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Fix strange behavior (and possible crashes) in full text phrase search. 

In an attempt to simplify the tsquery matching engine, the original
phrase search patch invented rewrite rules that would rearrange a
tsquery so that no AND/OR/NOT operator appeared below a PHRASE operator.
But this approach had numerous problems.  The rearrangement step was
missed by ts_rewrite (and perhaps other places), allowing tsqueries
to be created that would cause Assert failures or perhaps crashes at
execution, as reported by Andreas Seltenreich.  The rewrite rules
effectively defined semantics for operators underneath PHRASE that were
buggy, or at least unintuitive.  And because rewriting was done in
tsqueryin() rather than at execution, the rearrangement was user-visible,
which is not very desirable --- for example, it might cause unexpected
matches or failures to match in ts_rewrite.

As a somewhat independent problem, the behavior of nested PHRASE operators
was only sane for left-deep trees; queries like "x <-> (y <-> z)" did not
behave intuitively at all.

To fix, get rid of the rewrite logic altogether, and instead teach the
tsquery execution engine to manage AND/OR/NOT below a PHRASE operator
by explicitly computing the match location(s) and match widths for these
operators.

This requires introducing some additional fields into the publicly visible
ExecPhraseData struct; but since there's no way for third-party code to
pass such a struct to TS_phrase_execute, it shouldn't create an ABI problem
as long as we don't move the offsets of the existing fields.

Another related problem was that index searches supposed that "!x <-> y"
could be lossily approximated as "!x & y", which isn't correct because
the latter will reject, say, "x q y" which the query itself accepts.
This required some tweaking in TS_execute_ternary along with the main
tsquery engine.

Back-patch to 9.6 where phrase operators were introduced.  While this
could be argued to change behavior more than we'd like in a stable branch,
we have to do something about the crash hazards and index-vs-seqscan
inconsistency, and it doesn't seem desirable to let the unintuitive
behaviors induced by the rewriting implementation stand as precedent.

Discussion: https://postgr.es/m/28215.1481999808@sss.pgh.pa.us
Discussion: https://postgr.es/m/26706.1482087250@sss.pgh.pa.us
This commit is contained in:
Tom Lane 2016-12-21 15:18:25 -05:00
parent 2d1018ca56
commit 89fcea1ace
14 changed files with 678 additions and 606 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

8
doc/src/sgml/datatype.sgml
View File

@ -3959,15 +3959,7 @@ SELECT 'fat &amp; rat &amp; ! cat'::tsquery;
tsquery
------------------------
'fat' &amp; 'rat' &amp; !'cat'
SELECT '(fat | rat) &lt;-&gt; cat'::tsquery;
tsquery
-----------------------------------
'fat' &lt;-&gt; 'cat' | 'rat' &lt;-&gt; 'cat'
</programlisting>
The last example demonstrates that <type>tsquery</type> sometimes
rearranges nested operators into a logically equivalent formulation.
</para>
<para>

26
doc/src/sgml/textsearch.sgml
View File

@ -264,7 +264,7 @@ SELECT 'fat &amp; cow'::tsquery @@ 'a fat cat sat on a mat and ate a fat rat'::t
text, any more than a <type>tsvector</type> is. A <type>tsquery</type>
contains search terms, which must be already-normalized lexemes, and
may combine multiple terms using AND, OR, NOT, and FOLLOWED BY operators.
(For details see <xref linkend="datatype-tsquery">.) There are
(For syntax details see <xref linkend="datatype-tsquery">.) There are
functions <function>to_tsquery</>, <function>plainto_tsquery</>,
and <function>phraseto_tsquery</>
that are helpful in converting user-written text into a proper
@ -323,6 +323,8 @@ text @@ text
at least one of its arguments must appear, while the <literal>!</> (NOT)
operator specifies that its argument must <emphasis>not</> appear in
order to have a match.
For example, the query <literal>fat &amp; ! rat</> matches documents that
contain <literal>fat</> but not <literal>rat</>.
</para>
<para>
@ -377,6 +379,28 @@ SELECT phraseto_tsquery('the cats ate the rats');
then <literal>&amp;</literal>, then <literal>&lt;-&gt;</literal>,
and <literal>!</literal> most tightly.
</para>
<para>
It's worth noticing that the AND/OR/NOT operators mean something subtly
different when they are within the arguments of a FOLLOWED BY operator
than when they are not, because within FOLLOWED BY the exact position of
the match is significant. For example, normally <literal>!x</> matches
only documents that do not contain <literal>x</> anywhere.
But <literal>!x &lt;-&gt; y</> matches <literal>y</> if it is not
immediately after an <literal>x</>; an occurrence of <literal>x</>
elsewhere in the document does not prevent a match. Another example is
that <literal>x &amp; y</> normally only requires that <literal>x</>
and <literal>y</> both appear somewhere in the document, but
<literal>(x &amp; y) &lt;-&gt; z</> requires <literal>x</>
and <literal>y</> to match at the same place, immediately before
a <literal>z</>. Thus this query behaves differently from
<literal>x &lt;-&gt; z &amp; y &lt;-&gt; z</>, which will match a
document containing two separate sequences <literal>x z</> and
<literal>y z</>. (This specific query is useless as written,
since <literal>x</> and <literal>y</> could not match at the same place;
but with more complex situations such as prefix-match patterns, a query
of this form could be useful.)
</para>
</sect2>
<sect2 id="textsearch-intro-configurations">

28
src/backend/utils/adt/tsginidx.c
View File

@ -212,7 +212,7 @@ checkcondition_gin(void *checkval, QueryOperand *val, ExecPhraseData *data)
* Evaluate tsquery boolean expression using ternary logic.
*/
static GinTernaryValue
TS_execute_ternary(GinChkVal *gcv, QueryItem *curitem)
TS_execute_ternary(GinChkVal *gcv, QueryItem *curitem, bool in_phrase)
{
GinTernaryValue val1,
val2,
@ -230,7 +230,10 @@ TS_execute_ternary(GinChkVal *gcv, QueryItem *curitem)
switch (curitem->qoperator.oper)
{
case OP_NOT:
result = TS_execute_ternary(gcv, curitem + 1);
/* In phrase search, always return MAYBE since we lack positions */
if (in_phrase)
return GIN_MAYBE;
result = TS_execute_ternary(gcv, curitem + 1, in_phrase);
if (result == GIN_MAYBE)
return result;
return !result;
@ -238,17 +241,21 @@ TS_execute_ternary(GinChkVal *gcv, QueryItem *curitem)
case OP_PHRASE:
/*
* GIN doesn't contain any information about positions, treat
* GIN doesn't contain any information about positions, so treat
* OP_PHRASE as OP_AND with recheck requirement
*/
*gcv->need_recheck = true;
*(gcv->need_recheck) = true;
/* Pass down in_phrase == true in case there's a NOT below */
in_phrase = true;
/* FALL THRU */
case OP_AND:
val1 = TS_execute_ternary(gcv, curitem + curitem->qoperator.left);
val1 = TS_execute_ternary(gcv, curitem + curitem->qoperator.left,
in_phrase);
if (val1 == GIN_FALSE)
return GIN_FALSE;
val2 = TS_execute_ternary(gcv, curitem + 1);
val2 = TS_execute_ternary(gcv, curitem + 1, in_phrase);
if (val2 == GIN_FALSE)
return GIN_FALSE;
if (val1 == GIN_TRUE && val2 == GIN_TRUE)
@ -257,10 +264,11 @@ TS_execute_ternary(GinChkVal *gcv, QueryItem *curitem)
return GIN_MAYBE;
case OP_OR:
val1 = TS_execute_ternary(gcv, curitem + curitem->qoperator.left);
val1 = TS_execute_ternary(gcv, curitem + curitem->qoperator.left,
in_phrase);
if (val1 == GIN_TRUE)
return GIN_TRUE;
val2 = TS_execute_ternary(gcv, curitem + 1);
val2 = TS_execute_ternary(gcv, curitem + 1, in_phrase);
if (val2 == GIN_TRUE)
return GIN_TRUE;
if (val1 == GIN_FALSE && val2 == GIN_FALSE)
@ -307,7 +315,7 @@ gin_tsquery_consistent(PG_FUNCTION_ARGS)
res = TS_execute(GETQUERY(query),
&gcv,
TS_EXEC_CALC_NOT | TS_EXEC_PHRASE_AS_AND,
TS_EXEC_CALC_NOT | TS_EXEC_PHRASE_NO_POS,
checkcondition_gin);
}
@ -343,7 +351,7 @@ gin_tsquery_triconsistent(PG_FUNCTION_ARGS)
gcv.map_item_operand = (int *) (extra_data[0]);
gcv.need_recheck = &recheck;
res = TS_execute_ternary(&gcv, GETQUERY(query));
res = TS_execute_ternary(&gcv, GETQUERY(query), false);
if (res == GIN_TRUE && recheck)
res = GIN_MAYBE;

17
src/backend/utils/adt/tsgistidx.c
View File

@ -359,12 +359,11 @@ gtsvector_consistent(PG_FUNCTION_ARGS)
if (ISALLTRUE(key))
PG_RETURN_BOOL(true);
PG_RETURN_BOOL(TS_execute(
GETQUERY(query),
/* since signature is lossy, cannot specify CALC_NOT here */
PG_RETURN_BOOL(TS_execute(GETQUERY(query),
(void *) GETSIGN(key),
TS_EXEC_PHRASE_AS_AND,
checkcondition_bit
));
TS_EXEC_PHRASE_NO_POS,
checkcondition_bit));
}
else
{ /* only leaf pages */
@ -372,12 +371,10 @@ gtsvector_consistent(PG_FUNCTION_ARGS)
chkval.arrb = GETARR(key);
chkval.arre = chkval.arrb + ARRNELEM(key);
PG_RETURN_BOOL(TS_execute(
GETQUERY(query),
PG_RETURN_BOOL(TS_execute(GETQUERY(query),
(void *) &chkval,
TS_EXEC_PHRASE_AS_AND | TS_EXEC_CALC_NOT,
checkcondition_arr
));
TS_EXEC_PHRASE_NO_POS | TS_EXEC_CALC_NOT,
checkcondition_arr));
}
}

25
src/backend/utils/adt/tsquery.c
View File

@ -557,13 +557,11 @@ findoprnd_recurse(QueryItem *ptr, uint32 *pos, int nnodes, bool *needcleanup)
curitem->oper == OP_OR ||
curitem->oper == OP_PHRASE);
if (curitem->oper == OP_PHRASE)
*needcleanup = true; /* push OP_PHRASE down later */
(*pos)++;
/* process RIGHT argument */
findoprnd_recurse(ptr, pos, nnodes, needcleanup);
curitem->left = *pos - tmp; /* set LEFT arg's offset */
/* process LEFT argument */
@ -574,8 +572,9 @@ findoprnd_recurse(QueryItem *ptr, uint32 *pos, int nnodes, bool *needcleanup)
/*
* Fills in the left-fields previously left unfilled. The input
* QueryItems must be in polish (prefix) notation.
* Fill in the left-fields previously left unfilled.
* The input QueryItems must be in polish (prefix) notation.
* Also, set *needcleanup to true if there are any QI_VALSTOP nodes.
*/
static void
findoprnd(QueryItem *ptr, int size, bool *needcleanup)
@ -687,15 +686,17 @@ parse_tsquery(char *buf,
memcpy((void *) GETOPERAND(query), (void *) state.op, state.sumlen);
pfree(state.op);
/* Set left operand pointers for every operator. */
/*
* Set left operand pointers for every operator. While we're at it,
* detect whether there are any QI_VALSTOP nodes.
*/
findoprnd(ptr, query->size, &needcleanup);
/*
* QI_VALSTOP nodes should be cleaned and OP_PHRASE should be pushed
* down
* If there are QI_VALSTOP nodes, delete them and simplify the tree.
*/
if (needcleanup)
return cleanup_fakeval_and_phrase(query);
query = cleanup_tsquery_stopwords(query);
return query;
}
@ -1088,6 +1089,9 @@ tsqueryrecv(PG_FUNCTION_ARGS)
*/
findoprnd(item, size, &needcleanup);
/* Can't have found any QI_VALSTOP nodes */
Assert(!needcleanup);
/* Copy operands to output struct */
for (i = 0; i < size; i++)
{
@ -1105,9 +1109,6 @@ tsqueryrecv(PG_FUNCTION_ARGS)
SET_VARSIZE(query, len + datalen);
if (needcleanup)
PG_RETURN_TSQUERY(cleanup_fakeval_and_phrase(query));
PG_RETURN_TSQUERY(query);
}

242
src/backend/utils/adt/tsquery_cleanup.c
View File

@ -25,19 +25,6 @@ typedef struct NODE
QueryItem *valnode;
} NODE;
/*
* To simplify walking on query tree and pushing down of phrase operator
* we define some fake priority here: phrase operator has highest priority
* of any other operators (and we believe here that OP_PHRASE is a highest
* code of operations) and value node has ever highest priority.
* Priority values of other operations don't matter until they are less than
* phrase operator and value node.
*/
#define VALUE_PRIORITY (OP_COUNT + 1)
#define NODE_PRIORITY(x) \
( ((x)->valnode->qoperator.type == QI_OPR) ? \
(x)->valnode->qoperator.oper : VALUE_PRIORITY )
/*
* make query tree from plain view of query
*/
@ -368,227 +355,6 @@ clean_stopword_intree(NODE *node, int *ladd, int *radd)
return node;
}
static NODE *
copyNODE(NODE *node)
{
NODE *cnode = palloc(sizeof(NODE));
/* since this function recurses, it could be driven to stack overflow. */
check_stack_depth();
cnode->valnode = palloc(sizeof(QueryItem));
*(cnode->valnode) = *(node->valnode);
if (node->valnode->type == QI_OPR)
{
cnode->right = copyNODE(node->right);
if (node->valnode->qoperator.oper != OP_NOT)
cnode->left = copyNODE(node->left);
}
return cnode;
}
static NODE *
makeNODE(int8 op, NODE *left, NODE *right)
{
NODE *node = palloc(sizeof(NODE));
/* zeroing allocation to prevent difference in unused bytes */
node->valnode = palloc0(sizeof(QueryItem));
node->valnode->qoperator.type = QI_OPR;
node->valnode->qoperator.oper = op;
node->left = left;
node->right = right;
return node;
}
/*
* Move operation with high priority to the leaves. This guarantees
* that the phrase operator will be near the bottom of the tree.
* An idea behind is do not store position of lexemes during execution
* of ordinary operations (AND, OR, NOT) because it could be expensive.
* Actual transformation will be performed only on subtrees under the
* <-> (<n>) operation since it's needed solely for the phrase operator.
*
* Rules:
* a <-> (b | c) => (a <-> b) | (a <-> c)
* (a | b) <-> c => (a <-> c) | (b <-> c)
* a <-> !b => a & !(a <-> b)
* !a <-> b => b & !(a <-> b)
*
* Warnings for readers:
* a <-> b != b <-> a
*
* a <n> (b <n> c) != (a <n> b) <n> c since the phrase lengths are:
* n 2n-1
*/
static NODE *
normalize_phrase_tree(NODE *node)
{
/* there should be no stop words at this point */
Assert(node->valnode->type != QI_VALSTOP);
if (node->valnode->type == QI_VAL)
return node;
/* since this function recurses, it could be driven to stack overflow. */
check_stack_depth();
Assert(node->valnode->type == QI_OPR);
if (node->valnode->qoperator.oper == OP_NOT)
{
NODE *orignode = node;
/* eliminate NOT sequence */
while (node->valnode->type == QI_OPR &&
node->valnode->qoperator.oper == node->right->valnode->qoperator.oper)
{
node = node->right->right;
}
if (orignode != node)
/* current node isn't checked yet */
node = normalize_phrase_tree(node);
else
node->right = normalize_phrase_tree(node->right);
}
else if (node->valnode->qoperator.oper == OP_PHRASE)
{
int16 distance;
NODE *X;
node->left = normalize_phrase_tree(node->left);
node->right = normalize_phrase_tree(node->right);
/*
* if subtree contains only nodes with higher "priority" then we are
* done. See comment near NODE_PRIORITY()
*/
if (NODE_PRIORITY(node) <= NODE_PRIORITY(node->right) &&
NODE_PRIORITY(node) <= NODE_PRIORITY(node->left))
return node;
/*
* We can't swap left-right and works only with left child because of
* a <-> b != b <-> a
*/
distance = node->valnode->qoperator.distance;
if (node->right->valnode->type == QI_OPR)
{
switch (node->right->valnode->qoperator.oper)
{
case OP_AND:
/* a <-> (b & c) => (a <-> b) & (a <-> c) */
node = makeNODE(OP_AND,
makeNODE(OP_PHRASE,
node->left,
node->right->left),
makeNODE(OP_PHRASE,
copyNODE(node->left),
node->right->right));
node->left->valnode->qoperator.distance =
node->right->valnode->qoperator.distance = distance;
break;
case OP_OR:
/* a <-> (b | c) => (a <-> b) | (a <-> c) */
node = makeNODE(OP_OR,
makeNODE(OP_PHRASE,
node->left,
node->right->left),
makeNODE(OP_PHRASE,
copyNODE(node->left),
node->right->right));
node->left->valnode->qoperator.distance =
node->right->valnode->qoperator.distance = distance;
break;
case OP_NOT:
/* a <-> !b => a & !(a <-> b) */
X = node->right;
node->right = node->right->right;
X->right = node;
node = makeNODE(OP_AND,
copyNODE(node->left),
X);
break;
case OP_PHRASE:
/* no-op */
break;
default:
elog(ERROR, "Wrong type of tsquery node: %d",
node->right->valnode->qoperator.oper);
}
}
if (node->left->valnode->type == QI_OPR &&
node->valnode->qoperator.oper == OP_PHRASE)
{
/*
* if the node is still OP_PHRASE, check the left subtree,
* otherwise the whole node will be transformed later.
*/
switch (node->left->valnode->qoperator.oper)
{
case OP_AND:
/* (a & b) <-> c => (a <-> c) & (b <-> c) */
node = makeNODE(OP_AND,
makeNODE(OP_PHRASE,
node->left->left,
node->right),
makeNODE(OP_PHRASE,
node->left->right,
copyNODE(node->right)));
node->left->valnode->qoperator.distance =
node->right->valnode->qoperator.distance = distance;
break;
case OP_OR:
/* (a | b) <-> c => (a <-> c) | (b <-> c) */
node = makeNODE(OP_OR,
makeNODE(OP_PHRASE,
node->left->left,
node->right),
makeNODE(OP_PHRASE,
node->left->right,
copyNODE(node->right)));
node->left->valnode->qoperator.distance =
node->right->valnode->qoperator.distance = distance;
break;
case OP_NOT:
/* !a <-> b => b & !(a <-> b) */
X = node->left;
node->left = node->left->right;
X->right = node;
node = makeNODE(OP_AND,
X,
copyNODE(node->right));
break;
case OP_PHRASE:
/* no-op */
break;
default:
elog(ERROR, "Wrong type of tsquery node: %d",
node->left->valnode->qoperator.oper);
}
}
/* continue transformation */
node = normalize_phrase_tree(node);
}
else /* AND or OR */
{
node->left = normalize_phrase_tree(node->left);
node->right = normalize_phrase_tree(node->right);
}
return node;
}
/*
* Number of elements in query tree
*/
@ -613,8 +379,11 @@ calcstrlen(NODE *node)
return size;
}
/*
* Remove QI_VALSTOP (stopword) nodes from TSQuery.
*/
TSQuery
cleanup_fakeval_and_phrase(TSQuery in)
cleanup_tsquery_stopwords(TSQuery in)
{
int32 len,
lenstr,
@ -642,9 +411,6 @@ cleanup_fakeval_and_phrase(TSQuery in)
return out;
}
/* push OP_PHRASE nodes down */
root = normalize_phrase_tree(root);
/*
* Build TSQuery from plain view
*/

4
src/backend/utils/adt/tsquery_op.c
View File

@ -104,7 +104,7 @@ tsquery_or(PG_FUNCTION_ARGS)
PG_FREE_IF_COPY(a, 0);
PG_FREE_IF_COPY(b, 1);
PG_RETURN_POINTER(query);
PG_RETURN_TSQUERY(query);
}
Datum
@ -140,7 +140,7 @@ tsquery_phrase_distance(PG_FUNCTION_ARGS)
PG_FREE_IF_COPY(a, 0);
PG_FREE_IF_COPY(b, 1);
PG_RETURN_POINTER(cleanup_fakeval_and_phrase(query));
PG_RETURN_TSQUERY(query);
}
Datum

485
src/backend/utils/adt/tsvector_op.c
View File

@ -11,9 +11,10 @@
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include <limits.h>
#include "access/htup_details.h"
#include "catalog/namespace.h"
#include "catalog/pg_type.h"
@ -1404,148 +1405,395 @@ checkcondition_str(void *checkval, QueryOperand *val, ExecPhraseData *data)
return res;
}
/*
* Compute output position list for a tsquery operator in phrase mode.
*
* Merge the position lists in Ldata and Rdata as specified by "emit",
* returning the result list into *data. The input position lists must be
* sorted and unique, and the output will be as well.
*
* data: pointer to initially-all-zeroes output struct, or NULL
* Ldata, Rdata: input position lists
* emit: bitmask of TSPO_XXX flags
* Loffset: offset to be added to Ldata positions before comparing/outputting
* Roffset: offset to be added to Rdata positions before comparing/outputting
* max_npos: maximum possible required size of output position array
*
* Loffset and Roffset should not be negative, else we risk trying to output
* negative positions, which won't fit into WordEntryPos.
*
* Returns true if any positions were emitted to *data; or if data is NULL,
* returns true if any positions would have been emitted.
*/
#define TSPO_L_ONLY 0x01 /* emit positions appearing only in L */
#define TSPO_R_ONLY 0x02 /* emit positions appearing only in R */
#define TSPO_BOTH 0x04 /* emit positions appearing in both L&R */
static bool
TS_phrase_output(ExecPhraseData *data,
ExecPhraseData *Ldata,
ExecPhraseData *Rdata,
int emit,
int Loffset,
int Roffset,
int max_npos)
{
int Lindex,
Rindex;
/* Loop until both inputs are exhausted */
Lindex = Rindex = 0;
while (Lindex < Ldata->npos || Rindex < Rdata->npos)
{
int Lpos,
Rpos;
int output_pos = 0;
/*
* Fetch current values to compare. WEP_GETPOS() is needed because
* ExecPhraseData->data can point to a tsvector's WordEntryPosVector.
*/
if (Lindex < Ldata->npos)
Lpos = WEP_GETPOS(Ldata->pos[Lindex]) + Loffset;
else
{
/* L array exhausted, so we're done if R_ONLY isn't set */
if (!(emit & TSPO_R_ONLY))
break;
Lpos = INT_MAX;
}
if (Rindex < Rdata->npos)
Rpos = WEP_GETPOS(Rdata->pos[Rindex]) + Roffset;
else
{
/* R array exhausted, so we're done if L_ONLY isn't set */
if (!(emit & TSPO_L_ONLY))
break;
Rpos = INT_MAX;
}
/* Merge-join the two input lists */
if (Lpos < Rpos)
{
/* Lpos is not matched in Rdata, should we output it? */
if (emit & TSPO_L_ONLY)
output_pos = Lpos;
Lindex++;
}
else if (Lpos == Rpos)
{
/* Lpos and Rpos match ... should we output it? */
if (emit & TSPO_BOTH)
output_pos = Rpos;
Lindex++;
Rindex++;
}
else /* Lpos > Rpos */
{
/* Rpos is not matched in Ldata, should we output it? */
if (emit & TSPO_R_ONLY)
output_pos = Rpos;
Rindex++;
}
if (output_pos > 0)
{
if (data)
{
/* Store position, first allocating output array if needed */
if (data->pos == NULL)
{
data->pos = (WordEntryPos *)
palloc(max_npos * sizeof(WordEntryPos));
data->allocated = true;
}
data->pos[data->npos++] = output_pos;
}
else
{
/*
* Exact positions not needed, so return true as soon as we
* know there is at least one.
*/
return true;
}
}
}
if (data && data->npos > 0)
{
/* Let's assert we didn't overrun the array */
Assert(data->npos <= max_npos);
return true;
}
return false;
}
/*
* Execute tsquery at or below an OP_PHRASE operator.
*
* This handles the recursion at levels where we need to care about
* match locations. In addition to the same arguments used for TS_execute,
* the caller may pass a preinitialized-to-zeroes ExecPhraseData struct to
* be filled with lexeme match positions on success. data == NULL if no
* match data need be returned. (In practice, outside callers pass NULL,
* and only the internal recursion cases pass a data pointer.)
* This handles tsquery execution at recursion levels where we need to care
* about match locations.
*
* In addition to the same arguments used for TS_execute, the caller may pass
* a preinitialized-to-zeroes ExecPhraseData struct, to be filled with lexeme
* match position info on success. data == NULL if no position data need be
* returned. (In practice, outside callers pass NULL, and only the internal
* recursion cases pass a data pointer.)
* Note: the function assumes data != NULL for operators other than OP_PHRASE.
* This is OK because an outside call always starts from an OP_PHRASE node.
*
* The detailed semantics of the match data, given that the function returned
* "true" (successful match, or possible match), are:
*
* npos > 0, negate = false:
* query is matched at specified position(s) (and only those positions)
* npos > 0, negate = true:
* query is matched at all positions *except* specified position(s)
* npos = 0, negate = false:
* query is possibly matched, matching position(s) are unknown
* (this should only be returned when TS_EXEC_PHRASE_NO_POS flag is set)
* npos = 0, negate = true:
* query is matched at all positions
*
* Successful matches also return a "width" value which is the match width in
* lexemes, less one. Hence, "width" is zero for simple one-lexeme matches,
* and is the sum of the phrase operator distances for phrase matches. Note
* that when width > 0, the listed positions represent the ends of matches not
* the starts. (This unintuitive rule is needed to avoid possibly generating
* negative positions, which wouldn't fit into the WordEntryPos arrays.)
*
* When the function returns "false" (no match), it must return npos = 0,
* negate = false (which is the state initialized by the caller); but the
* "width" output in such cases is undefined.
*/
static bool
TS_phrase_execute(QueryItem *curitem, void *arg, uint32 flags,
ExecPhraseData *data,
TSExecuteCallback chkcond)
TSExecuteCallback chkcond,
ExecPhraseData *data)
{
ExecPhraseData Ldata,
Rdata;
bool lmatch,
rmatch;
int Loffset,
Roffset,
maxwidth;
/* since this function recurses, it could be driven to stack overflow */
check_stack_depth();
if (curitem->type == QI_VAL)
{
return chkcond(arg, (QueryOperand *) curitem, data);
}
else
switch (curitem->qoperator.oper)
{
ExecPhraseData Ldata = {0, false, NULL},
Rdata = {0, false, NULL};
WordEntryPos *Lpos,
*LposStart,
*Rpos,
*pos_iter = NULL;
case OP_NOT:
Assert(curitem->qoperator.oper == OP_PHRASE);
if (!TS_phrase_execute(curitem + curitem->qoperator.left,
arg, flags, &Ldata, chkcond))
return false;
if (!TS_phrase_execute(curitem + 1, arg, flags, &Rdata, chkcond))
return false;
/*
* If either operand has no position information, then we normally
* return false. But if TS_EXEC_PHRASE_AS_AND flag is set then we
* return true, treating OP_PHRASE as if it were OP_AND.
*/
if (Ldata.npos == 0 || Rdata.npos == 0)
return (flags & TS_EXEC_PHRASE_AS_AND) ? true : false;
/*
* Prepare output position array if needed.
*/
if (data)
{
/*
* We can recycle the righthand operand's result array if it was
* palloc'd, else must allocate our own. The number of matches
* couldn't be more than the smaller of the two operands' matches.
* Because a "true" result with no specific positions is taken as
* uncertain, we need no special care here for !TS_EXEC_CALC_NOT.
* If it's a false positive, the right things happen anyway.
*
* Also, we need not touch data->width, since a NOT operation does
* not change the match width.
*/
if (!Rdata.allocated)
data->pos = palloc(sizeof(WordEntryPos) * Min(Ldata.npos, Rdata.npos));
else
data->pos = Rdata.pos;
data->allocated = true;
data->npos = 0;
pos_iter = data->pos;
}
/*
* Find matches by distance. WEP_GETPOS() is needed because
* ExecPhraseData->data can point to a tsvector's WordEntryPosVector.
*
* Note that the output positions are those of the matching RIGHT
* operands.
*/
Rpos = Rdata.pos;
LposStart = Ldata.pos;
while (Rpos < Rdata.pos + Rdata.npos)
{
/*
* We need to check all possible distances, so reset Lpos to
* guaranteed not yet satisfied position.
*/
Lpos = LposStart;
while (Lpos < Ldata.pos + Ldata.npos)
if (TS_phrase_execute(curitem + 1, arg, flags, chkcond, data))
{
if (WEP_GETPOS(*Rpos) - WEP_GETPOS(*Lpos) ==
curitem->qoperator.distance)
if (data->npos > 0)
{
/* MATCH! */
if (data)
{
/* Store position for upper phrase operator */
*pos_iter = WEP_GETPOS(*Rpos);
pos_iter++;
/*
* Set left start position to next, because current
* one could not satisfy distance for any other right
* position
*/
LposStart = Lpos + 1;
break;
}
else
{
/*
* We are at the root of the phrase tree and hence we
* don't have to identify all the match positions.
* Just report success.
*/
return true;
}
/* we have some positions, invert negate flag */
data->negate = !data->negate;
return true;
}
else if (WEP_GETPOS(*Rpos) <= WEP_GETPOS(*Lpos) ||
WEP_GETPOS(*Rpos) - WEP_GETPOS(*Lpos) <
curitem->qoperator.distance)
else if (data->negate)
{
/*
* Go to the next Rpos, because Lpos is ahead or on less
* distance than required by current operator
*/
break;
/* change "match everywhere" to "match nowhere" */
data->negate = false;
return false;
}
Lpos++;
/* match positions are, and remain, uncertain */
return true;
}
else
{
/* change "match nowhere" to "match everywhere" */
Assert(data->npos == 0 && !data->negate);
data->negate = true;
return true;
}
Rpos++;
}
case OP_PHRASE:
case OP_AND:
memset(&Ldata, 0, sizeof(Ldata));
memset(&Rdata, 0, sizeof(Rdata));
if (data)
{
data->npos = pos_iter - data->pos;
if (!TS_phrase_execute(curitem + curitem->qoperator.left,
arg, flags, chkcond, &Ldata))
return false;
if (data->npos > 0)
if (!TS_phrase_execute(curitem + 1,
arg, flags, chkcond, &Rdata))
return false;
/*
* If either operand has no position information, then we can't
* return position data, only a "possible match" result. "Possible
* match" answers are only wanted when TS_EXEC_PHRASE_NO_POS flag
* is set, otherwise return false.
*/
if ((Ldata.npos == 0 && !Ldata.negate) ||
(Rdata.npos == 0 && !Rdata.negate))
return (flags & TS_EXEC_PHRASE_NO_POS) ? true : false;
if (curitem->qoperator.oper == OP_PHRASE)
{
/*
* Compute Loffset and Roffset suitable for phrase match, and
* compute overall width of whole phrase match.
*/
Loffset = curitem->qoperator.distance + Rdata.width;
Roffset = 0;
if (data)
data->width = curitem->qoperator.distance +
Ldata.width + Rdata.width;
}
else
{
/*
* For OP_AND, set output width and alignment like OP_OR (see
* comment below)
*/
maxwidth = Max(Ldata.width, Rdata.width);
Loffset = maxwidth - Ldata.width;
Roffset = maxwidth - Rdata.width;
if (data)
data->width = maxwidth;
}
if (Ldata.negate && Rdata.negate)
{
/* !L & !R: treat as !(L | R) */
(void) TS_phrase_output(data, &Ldata, &Rdata,
TSPO_BOTH | TSPO_L_ONLY | TSPO_R_ONLY,
Loffset, Roffset,
Ldata.npos + Rdata.npos);
if (data)
data->negate = true;
return true;
}
}
else if (Ldata.negate)
{
/* !L & R */
return TS_phrase_output(data, &Ldata, &Rdata,
TSPO_R_ONLY,
Loffset, Roffset,
Rdata.npos);
}
else if (Rdata.negate)
{
/* L & !R */
return TS_phrase_output(data, &Ldata, &Rdata,
TSPO_L_ONLY,
Loffset, Roffset,
Ldata.npos);
}
else
{
/* straight AND */
return TS_phrase_output(data, &Ldata, &Rdata,
TSPO_BOTH,
Loffset, Roffset,
Min(Ldata.npos, Rdata.npos));
}
case OP_OR:
memset(&Ldata, 0, sizeof(Ldata));
memset(&Rdata, 0, sizeof(Rdata));
lmatch = TS_phrase_execute(curitem + curitem->qoperator.left,
arg, flags, chkcond, &Ldata);
rmatch = TS_phrase_execute(curitem + 1,
arg, flags, chkcond, &Rdata);
if (!lmatch && !rmatch)
return false;
/*
* If a valid operand has no position information, then we can't
* return position data, only a "possible match" result. "Possible
* match" answers are only wanted when TS_EXEC_PHRASE_NO_POS flag
* is set, otherwise return false.
*/
if ((lmatch && Ldata.npos == 0 && !Ldata.negate) ||
(rmatch && Rdata.npos == 0 && !Rdata.negate))
return (flags & TS_EXEC_PHRASE_NO_POS) ? true : false;
/*
* Cope with undefined output width from failed submatch. (This
* takes less code than trying to ensure that all failure returns
* set data->width to zero.)
*/
if (!lmatch)
Ldata.width = 0;
if (!rmatch)
Rdata.width = 0;
/*
* For OP_AND and OP_OR, report the width of the wider of the two
* inputs, and align the narrower input's positions to the right
* end of that width. This rule deals at least somewhat
* reasonably with cases like "x <-> (y | z <-> q)".
*/
maxwidth = Max(Ldata.width, Rdata.width);
Loffset = maxwidth - Ldata.width;
Roffset = maxwidth - Rdata.width;
data->width = maxwidth;
if (Ldata.negate && Rdata.negate)
{
/* !L | !R: treat as !(L & R) */
(void) TS_phrase_output(data, &Ldata, &Rdata,
TSPO_BOTH,
Loffset, Roffset,
Min(Ldata.npos, Rdata.npos));
data->negate = true;
return true;
}
else if (Ldata.negate)
{
/* !L | R: treat as !(L & !R) */
(void) TS_phrase_output(data, &Ldata, &Rdata,
TSPO_L_ONLY,
Loffset, Roffset,
Ldata.npos);
data->negate = true;
return true;
}
else if (Rdata.negate)
{
/* L | !R: treat as !(!L & R) */
(void) TS_phrase_output(data, &Ldata, &Rdata,
TSPO_R_ONLY,
Loffset, Roffset,
Rdata.npos);
data->negate = true;
return true;
}
else
{
/* straight OR */
return TS_phrase_output(data, &Ldata, &Rdata,
TSPO_BOTH | TSPO_L_ONLY | TSPO_R_ONLY,
Loffset, Roffset,
Ldata.npos + Rdata.npos);
}
default:
elog(ERROR, "unrecognized operator: %d", curitem->qoperator.oper);
}
/* not reachable, but keep compiler quiet */
return false;
}
@ -1594,12 +1842,7 @@ TS_execute(QueryItem *curitem, void *arg, uint32 flags,
return TS_execute(curitem + 1, arg, flags, chkcond);
case OP_PHRASE:
/*
* do not check TS_EXEC_PHRASE_AS_AND here because chkcond() could
* do something more if it's called from TS_phrase_execute()
*/
return TS_phrase_execute(curitem, arg, flags, NULL, chkcond);
return TS_phrase_execute(curitem, arg, flags, chkcond, NULL);
default:
elog(ERROR, "unrecognized operator: %d", curitem->qoperator.oper);

31
src/include/tsearch/ts_utils.h
View File

@ -113,8 +113,8 @@ extern text *generateHeadline(HeadlineParsedText *prs);
* struct ExecPhraseData is passed to a TSExecuteCallback function if we need
* lexeme position data (because of a phrase-match operator in the tsquery).
* The callback should fill in position data when it returns true (success).
* If it cannot return position data, it may ignore its "data" argument, but
* then the caller of TS_execute() must pass the TS_EXEC_PHRASE_AS_AND flag
* If it cannot return position data, it may leave "data" unchanged, but
* then the caller of TS_execute() must pass the TS_EXEC_PHRASE_NO_POS flag
* and must arrange for a later recheck with position data available.
*
* The reported lexeme positions must be sorted and unique. Callers must only
@ -123,13 +123,21 @@ extern text *generateHeadline(HeadlineParsedText *prs);
* portion of a tsvector value. If "allocated" is true then the pos array
* is palloc'd workspace and caller may free it when done.
*
* "negate" means that the pos array contains positions where the query does
* not match, rather than positions where it does. "width" is positive when
* the match is wider than one lexeme. Neither of these fields normally need
* to be touched by TSExecuteCallback functions; they are used for
* phrase-search processing within TS_execute.
*
* All fields of the ExecPhraseData struct are initially zeroed by caller.
*/
typedef struct ExecPhraseData
{
int npos; /* number of positions reported */
bool allocated; /* pos points to palloc'd data? */
bool negate; /* positions are where query is NOT matched */
WordEntryPos *pos; /* ordered, non-duplicate lexeme positions */
int width; /* width of match in lexemes, less 1 */
} ExecPhraseData;
/*
@ -139,7 +147,9 @@ typedef struct ExecPhraseData
* val: lexeme to test for presence of
* data: to be filled with lexeme positions; NULL if position data not needed
*
* Return TRUE if lexeme is present in data, else FALSE
* Return TRUE if lexeme is present in data, else FALSE. If data is not
* NULL, it should be filled with lexeme positions, but function can leave
* it as zeroes if position data is not available.
*/
typedef bool (*TSExecuteCallback) (void *arg, QueryOperand *val,
ExecPhraseData *data);
@ -151,15 +161,18 @@ typedef bool (*TSExecuteCallback) (void *arg, QueryOperand *val,
/*
* If TS_EXEC_CALC_NOT is not set, then NOT expressions are automatically
* evaluated to be true. Useful in cases where NOT cannot be accurately
* computed (GiST) or it isn't important (ranking).
* computed (GiST) or it isn't important (ranking). From TS_execute's
* perspective, !CALC_NOT means that the TSExecuteCallback function might
* return false-positive indications of a lexeme's presence.
*/
#define TS_EXEC_CALC_NOT (0x01)
/*
* Treat OP_PHRASE as OP_AND. Used when positional information is not
* accessible, like in consistent methods of GIN/GiST indexes; rechecking
* must occur later.
* If TS_EXEC_PHRASE_NO_POS is set, allow OP_PHRASE to be executed lossily
* in the absence of position information: a TRUE result indicates that the
* phrase might be present. Without this flag, OP_PHRASE always returns
* false if lexeme position information is not available.
*/
#define TS_EXEC_PHRASE_AS_AND (0x02)
#define TS_EXEC_PHRASE_NO_POS (0x02)
extern bool TS_execute(QueryItem *curitem, void *arg, uint32 flags,
TSExecuteCallback chkcond);
@ -228,7 +241,7 @@ extern Datum gin_tsquery_consistent_oldsig(PG_FUNCTION_ARGS);
* TSQuery Utilities
*/
extern QueryItem *clean_NOT(QueryItem *ptr, int32 *len);
extern TSQuery cleanup_fakeval_and_phrase(TSQuery in);
extern TSQuery cleanup_tsquery_stopwords(TSQuery in);
typedef struct QTNode
{

12
src/test/regress/expected/tsdicts.out
View File

@ -470,15 +470,15 @@ SELECT to_tsquery('hunspell_tst', 'footballyklubber:b & rebookings:A & sky');
(1 row)
SELECT to_tsquery('hunspell_tst', 'footballyklubber:b <-> sky');
to_tsquery
-----------------------------------------------------------------
'foot':B <-> 'sky' & 'ball':B <-> 'sky' & 'klubber':B <-> 'sky'
to_tsquery
-------------------------------------------------
( 'foot':B & 'ball':B & 'klubber':B ) <-> 'sky'
(1 row)
SELECT phraseto_tsquery('hunspell_tst', 'footballyklubber sky');
phraseto_tsquery
-----------------------------------------------------------
'foot' <-> 'sky' & 'ball' <-> 'sky' & 'klubber' <-> 'sky'
phraseto_tsquery
-------------------------------------------
( 'foot' & 'ball' & 'klubber' ) <-> 'sky'
(1 row)
-- Test ispell dictionary with hunspell affix with FLAG long in configuration

40
src/test/regress/expected/tsearch.out
View File

@ -556,15 +556,15 @@ SELECT plainto_tsquery('english', 'foo bar') && 'asd | fg';
-- Check stop word deletion, a and s are stop-words
SELECT to_tsquery('english', '!(a & !b) & c');
to_tsquery
------------
'b' & 'c'
to_tsquery
-------------
!!'b' & 'c'
(1 row)
SELECT to_tsquery('english', '!(a & !b)');
to_tsquery
------------
'b'
!!'b'
(1 row)
SELECT to_tsquery('english', '(1 <-> 2) <-> a');
@ -1240,15 +1240,15 @@ SELECT ts_rewrite('1 & (2 <2> 3)', 'SELECT keyword, sample FROM test_tsquery'::t
(1 row)
SELECT ts_rewrite('5 <-> (1 & (2 <-> 3))', 'SELECT keyword, sample FROM test_tsquery'::text );
ts_rewrite
---------------------------------------
'5' <-> '1' & '5' <-> ( '2' <-> '3' )
ts_rewrite
-------------------------
'5' <-> ( '2' <-> '4' )
(1 row)
SELECT ts_rewrite('5 <-> (6 | 8)', 'SELECT keyword, sample FROM test_tsquery'::text );
ts_rewrite
---------------------------
'5' <-> '7' | '5' <-> '8'
ts_rewrite
-----------------------
'5' <-> ( '6' | '8' )
(1 row)
-- Check empty substitution
@ -1386,6 +1386,26 @@ SELECT ts_rewrite( query, 'SELECT keyword, sample FROM test_tsquery' ) FROM to_t
'citi' & 'foo' & ( 'bar' | 'qq' ) & ( 'nyc' | 'big' & 'appl' | 'new' & 'york' )
(1 row)
SELECT ts_rewrite(tsquery_phrase('foo', 'foo'), 'foo', 'bar | baz');
ts_rewrite
-----------------------------------------
( 'bar' | 'baz' ) <-> ( 'bar' | 'baz' )
(1 row)
SELECT to_tsvector('foo bar') @@
ts_rewrite(tsquery_phrase('foo', 'foo'), 'foo', 'bar | baz');
?column?
----------
f
(1 row)
SELECT to_tsvector('bar baz') @@
ts_rewrite(tsquery_phrase('foo', 'foo'), 'foo', 'bar | baz');
?column?
----------
t
(1 row)
RESET enable_seqscan;
--test GUC
SET default_text_search_config=simple;

304
src/test/regress/expected/tstypes.out
View File

@ -366,133 +366,6 @@ SELECT '!!a & !!b'::tsquery;
!!'a' & !!'b'
(1 row)
-- phrase transformation
SELECT 'a <-> (b|c)'::tsquery;
tsquery
---------------------------
'a' <-> 'b' | 'a' <-> 'c'
(1 row)
SELECT '(a|b) <-> c'::tsquery;
tsquery
---------------------------
'a' <-> 'c' | 'b' <-> 'c'
(1 row)
SELECT '(a|b) <-> (d|c)'::tsquery;
tsquery
-------------------------------------------------------
'a' <-> 'd' | 'b' <-> 'd' | 'a' <-> 'c' | 'b' <-> 'c'
(1 row)
SELECT 'a <-> (b&c)'::tsquery;
tsquery
---------------------------
'a' <-> 'b' & 'a' <-> 'c'
(1 row)
SELECT '(a&b) <-> c'::tsquery;
tsquery
---------------------------
'a' <-> 'c' & 'b' <-> 'c'
(1 row)
SELECT '(a&b) <-> (d&c)'::tsquery;
tsquery
-------------------------------------------------------
'a' <-> 'd' & 'b' <-> 'd' & 'a' <-> 'c' & 'b' <-> 'c'
(1 row)
SELECT 'a <-> !b'::tsquery;
tsquery
------------------------
'a' & !( 'a' <-> 'b' )
(1 row)
SELECT '!a <-> b'::tsquery;
tsquery
------------------------
!( 'a' <-> 'b' ) & 'b'
(1 row)
SELECT '!a <-> !b'::tsquery;
tsquery
------------------------------------
!'a' & !( !( 'a' <-> 'b' ) & 'b' )
(1 row)
SELECT 'a <-> !(b&c)'::tsquery;
tsquery
--------------------------------------
'a' & !( 'a' <-> 'b' & 'a' <-> 'c' )
(1 row)
SELECT 'a <-> !(b|c)'::tsquery;
tsquery
--------------------------------------
'a' & !( 'a' <-> 'b' | 'a' <-> 'c' )
(1 row)
SELECT '!(a&b) <-> c'::tsquery;
tsquery
--------------------------------------
!( 'a' <-> 'c' & 'b' <-> 'c' ) & 'c'
(1 row)
SELECT '!(a|b) <-> c'::tsquery;
tsquery
--------------------------------------
!( 'a' <-> 'c' | 'b' <-> 'c' ) & 'c'
(1 row)
SELECT '(!a|b) <-> c'::tsquery;
tsquery
--------------------------------------
!( 'a' <-> 'c' ) & 'c' | 'b' <-> 'c'
(1 row)
SELECT '(!a&b) <-> c'::tsquery;
tsquery
--------------------------------------
!( 'a' <-> 'c' ) & 'c' & 'b' <-> 'c'
(1 row)
SELECT 'c <-> (!a|b)'::tsquery;
tsquery
--------------------------------------
'c' & !( 'c' <-> 'a' ) | 'c' <-> 'b'
(1 row)
SELECT 'c <-> (!a&b)'::tsquery;
tsquery
--------------------------------------
'c' & !( 'c' <-> 'a' ) & 'c' <-> 'b'
(1 row)
SELECT '(a|b) <-> !c'::tsquery;
tsquery
------------------------------------------------
( 'a' | 'b' ) & !( 'a' <-> 'c' | 'b' <-> 'c' )
(1 row)
SELECT '(a&b) <-> !c'::tsquery;
tsquery
--------------------------------------------
'a' & 'b' & !( 'a' <-> 'c' & 'b' <-> 'c' )
(1 row)
SELECT '!c <-> (a|b)'::tsquery;
tsquery
-------------------------------------------------
!( 'c' <-> 'a' ) & 'a' | !( 'c' <-> 'b' ) & 'b'
(1 row)
SELECT '!c <-> (a&b)'::tsquery;
tsquery
-------------------------------------------------
!( 'c' <-> 'a' ) & 'a' & !( 'c' <-> 'b' ) & 'b'
(1 row)
--comparisons
SELECT 'a' < 'b & c'::tsquery as "true";
true
@ -568,33 +441,33 @@ SELECT 'foo & bar'::tsquery && 'asd | fg';
(1 row)
SELECT 'a' <-> 'b & d'::tsquery;
?column?
---------------------------
'a' <-> 'b' & 'a' <-> 'd'
?column?
-----------------------
'a' <-> ( 'b' & 'd' )
(1 row)
SELECT 'a & g' <-> 'b & d'::tsquery;
?column?
-------------------------------------------------------
'a' <-> 'b' & 'g' <-> 'b' & 'a' <-> 'd' & 'g' <-> 'd'
?column?
---------------------------------
( 'a' & 'g' ) <-> ( 'b' & 'd' )
(1 row)
SELECT 'a & g' <-> 'b | d'::tsquery;
?column?
-------------------------------------------------------
'a' <-> 'b' & 'g' <-> 'b' | 'a' <-> 'd' & 'g' <-> 'd'
?column?
---------------------------------
( 'a' & 'g' ) <-> ( 'b' | 'd' )
(1 row)
SELECT 'a & g' <-> 'b <-> d'::tsquery;
?column?
---------------------------------------------------
'a' <-> ( 'b' <-> 'd' ) & 'g' <-> ( 'b' <-> 'd' )
?column?
-----------------------------------
( 'a' & 'g' ) <-> ( 'b' <-> 'd' )
(1 row)
SELECT tsquery_phrase('a <3> g', 'b & d', 10);
tsquery_phrase
---------------------------------------------
'a' <3> 'g' <10> 'b' & 'a' <3> 'g' <10> 'd'
tsquery_phrase
--------------------------------
'a' <3> 'g' <10> ( 'b' & 'd' )
(1 row)
-- tsvector-tsquery operations
@ -749,18 +622,18 @@ SELECT to_tsvector('simple', '1 2 3 4') @@ '(1 <-> 2) <-> 3' AS "true";
t
(1 row)
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <-> (2 <-> 3)' AS "false";
false
-------
f
(1 row)
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <2> (2 <-> 3)' AS "true";
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <-> (2 <-> 3)' AS "true";
true
------
t
(1 row)
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <2> (2 <-> 3)' AS "false";
false
-------
f
(1 row)
SELECT to_tsvector('simple', '1 2 1 2 3 4') @@ '(1 <-> 2) <-> 3' AS "true";
true
------
@ -773,6 +646,133 @@ SELECT to_tsvector('simple', '1 2 1 2 3 4') @@ '1 <-> 2 <-> 3' AS "true";
t
(1 row)
-- without position data, phrase search does not match
SELECT strip(to_tsvector('simple', '1 2 3 4')) @@ '1 <-> 2 <-> 3' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'q x q y') @@ 'q <-> (x & y)' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'q x') @@ 'q <-> (x | y <-> z)' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'q y') @@ 'q <-> (x | y <-> z)' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'q y z') @@ 'q <-> (x | y <-> z)' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'q y x') @@ 'q <-> (x | y <-> z)' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'q x y') @@ 'q <-> (x | y <-> z)' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'q x') @@ '(x | y <-> z) <-> q' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'x q') @@ '(x | y <-> z) <-> q' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'x y q') @@ '(x | y <-> z) <-> q' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'x y z') @@ '(x | y <-> z) <-> q' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'x y z q') @@ '(x | y <-> z) <-> q' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'y z q') @@ '(x | y <-> z) <-> q' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'y y q') @@ '(x | y <-> z) <-> q' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'y y q') @@ '(!x | y <-> z) <-> q' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'x y q') @@ '(!x | y <-> z) <-> q' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'y y q') @@ '(x | y <-> !z) <-> q' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'x q') @@ '(x | y <-> !z) <-> q' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'x q') @@ '(!x | y <-> z) <-> q' AS "false";
false
-------
f
(1 row)
select to_tsvector('simple', 'z q') @@ '(!x | y <-> z) <-> q' AS "true";
true
------
t
(1 row)
select to_tsvector('simple', 'x y q y') @@ '!x <-> y' AS "true";
true
------
t
(1 row)
--ranking
SELECT ts_rank(' a:1 s:2C d g'::tsvector, 'a | s');
ts_rank
@ -1002,6 +1002,12 @@ SELECT 'a:1 b:3'::tsvector @@ 'a <3> b'::tsquery AS "false";
f
(1 row)
SELECT 'a:1 b:3'::tsvector @@ 'a <0> a:*'::tsquery AS "true";
true
------
t
(1 row)
-- tsvector editing operations
SELECT strip('w:12B w:13* w:12,5,6 a:1,3* a:3 w asd:1dc asd'::tsvector);
strip

6
src/test/regress/sql/tsearch.sql
View File

@ -447,6 +447,12 @@ SELECT ts_rewrite( query, 'SELECT keyword, sample FROM test_tsquery' ) FROM to_t
SELECT ts_rewrite( query, 'SELECT keyword, sample FROM test_tsquery' ) FROM to_tsquery('english', 'moscow & hotel') AS query;
SELECT ts_rewrite( query, 'SELECT keyword, sample FROM test_tsquery' ) FROM to_tsquery('english', 'bar & new & qq & foo & york') AS query;
SELECT ts_rewrite(tsquery_phrase('foo', 'foo'), 'foo', 'bar | baz');
SELECT to_tsvector('foo bar') @@
ts_rewrite(tsquery_phrase('foo', 'foo'), 'foo', 'bar | baz');
SELECT to_tsvector('bar baz') @@
ts_rewrite(tsquery_phrase('foo', 'foo'), 'foo', 'bar | baz');
RESET enable_seqscan;
--test GUC

56
src/test/regress/sql/tstypes.sql
View File

@ -64,34 +64,6 @@ SELECT 'a & !!b'::tsquery;
SELECT '!!a & b'::tsquery;
SELECT '!!a & !!b'::tsquery;
-- phrase transformation
SELECT 'a <-> (b|c)'::tsquery;
SELECT '(a|b) <-> c'::tsquery;
SELECT '(a|b) <-> (d|c)'::tsquery;
SELECT 'a <-> (b&c)'::tsquery;
SELECT '(a&b) <-> c'::tsquery;
SELECT '(a&b) <-> (d&c)'::tsquery;
SELECT 'a <-> !b'::tsquery;
SELECT '!a <-> b'::tsquery;
SELECT '!a <-> !b'::tsquery;
SELECT 'a <-> !(b&c)'::tsquery;
SELECT 'a <-> !(b|c)'::tsquery;
SELECT '!(a&b) <-> c'::tsquery;
SELECT '!(a|b) <-> c'::tsquery;
SELECT '(!a|b) <-> c'::tsquery;
SELECT '(!a&b) <-> c'::tsquery;
SELECT 'c <-> (!a|b)'::tsquery;
SELECT 'c <-> (!a&b)'::tsquery;
SELECT '(a|b) <-> !c'::tsquery;
SELECT '(a&b) <-> !c'::tsquery;
SELECT '!c <-> (a|b)'::tsquery;
SELECT '!c <-> (a&b)'::tsquery;
--comparisons
SELECT 'a' < 'b & c'::tsquery as "true";
SELECT 'a' > 'b & c'::tsquery as "false";
@ -146,10 +118,33 @@ SELECT to_tsvector('simple', '1 2 11 3') @@ '1:* <-> 3' AS "true";
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <-> 2 <-> 3' AS "true";
SELECT to_tsvector('simple', '1 2 3 4') @@ '(1 <-> 2) <-> 3' AS "true";
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <-> (2 <-> 3)' AS "false";
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <2> (2 <-> 3)' AS "true";
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <-> (2 <-> 3)' AS "true";
SELECT to_tsvector('simple', '1 2 3 4') @@ '1 <2> (2 <-> 3)' AS "false";
SELECT to_tsvector('simple', '1 2 1 2 3 4') @@ '(1 <-> 2) <-> 3' AS "true";
SELECT to_tsvector('simple', '1 2 1 2 3 4') @@ '1 <-> 2 <-> 3' AS "true";
-- without position data, phrase search does not match
SELECT strip(to_tsvector('simple', '1 2 3 4')) @@ '1 <-> 2 <-> 3' AS "false";
select to_tsvector('simple', 'q x q y') @@ 'q <-> (x & y)' AS "false";
select to_tsvector('simple', 'q x') @@ 'q <-> (x | y <-> z)' AS "true";
select to_tsvector('simple', 'q y') @@ 'q <-> (x | y <-> z)' AS "false";
select to_tsvector('simple', 'q y z') @@ 'q <-> (x | y <-> z)' AS "true";
select to_tsvector('simple', 'q y x') @@ 'q <-> (x | y <-> z)' AS "false";
select to_tsvector('simple', 'q x y') @@ 'q <-> (x | y <-> z)' AS "true";
select to_tsvector('simple', 'q x') @@ '(x | y <-> z) <-> q' AS "false";
select to_tsvector('simple', 'x q') @@ '(x | y <-> z) <-> q' AS "true";
select to_tsvector('simple', 'x y q') @@ '(x | y <-> z) <-> q' AS "false";
select to_tsvector('simple', 'x y z') @@ '(x | y <-> z) <-> q' AS "false";
select to_tsvector('simple', 'x y z q') @@ '(x | y <-> z) <-> q' AS "true";
select to_tsvector('simple', 'y z q') @@ '(x | y <-> z) <-> q' AS "true";
select to_tsvector('simple', 'y y q') @@ '(x | y <-> z) <-> q' AS "false";
select to_tsvector('simple', 'y y q') @@ '(!x | y <-> z) <-> q' AS "true";
select to_tsvector('simple', 'x y q') @@ '(!x | y <-> z) <-> q' AS "true";
select to_tsvector('simple', 'y y q') @@ '(x | y <-> !z) <-> q' AS "true";
select to_tsvector('simple', 'x q') @@ '(x | y <-> !z) <-> q' AS "true";
select to_tsvector('simple', 'x q') @@ '(!x | y <-> z) <-> q' AS "false";
select to_tsvector('simple', 'z q') @@ '(!x | y <-> z) <-> q' AS "true";
select to_tsvector('simple', 'x y q y') @@ '!x <-> y' AS "true";
--ranking
SELECT ts_rank(' a:1 s:2C d g'::tsvector, 'a | s');
@ -193,6 +188,7 @@ SELECT 'a:1 b:3'::tsvector @@ 'a <0> b'::tsquery AS "false";
SELECT 'a:1 b:3'::tsvector @@ 'a <1> b'::tsquery AS "false";
SELECT 'a:1 b:3'::tsvector @@ 'a <2> b'::tsquery AS "true";
SELECT 'a:1 b:3'::tsvector @@ 'a <3> b'::tsquery AS "false";
SELECT 'a:1 b:3'::tsvector @@ 'a <0> a:*'::tsquery AS "true";
-- tsvector editing operations