PG_ARGISNULL(i)) { Datum value = PG_GETARG_DATUM(i); /* add separator if appropriate */ if (first_arg) first_arg = false; else appendStringInfoString(&str, sepstr); /* call the appropriate type output function, append the result */ appendStringInfoString(&str, OutputFunctionCall(&foutcache[i], value)); } } result = cstring_to_text_with_len(str.data, str.len); pfree(str.data); return result; } /* * Concatenate all arguments. NULL arguments are ignored. */ Datum text_concat(PG_FUNCTION_ARGS) { text *result; result = concat_internal("", 0, fcinfo); if (result == NULL) PG_RETURN_NULL(); PG_RETURN_TEXT_P(result); } /* * Concatenate all but first argument value with separators. The first * parameter is used as the separator. NULL arguments are ignored. */ Datum text_concat_ws(PG_FUNCTION_ARGS) { char *sep; text *result; /* return NULL when separator is NULL */ if (PG_ARGISNULL(0)) PG_RETURN_NULL(); sep = text_to_cstring(PG_GETARG_TEXT_PP(0)); result = concat_internal(sep, 1, fcinfo); if (result == NULL) PG_RETURN_NULL(); PG_RETURN_TEXT_P(result); } /* * Return first n characters in the string. When n is negative, * return all but last |n| characters. */ Datum text_left(PG_FUNCTION_ARGS) { int n = PG_GETARG_INT32(1); if (n < 0) { text *str = PG_GETARG_TEXT_PP(0); const char *p = VARDATA_ANY(str); int len = VARSIZE_ANY_EXHDR(str); int rlen; n = pg_mbstrlen_with_len(p, len) + n; rlen = pg_mbcharcliplen(p, len, n); PG_RETURN_TEXT_P(cstring_to_text_with_len(p, rlen)); } else PG_RETURN_TEXT_P(text_substring(PG_GETARG_DATUM(0), 1, n, false)); } /* * Return last n characters in the string. When n is negative, * return all but first |n| characters. */ Datum text_right(PG_FUNCTION_ARGS) { text *str = PG_GETARG_TEXT_PP(0); const char *p = VARDATA_ANY(str); int len = VARSIZE_ANY_EXHDR(str); int n = PG_GETARG_INT32(1); int off; if (n < 0) n = -n; else n = pg_mbstrlen_with_len(p, len) - n; off = pg_mbcharcliplen(p, len, n); PG_RETURN_TEXT_P(cstring_to_text_with_len(p + off, len - off)); } /* * Return reversed string */ Datum text_reverse(PG_FUNCTION_ARGS) { text *str = PG_GETARG_TEXT_PP(0); const char *p = VARDATA_ANY(str); int len = VARSIZE_ANY_EXHDR(str); const char *endp = p + len; text *result; char *dst; result = palloc(len + VARHDRSZ); dst = (char *) VARDATA(result) + len; SET_VARSIZE(result, len + VARHDRSZ); if (pg_database_encoding_max_length() > 1) { /* multibyte version */ while (p < endp) { int sz; sz = pg_mblen(p); dst -= sz; memcpy(dst, p, sz); p += sz; } } else { /* single byte version */ while (p < endp) *(--dst) = *p++; } PG_RETURN_TEXT_P(result); } /* * Support macros for text_format() */ #define TEXT_FORMAT_FLAG_MINUS 0x0001 /* is minus flag present? */ #define ADVANCE_PARSE_POINTER(ptr,end_ptr) \ do { \ if (++(ptr) >= (end_ptr)) \ ereport(ERROR, \ (errcode(ERRCODE_INVALID_PARAMETER_VALUE), \ errmsg("unterminated format() type specifier"), \ errhint("For a single \"%%\" use \"%%%%\"."))); \ } while (0) /* * Returns a formatted string */ Datum text_format(PG_FUNCTION_ARGS) { text *fmt; StringInfoData str; const char *cp; const char *start_ptr; const char *end_ptr; text *result; int arg; bool funcvariadic; int nargs; Datum *elements = NULL; bool *nulls = NULL; Oid element_type = InvalidOid; Oid prev_type = InvalidOid; Oid prev_width_type = InvalidOid; FmgrInfo typoutputfinfo; FmgrInfo typoutputinfo_width; /* When format string is null, immediately return null */ if (PG_ARGISNULL(0)) PG_RETURN_NULL(); /* If argument is marked VARIADIC, expand array into elements */ if (get_fn_expr_variadic(fcinfo->flinfo)) { ArrayType *arr; int16 elmlen; bool elmbyval; char elmalign; int nitems; /* Should have just the one argument */ Assert(PG_NARGS() == 2); /* If argument is NULL, we treat it as zero-length array */ if (PG_ARGISNULL(1)) nitems = 0; else { /* * Non-null argument had better be an array. We assume that any * call context that could let get_fn_expr_variadic return true * will have checked that a VARIADIC-labeled parameter actually is * an array. So it should be okay to just Assert that it's an * array rather than doing a full-fledged error check. */ Assert(OidIsValid(get_base_element_type(get_fn_expr_argtype(fcinfo->flinfo, 1)))); /* OK, safe to fetch the array value */ arr = PG_GETARG_ARRAYTYPE_P(1); /* Get info about array element type */ element_type = ARR_ELEMTYPE(arr); get_typlenbyvalalign(element_type, &elmlen, &elmbyval, &elmalign); /* Extract all array elements */ deconstruct_array(arr, element_type, elmlen, elmbyval, elmalign, &elements, &nulls, &nitems); } nargs = nitems + 1; funcvariadic = true; } else { /* Non-variadic case, we'll process the arguments individually */ nargs = PG_NARGS(); funcvariadic = false; } /* Setup for main loop. */ fmt = PG_GETARG_TEXT_PP(0); start_ptr = VARDATA_ANY(fmt); end_ptr = start_ptr + VARSIZE_ANY_EXHDR(fmt); initStringInfo(&str); arg = 1; /* next argument position to print */ /* Scan format string, looking for conversion specifiers. */ for (cp = start_ptr; cp < end_ptr; cp++) { int argpos; int widthpos; int flags; int width; Datum value; bool isNull; Oid typid; /* * If it's not the start of a conversion specifier, just copy it to * the output buffer. */ if (*cp != '%') { appendStringInfoCharMacro(&str, *cp); continue; } ADVANCE_PARSE_POINTER(cp, end_ptr); /* Easy case: %% outputs a single % */ if (*cp == '%') { appendStringInfoCharMacro(&str, *cp); continue; } /* Parse the optional portions of the format specifier */ cp = text_format_parse_format(cp, end_ptr, &argpos, &widthpos, &flags, &width); /* * Next we should see the main conversion specifier. Whether or not * an argument position was present, it's known that at least one * character remains in the string at this point. Experience suggests * that it's worth checking that that character is one of the expected * ones before we try to fetch arguments, so as to produce the least * confusing response to a mis-formatted specifier. */ if (strchr("sIL", *cp) == NULL) ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("unrecognized format() type specifier \"%.*s\"", pg_mblen(cp), cp), errhint("For a single \"%%\" use \"%%%%\"."))); /* If indirect width was specified, get its value */ if (widthpos >= 0) { /* Collect the specified or next argument position */ if (widthpos > 0) arg = widthpos; if (arg >= nargs) ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("too few arguments for format()"))); /* Get the value and type of the selected argument */ if (!funcvariadic) { value = PG_GETARG_DATUM(arg); isNull = PG_ARGISNULL(arg); typid = get_fn_expr_argtype(fcinfo->flinfo, arg); } else { value = elements[arg - 1]; isNull = nulls[arg - 1]; typid = element_type; } if (!OidIsValid(typid)) elog(ERROR, "could not determine data type of format() input"); arg++; /* We can treat NULL width the same as zero */ if (isNull) width = 0; else if (typid == INT4OID) width = DatumGetInt32(value); else if (typid == INT2OID) width = DatumGetInt16(value); else { /* For less-usual datatypes, convert to text then to int */ char *str; if (typid != prev_width_type) { Oid typoutputfunc; bool typIsVarlena; getTypeOutputInfo(typid, &typoutputfunc, &typIsVarlena); fmgr_info(typoutputfunc, &typoutputinfo_width); prev_width_type = typid; } str = OutputFunctionCall(&typoutputinfo_width, value); /* pg_strtoint32 will complain about bad data or overflow */ width = pg_strtoint32(str); pfree(str); } } /* Collect the specified or next argument position */ if (argpos > 0) arg = argpos; if (arg >= nargs) ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("too few arguments for format()"))); /* Get the value and type of the selected argument */ if (!funcvariadic) { value = PG_GETARG_DATUM(arg); isNull = PG_ARGISNULL(arg); typid = get_fn_expr_argtype(fcinfo->flinfo, arg); } else { value = elements[arg - 1]; isNull = nulls[arg - 1]; typid = element_type; } if (!OidIsValid(typid)) elog(ERROR, "could not determine data type of format() input"); arg++; /* * Get the appropriate typOutput function, reusing previous one if * same type as previous argument. That's particularly useful in the * variadic-array case, but often saves work even for ordinary calls. */ if (typid != prev_type) { Oid typoutputfunc; bool typIsVarlena; getTypeOutputInfo(typid, &typoutputfunc, &typIsVarlena); fmgr_info(typoutputfunc, &typoutputfinfo); prev_type = typid; } /* * And now we can format the value. */ switch (*cp) { case 's': case 'I': case 'L': text_format_string_conversion(&str, *cp, &typoutputfinfo, value, isNull, flags, width); break; default: /* should not get here, because of previous check */ ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("unrecognized format() type specifier \"%.*s\"", pg_mblen(cp), cp), errhint("For a single \"%%\" use \"%%%%\"."))); break; } } /* Don't need deconstruct_array results anymore. */ if (elements != NULL) pfree(elements); if (nulls != NULL) pfree(nulls); /* Generate results. */ result = cstring_to_text_with_len(str.data, str.len); pfree(str.data); PG_RETURN_TEXT_P(result); } /* * Parse contiguous digits as a decimal number. * * Returns true if some digits could be parsed. * The value is returned into *value, and *ptr is advanced to the next * character to be parsed. * * Note parsing invariant: at least one character is known available before * string end (end_ptr) at entry, and this is still true at exit. */ static bool text_format_parse_digits(const char **ptr, const char *end_ptr, int *value) { bool found = false; const char *cp = *ptr; int val = 0; while (*cp >= '0' && *cp <= '9') { int8 digit = (*cp - '0'); if (unlikely(pg_mul_s32_overflow(val, 10, &val)) || unlikely(pg_add_s32_overflow(val, digit, &val))) ereport(ERROR, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("number is out of range"))); ADVANCE_PARSE_POINTER(cp, end_ptr); found = true; } *ptr = cp; *value = val; return found; } /* * Parse a format specifier (generally following the SUS printf spec). * * We have already advanced over the initial '%', and we are looking for * [argpos][flags][width]type (but the type character is not consumed here). * * Inputs are start_ptr (the position after '%') and end_ptr (string end + 1). * Output parameters: * argpos: argument position for value to be printed. -1 means unspecified. * widthpos: argument position for width. Zero means the argument position * was unspecified (ie, take the next arg) and -1 means no width * argument (width was omitted or specified as a constant). * flags: bitmask of flags. * width: directly-specified width value. Zero means the width was omitted * (note it's not necessary to distinguish this case from an explicit * zero width value). * * The function result is the next character position to be parsed, ie, the * location where the type character is/should be. * * Note parsing invariant: at least one character is known available before * string end (end_ptr) at entry, and this is still true at exit. */ static const char * text_format_parse_format(const char *start_ptr, const char *end_ptr, int *argpos, int *widthpos, int *flags, int *width) { const char *cp = start_ptr; int n; /* set defaults for output parameters */ *argpos = -1; *widthpos = -1; *flags = 0; *width = 0; /* try to identify first number */ if (text_format_parse_digits(&cp, end_ptr, &n)) { if (*cp != '$') { /* Must be just a width and a type, so we're done */ *width = n; return cp; } /* The number was argument position */ *argpos = n; /* Explicit 0 for argument index is immediately refused */ if (n == 0) ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("format specifies argument 0, but arguments are numbered from 1"))); ADVANCE_PARSE_POINTER(cp, end_ptr); } /* Handle flags (only minus is supported now) */ while (*cp == '-') { *flags |= TEXT_FORMAT_FLAG_MINUS; ADVANCE_PARSE_POINTER(cp, end_ptr); } if (*cp == '*') { /* Handle indirect width */ ADVANCE_PARSE_POINTER(cp, end_ptr); if (text_format_parse_digits(&cp, end_ptr, &n)) { /* number in this position must be closed by $ */ if (*cp != '$') ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("width argument position must be ended by \"$\""))); /* The number was width argument position */ *widthpos = n; /* Explicit 0 for argument index is immediately refused */ if (n == 0) ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("format specifies argument 0, but arguments are numbered from 1"))); ADVANCE_PARSE_POINTER(cp, end_ptr); } else *widthpos = 0; /* width's argument position is unspecified */ } else { /* Check for direct width specification */ if (text_format_parse_digits(&cp, end_ptr, &n)) *width = n; } /* cp should now be pointing at type character */ return cp; } /* * Format a %s, %I, or %L conversion */ static void text_format_string_conversion(StringInfo buf, char conversion, FmgrInfo *typOutputInfo, Datum value, bool isNull, int flags, int width) { char *str; /* Handle NULL arguments before trying to stringify the value. */ if (isNull) { if (conversion == 's') text_format_append_string(buf, "", flags, width); else if (conversion == 'L') text_format_append_string(buf, "NULL", flags, width); else if (conversion == 'I') ereport(ERROR, (errcode(ERRCODE_NULL_VALUE_NOT_ALLOWED), errmsg("null values cannot be formatted as an SQL identifier"))); return; } /* Stringify. */ str = OutputFunctionCall(typOutputInfo, value); /* Escape. */ if (conversion == 'I') { /* quote_identifier may or may not allocate a new string. */ text_format_append_string(buf, quote_identifier(str), flags, width); } else if (conversion == 'L') { char *qstr = quote_literal_cstr(str); text_format_append_string(buf, qstr, flags, width); /* quote_literal_cstr() always allocates a new string */ pfree(qstr); } else text_format_append_string(buf, str, flags, width); /* Cleanup. */ pfree(str); } /* * Append str to buf, padding as directed by flags/width */ static void text_format_append_string(StringInfo buf, const char *str, int flags, int width) { bool align_to_left = false; int len; /* fast path for typical easy case */ if (width == 0) { appendStringInfoString(buf, str); return; } if (width < 0) { /* Negative width: implicit '-' flag, then take absolute value */ align_to_left = true; /* -INT_MIN is undefined */ if (width <= INT_MIN) ereport(ERROR, (errcode(ERRCODE_NUMERIC_VALUE_OUT_OF_RANGE), errmsg("number is out of range"))); width = -width; } else if (flags & TEXT_FORMAT_FLAG_MINUS) align_to_left = true; len = pg_mbstrlen(str); if (align_to_left) { /* left justify */ appendStringInfoString(buf, str); if (len < width) appendStringInfoSpaces(buf, width - len); } else { /* right justify */ if (len < width) appendStringInfoSpaces(buf, width - len); appendStringInfoString(buf, str); } } /* * text_format_nv - nonvariadic wrapper for text_format function. * * note: this wrapper is necessary to pass the sanity check in opr_sanity, * which checks that all built-in functions that share the implementing C * function take the same number of arguments. */ Datum text_format_nv(PG_FUNCTION_ARGS) { return text_format(fcinfo); } /* * Helper function for Levenshtein distance functions. Faster than memcmp(), * for this use case. */ static inline bool rest_of_char_same(const char *s1, const char *s2, int len) { while (len > 0) { len--; if (s1[len] != s2[len]) return false; } return true; } /* Expand each Levenshtein distance variant */ #include "levenshtein.c" #define LEVENSHTEIN_LESS_EQUAL #include "levenshtein.c" /* * Unicode support */ static UnicodeNormalizationForm unicode_norm_form_from_string(const char *formstr) { UnicodeNormalizationForm form = -1; /* * Might as well check this while we're here. */ if (GetDatabaseEncoding() != PG_UTF8) ereport(ERROR, (errcode(ERRCODE_SYNTAX_ERROR), errmsg("Unicode normalization can only be performed if server encoding is UTF8"))); if (pg_strcasecmp(formstr, "NFC") == 0) form = UNICODE_NFC; else if (pg_strcasecmp(formstr, "NFD") == 0) form = UNICODE_NFD; else if (pg_strcasecmp(formstr, "NFKC") == 0) form = UNICODE_NFKC; else if (pg_strcasecmp(formstr, "NFKD") == 0) form = UNICODE_NFKD; else ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("invalid normalization form: %s", formstr))); return form; } Datum unicode_normalize_func(PG_FUNCTION_ARGS) { text *input = PG_GETARG_TEXT_PP(0); char *formstr = text_to_cstring(PG_GETARG_TEXT_PP(1)); UnicodeNormalizationForm form; int size; pg_wchar *input_chars; pg_wchar *output_chars; unsigned char *p; text *result; int i; form = unicode_norm_form_from_string(formstr); /* convert to pg_wchar */ size = pg_mbstrlen_with_len(VARDATA_ANY(input), VARSIZE_ANY_EXHDR(input)); input_chars = palloc((size + 1) * sizeof(pg_wchar)); p = (unsigned char *) VARDATA_ANY(input); for (i = 0; i < size; i++) { input_chars[i] = utf8_to_unicode(p); p += pg_utf_mblen(p); } input_chars[i] = (pg_wchar) '\0'; Assert((char *) p == VARDATA_ANY(input) + VARSIZE_ANY_EXHDR(input)); /* action */ output_chars = unicode_normalize(form, input_chars); /* convert back to UTF-8 string */ size = 0; for (pg_wchar *wp = output_chars; *wp; wp++) { unsigned char buf[4]; unicode_to_utf8(*wp, buf); size += pg_utf_mblen(buf); } result = palloc(size + VARHDRSZ); SET_VARSIZE(result, size + VARHDRSZ); p = (unsigned char *) VARDATA_ANY(result); for (pg_wchar *wp = output_chars; *wp; wp++) { unicode_to_utf8(*wp, p); p += pg_utf_mblen(p); } Assert((char *) p == (char *) result + size + VARHDRSZ); PG_RETURN_TEXT_P(result); } /* * Check whether the string is in the specified Unicode normalization form. * * This is done by converting the string to the specified normal form and then * comparing that to the original string. To speed that up, we also apply the * "quick check" algorithm specified in UAX #15, which can give a yes or no * answer for many strings by just scanning the string once. * * This function should generally be optimized for the case where the string * is in fact normalized. In that case, we'll end up looking at the entire * string, so it's probably not worth doing any incremental conversion etc. */ Datum unicode_is_normalized(PG_FUNCTION_ARGS) { text *input = PG_GETARG_TEXT_PP(0); char *formstr = text_to_cstring(PG_GETARG_TEXT_PP(1)); UnicodeNormalizationForm form; int size; pg_wchar *input_chars; pg_wchar *output_chars; unsigned char *p; int i; UnicodeNormalizationQC quickcheck; int output_size; bool result; form = unicode_norm_form_from_string(formstr); /* convert to pg_wchar */ size = pg_mbstrlen_with_len(VARDATA_ANY(input), VARSIZE_ANY_EXHDR(input)); input_chars = palloc((size + 1) * sizeof(pg_wchar)); p = (unsigned char *) VARDATA_ANY(input); for (i = 0; i < size; i++) { input_chars[i] = utf8_to_unicode(p); p += pg_utf_mblen(p); } input_chars[i] = (pg_wchar) '\0'; Assert((char *) p == VARDATA_ANY(input) + VARSIZE_ANY_EXHDR(input)); /* quick check (see UAX #15) */ quickcheck = unicode_is_normalized_quickcheck(form, input_chars); if (quickcheck == UNICODE_NORM_QC_YES) PG_RETURN_BOOL(true); else if (quickcheck == UNICODE_NORM_QC_NO) PG_RETURN_BOOL(false); /* normalize and compare with original */ output_chars = unicode_normalize(form, input_chars); output_size = 0; for (pg_wchar *wp = output_chars; *wp; wp++) output_size++; result = (size == output_size) && (memcmp(input_chars, output_chars, size * sizeof(pg_wchar)) == 0); PG_RETURN_BOOL(result); } /* * Check if first n chars are hexadecimal digits */ static bool isxdigits_n(const char *instr, size_t n) { for (size_t i = 0; i < n; i++) if (!isxdigit((unsigned char) instr[i])) return false; return true; } static unsigned int hexval(unsigned char c) { if (c >= '0' && c <= '9') return c - '0'; if (c >= 'a' && c <= 'f') return c - 'a' + 0xA; if (c >= 'A' && c <= 'F') return c - 'A' + 0xA; elog(ERROR, "invalid hexadecimal digit"); return 0; /* not reached */ } /* * Translate string with hexadecimal digits to number */ static unsigned int hexval_n(const char *instr, size_t n) { unsigned int result = 0; for (size_t i = 0; i < n; i++) result += hexval(instr[i]) << (4 * (n - i - 1)); return result; } /* * Replaces Unicode escape sequences by Unicode characters */ Datum unistr(PG_FUNCTION_ARGS) { text *input_text = PG_GETARG_TEXT_PP(0); char *instr; int len; StringInfoData str; text *result; pg_wchar pair_first = 0; char cbuf[MAX_UNICODE_EQUIVALENT_STRING + 1]; instr = VARDATA_ANY(input_text); len = VARSIZE_ANY_EXHDR(input_text); initStringInfo(&str); while (len > 0) { if (instr[0] == '\\') { if (len >= 2 && instr[1] == '\\') { if (pair_first) goto invalid_pair; appendStringInfoChar(&str, '\\'); instr += 2; len -= 2; } else if ((len >= 5 && isxdigits_n(instr + 1, 4)) || (len >= 6 && instr[1] == 'u' && isxdigits_n(instr + 2, 4))) { pg_wchar unicode; int offset = instr[1] == 'u' ? 2 : 1; unicode = hexval_n(instr + offset, 4); if (!is_valid_unicode_codepoint(unicode)) ereport(ERROR, errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("invalid Unicode code point: %04X", unicode)); if (pair_first) { if (is_utf16_surrogate_second(unicode)) { unicode = surrogate_pair_to_codepoint(pair_first, unicode); pair_first = 0; } else goto invalid_pair; } else if (is_utf16_surrogate_second(unicode)) goto invalid_pair; if (is_utf16_surrogate_first(unicode)) pair_first = unicode; else { pg_unicode_to_server(unicode, (unsigned char *) cbuf); appendStringInfoString(&str, cbuf); } instr += 4 + offset; len -= 4 + offset; } else if (len >= 8 && instr[1] == '+' && isxdigits_n(instr + 2, 6)) { pg_wchar unicode; unicode = hexval_n(instr + 2, 6); if (!is_valid_unicode_codepoint(unicode)) ereport(ERROR, errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("invalid Unicode code point: %04X", unicode)); if (pair_first) { if (is_utf16_surrogate_second(unicode)) { unicode = surrogate_pair_to_codepoint(pair_first, unicode); pair_first = 0; } else goto invalid_pair; } else if (is_utf16_surrogate_second(unicode)) goto invalid_pair; if (is_utf16_surrogate_first(unicode)) pair_first = unicode; else { pg_unicode_to_server(unicode, (unsigned char *) cbuf); appendStringInfoString(&str, cbuf); } instr += 8; len -= 8; } else if (len >= 10 && instr[1] == 'U' && isxdigits_n(instr + 2, 8)) { pg_wchar unicode; unicode = hexval_n(instr + 2, 8); if (!is_valid_unicode_codepoint(unicode)) ereport(ERROR, errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("invalid Unicode code point: %04X", unicode)); if (pair_first) { if (is_utf16_surrogate_second(unicode)) { unicode = surrogate_pair_to_codepoint(pair_first, unicode); pair_first = 0; } else goto invalid_pair; } else if (is_utf16_surrogate_second(unicode)) goto invalid_pair; if (is_utf16_surrogate_first(unicode)) pair_first = unicode; else { pg_unicode_to_server(unicode, (unsigned char *) cbuf); appendStringInfoString(&str, cbuf); } instr += 10; len -= 10; } else ereport(ERROR, (errcode(ERRCODE_SYNTAX_ERROR), errmsg("invalid Unicode escape"), errhint("Unicode escapes must be \\XXXX, \\+XXXXXX, \\uXXXX, or \\UXXXXXXXX."))); } else { if (pair_first) goto invalid_pair; appendStringInfoChar(&str, *instr++); len--; } } /* unfinished surrogate pair? */ if (pair_first) goto invalid_pair; result = cstring_to_text_with_len(str.data, str.len); pfree(str.data); PG_RETURN_TEXT_P(result); invalid_pair: ereport(ERROR, (errcode(ERRCODE_SYNTAX_ERROR), errmsg("invalid Unicode surrogate pair"))); PG_RETURN_NULL(); /* keep compiler quiet */ }