com.rabbitmq.jms.parse.sql.SqlProduction Maven / Gradle / Ivy
/* Copyright (c) 2013 Pivotal Software, Inc. All rights reserved. */
package com.rabbitmq.jms.parse.sql;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.BINARYOP;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.COLLAPSE1;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.COLLAPSE2;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.CONJUNCTION;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.DISJUNCTION;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.JOINLIST;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.LEAF;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.LIST;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.PATTERN1;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.PATTERN2;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.POSTFIXUNARYOP;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.PREFIXUNARYOP;
import static com.rabbitmq.jms.parse.sql.SqlTreeType.TERNARYOP;
import com.rabbitmq.jms.parse.Multiples.Pair;
import com.rabbitmq.jms.parse.TokenStream;
/**
* This describes the SQL grammar in terms of the tokens {@link SqlTokenType}.
*
* For each grammar production, we match the alternatives in turn. For each alternative, we match the terms in sequence
* until we reach the end of the sequence. If we reach the end with all matched we return the resulting tree
* constructed from the sequence of terms matched (using a SqlTreeNodeType for that purpose), otherwise we go to the next alternative.
* If we run out of alternatives, and none of them matched, we return null
.
*
*
* The top-level expression should check, after matching correctly, that we have consumed all the tokens from the input
* stream. If so, then we are good to go. If not, the top-level expression has failed to match everything, and we can report the
* next few tokens to indicate where the failure occurred.
*
*
* The order of a production’s alternatives is important, we match those with more tokens first, where the prefixes are the same.
*
*
* The grammar, where the uppercase terms are terminals ({@link SqlTokenType}s) and the lowercase terms are non-terminals,
* is completely defined by the alternatives in the productions declared below. For example:
*
* or_expr -> and_expr OR or_expr
* | and_expr
*
* corresponds to the production declaration:
*
* or_expr ( cAlt( "and_expr OR or_expr" , DISJUNCTION )
* , cAlt( "and_expr" , COLLAPSE1 ) ),
*
* where each alternative is coded. (Because Java will not allow pre-reference of enum constants in enum definitions we cannot
* use the productions directly but must encode them (in this case as an array of strings); they are decoded during parsing.)
*
*
* Each alternative gets a sequence of productions (terminal or non-terminal) and a production action ({@link SqlTreeType}); the sequence
* is matched in order to match the alternative. The parser algorithm (for each production) treats the alternatives
* in declared order and accepts the first one that matches fully.
*
*
* Each production {@link SqlProduction} knows how to parse itself. This is the algorithm encoded in {@link #parse()} which recursively
* calls each potential sub-expression to parse a sequence. The terminal nodes know how to parse themselves (they are just single tokens),
* and progress has to be made (in the token sequence) so the recursion will terminate eventually, provided the grammar is well-defined.
*
*
* The parse tree is constructed using the {@link SqlTreeType} for a matched alternative (or LEAF in the case of a terminal). The
* parsed terms of the alternative are passed to the {@link SqlTreeType} to construct the tree of this type.
* Each terminal {@link SqlTokenType} is a LEAF in the tree and the token value is the value of the node.
*
*
* Non-terminals are associated with an array of coded alternatives; each coded alternative is an {@link SqlTreeType} and a {@link String} array.
* Each string in the array is the name of a {@link SqlProduction}.
*
*
* I would have liked to use {@link SqlProduction} explicitly, but Java doesn't let me use an enumerated type term in
* the definition of a term, unless it has been defined lexically beforehand (!) so I use strings instead!!
*
*
* Terminals are simply proxies for a {@link SqlTokenType} and have no alternatives.
*
*
* The root of the grammar is expression
, exposed in ROOT
.
*
*/
enum SqlProduction {
// non-terminals: grammar_alternative_______________________________ SqlTreeType
expression( cAlt( "or_expr" , COLLAPSE1 ) ),
or_expr ( cAlt( "and_expr OR or_expr" , DISJUNCTION )
, cAlt( "and_expr" , COLLAPSE1 ) ),
and_expr ( cAlt( "not_expr AND and_expr" , CONJUNCTION )
, cAlt( "not_expr" , COLLAPSE1 ) ),
not_expr ( cAlt( "NOT cmp_expr" , PREFIXUNARYOP )
, cAlt( "cmp_expr" , COLLAPSE1 ) ),
cmp_expr ( cAlt( "arith_expr op_cmp arith_expr" , BINARYOP )
, cAlt( "arith_expr BETWEEN arith_expr AND arith_expr" , TERNARYOP )
, cAlt( "arith_expr NOT_BETWEEN arith_expr AND arith_expr" , TERNARYOP )
, cAlt( "arith_expr" , COLLAPSE1 ) ),
op_cmp ( cAlt( "CMP_EQ" , LEAF )
, cAlt( "CMP_NEQ" , LEAF )
, cAlt( "CMP_LTEQ" , LEAF )
, cAlt( "CMP_GTEQ" , LEAF )
, cAlt( "CMP_LT" , LEAF )
, cAlt( "CMP_GT" , LEAF ) ),
op_plus ( cAlt( "OP_PLUS" , LEAF )
, cAlt( "OP_MINUS" , LEAF ) ),
op_mult ( cAlt( "OP_MULT" , LEAF )
, cAlt( "OP_DIV" , LEAF ) ),
arith_expr( cAlt( "plus_expr" , COLLAPSE1 ) ),
plus_expr ( cAlt( "mult_expr op_plus plus_expr" , BINARYOP )
, cAlt( "mult_expr" , COLLAPSE1 ) ),
mult_expr ( cAlt( "sign_expr op_mult mult_expr" , BINARYOP )
, cAlt( "sign_expr" , COLLAPSE1 ) ),
sign_expr ( cAlt( "op_plus sign_expr" , PREFIXUNARYOP )
, cAlt( "simple" , COLLAPSE1 ) ),
simple ( cAlt( "LP expression RP" , COLLAPSE2 )
, cAlt( "TRUE" , LEAF )
, cAlt( "FALSE" , LEAF )
, cAlt( "STRING" , LEAF )
, cAlt( "number" , COLLAPSE1 )
, cAlt( "IDENT NULL" , POSTFIXUNARYOP )
, cAlt( "IDENT NOT_NULL" , POSTFIXUNARYOP )
, cAlt( "IDENT IN stringlist" , BINARYOP )
, cAlt( "IDENT NOT_IN stringlist" , BINARYOP )
, cAlt( "IDENT LIKE pattern" , BINARYOP )
, cAlt( "IDENT NOT_LIKE pattern" , BINARYOP )
, cAlt( "IDENT" , LEAF ) ),
stringlist( cAlt( "LP strings RP" , COLLAPSE2 ) ),
strings ( cAlt( "STRING COMMA strings" , JOINLIST )
, cAlt( "STRING" , LIST ) ),
pattern ( cAlt( "STRING ESCAPE STRING" , PATTERN2 )
, cAlt( "STRING" , PATTERN1 ) ),
number ( cAlt( "HEX" , LEAF )
, cAlt( "FLOAT" , LEAF )
, cAlt( "INT" , LEAF ) ),
// terminals:
LIKE (SqlTokenType.LIKE ),
NOT_LIKE (SqlTokenType.NOT_LIKE ),
IN (SqlTokenType.IN ),
NOT_IN (SqlTokenType.NOT_IN ),
NULL (SqlTokenType.NULL ),
NOT_NULL (SqlTokenType.NOT_NULL ),
BETWEEN (SqlTokenType.BETWEEN ),
NOT_BETWEEN (SqlTokenType.NOT_BETWEEN),
AND (SqlTokenType.AND ),
OR (SqlTokenType.OR ),
NOT (SqlTokenType.NOT ),
ESCAPE (SqlTokenType.ESCAPE ),
TRUE (SqlTokenType.TRUE ),
FALSE (SqlTokenType.FALSE ),
CMP_EQ (SqlTokenType.CMP_EQ ),
CMP_NEQ (SqlTokenType.CMP_NEQ ),
CMP_LTEQ (SqlTokenType.CMP_LTEQ ),
CMP_GTEQ (SqlTokenType.CMP_GTEQ ),
CMP_LT (SqlTokenType.CMP_LT ),
CMP_GT (SqlTokenType.CMP_GT ),
OP_PLUS (SqlTokenType.OP_PLUS ),
OP_MINUS (SqlTokenType.OP_MINUS ),
OP_MULT (SqlTokenType.OP_MULT ),
OP_DIV (SqlTokenType.OP_DIV ),
COMMA (SqlTokenType.COMMA ),
LP (SqlTokenType.LP ),
RP (SqlTokenType.RP ),
IDENT (SqlTokenType.IDENT ),
STRING (SqlTokenType.STRING ),
FLOAT (SqlTokenType.FLOAT ),
INT (SqlTokenType.INT ),
HEX (SqlTokenType.HEX ),
;
public static final SqlProduction ROOT = expression;
private final SqlTokenType tokenType;
private final CodedAlternative[] codedAlts;
/**
* Constructor for non-terminals
* @param alts - (array of) alternatives
*/
SqlProduction(CodedAlternative ... alts) {
this.tokenType = null;
this.codedAlts = alts;
}
/**
* Constructor for terminals
* @param tokenType - terminal token type
*/
SqlProduction(SqlTokenType tokenType) {
this.tokenType = tokenType;
this.codedAlts = null;
}
/**
* Recursive descent parser for a particular production.
* @param ts - token stream to parse
* @return null
if this production cannot be (fully) matched immediately next in the stream,
* otherwise returns the constructed tree for this production with the stream set past the tokens used for it.
*/
SqlParseTree parse(TokenStream ts) {
if (this.tokenType != null) {
// terminal:
if (isTokenRightType(ts.readToken(), this.tokenType))
return new SqlParseTree(new SqlTreeNode(LEAF, ts.getNext())); // return single node tree
} else {
// non-terminal:
int startPosition = ts.position();
AlternativeParser altParser = new AlternativeParser(ts);
// Match each subsequent alternative until one fully matches
for (CodedAlternative codedAlt : this.codedAlts) {
if (altParser.match(codedAlt.alternative())) {
return codedAlt.treeType().tree(altParser.getMatchedChildren());
}
}
// We drop through if none of the alternatives matched fully.
ts.reset(startPosition);
}
return null;
}
private static final class AlternativeParser {
private static final SqlProduction[] EMPTY_ALTERNATIVE = new SqlProduction[0];
private static final SqlParseTree[] EMPTY_SUBTREES = new SqlParseTree[0];
private final TokenStream tokenStream;
private final int startPosition;
private SqlProduction[] alternative;
private SqlParseTree[] subtrees;
private int numberMatched;
// invariant: alternative.length == subtrees.length
// subtrees[i] is the parsed tree of alternative[i], for i in 0..numberMatched-1
// tokenStream from startPosition to tokenStream.position() contains the tokens which parse to subtrees[0..numberMatched-1]
AlternativeParser(TokenStream tokenStream) {
this.tokenStream = tokenStream;
this.startPosition = tokenStream.position();
this.alternative = EMPTY_ALTERNATIVE;
this.subtrees = EMPTY_SUBTREES;
this.numberMatched = 0;
}
boolean match(SqlProduction[] alt) {
setNewAlternative(alt);
for (int term=this.numberMatched; term < this.subtrees.length; ++term, ++this.numberMatched) {
this.subtrees[term] = this.alternative[term].parse(this.tokenStream);
if (null == this.subtrees[term]) break;
}
return isFullyMatched();
}
private void setNewAlternative(SqlProduction[] alt) {
SqlParseTree[] newSubtrees = new SqlParseTree[alt.length];
if (canUsePreviousMatches(alt)) {
System.arraycopy(this.subtrees, 0, newSubtrees, 0, this.numberMatched);
} else {
this.numberMatched = 0;
this.tokenStream.reset(this.startPosition);
}
this.alternative = alt;
this.subtrees = newSubtrees;
}
private boolean canUsePreviousMatches(SqlProduction[] alt) {
if (this.numberMatched > alt.length) return false;
for (int i=0; i < this.numberMatched; ++i) {
if (alt[i] != this.alternative[i]) return false;
}
return true;
}
private boolean isFullyMatched() {
return this.numberMatched == this.subtrees.length;
}
SqlParseTree[] getMatchedChildren() {
return isFullyMatched() ? this.subtrees : null;
}
}
/** @return true
if tok
is a {@link SqlToken} of the correct type. */
private static final boolean isTokenRightType(SqlToken tok, SqlTokenType tokType) {
return (tok != null && tok.type() == tokType);
}
/**
* Non-terminal coded alternative (array of these used to declare non-terminals)
* @param terms - string of production names
* @param treeNodeType - type of tree to construct if matched
* @return a coded grammar alternative for a production
*/
private static final CodedAlternative cAlt(String terms, SqlTreeType treeNodeType) {
return new CodedAlternative(treeNodeType, terms.split(" "));
}
/**
* An alternative is coded as a specialisation of a simple {@link Pair} which initially just stores the coded form.
* The accessor methods {@link #alternative()} and {@link #treeType()}
* do the necessary decoding (to an array of {@link SqlProduction} and a {@link SqlTreeType} respectively).
*/
private static final class CodedAlternative extends Pair {
public CodedAlternative(SqlTreeType l, String[] r) { super(l, r); }
/** Get array of productions: the term sequence of the alternative */
public SqlProduction[] alternative() { return aValueOf(this.right()); }
/** Get the type of tree to construct for this alternative */
public SqlTreeType treeType() { return this.left(); }
/**
* Convert array of {@link String}s to array of {@link SqlProduction}s
*/
private static final SqlProduction[] aValueOf(String[] ss) {
SqlProduction[] scts = new SqlProduction[ss.length];
for (int i=0; i