1 @c Copyright (C) 2014-2015 Free Software Foundation, Inc.
2 @c Free Software Foundation, Inc.
3 @c This is part of the GCC manual.
4 @c For copying conditions, see the file gcc.texi.
6 @node Match and Simplify
7 @chapter Match and Simplify
8 @cindex Match and Simplify
10 The GIMPLE and GENERIC pattern matching project match-and-simplify
11 tries to address several issues.
14 @item unify expression simplifications currently spread and duplicated
15 over separate files like fold-const.c, gimple-fold.c and builtins.c
16 @item allow for a cheap way to implement building and simplifying
17 non-trivial GIMPLE expressions, avoiding the need to go through
18 building and simplifying GENERIC via fold_buildN and then
19 gimplifying via force_gimple_operand
22 To address these the project introduces a simple domain specific language
23 to write expression simplifications from which code targeting GIMPLE
24 and GENERIC is auto-generated. The GENERIC variant follows the
25 fold_buildN API while for the GIMPLE variant and to address 2) new
37 @deftypefn {GIMPLE function} tree gimple_simplify (enum tree_code, tree, tree, gimple_seq *, tree (*)(tree))
38 @deftypefnx {GIMPLE function} tree gimple_simplify (enum tree_code, tree, tree, tree, gimple_seq *, tree (*)(tree))
39 @deftypefnx {GIMPLE function} tree gimple_simplify (enum tree_code, tree, tree, tree, tree, gimple_seq *, tree (*)(tree))
40 @deftypefnx {GIMPLE function} tree gimple_simplify (enum built_in_function, tree, tree, gimple_seq *, tree (*)(tree))
41 @deftypefnx {GIMPLE function} tree gimple_simplify (enum built_in_function, tree, tree, tree, gimple_seq *, tree (*)(tree))
42 @deftypefnx {GIMPLE function} tree gimple_simplify (enum built_in_function, tree, tree, tree, tree, gimple_seq *, tree (*)(tree))
43 The main GIMPLE API entry to the expression simplifications mimicing
44 that of the GENERIC fold_@{unary,binary,ternary@} functions.
47 thus providing n-ary overloads for operation or function. The
48 additional arguments are a gimple_seq where built statements are
49 inserted on (if @code{NULL} then simplifications requiring new statements
50 are not performed) and a valueization hook that can be used to
51 tie simplifications to a SSA lattice.
53 In addition to those APIs @code{fold_stmt} is overloaded with
56 @deftypefn bool fold_stmt (gimple_stmt_iterator *, tree (*)(tree));
60 Ontop of these a @code{fold_buildN}-like API for GIMPLE is introduced:
62 @deftypefn {GIMPLE function} tree gimple_build (gimple_seq *, location_t, enum tree_code, tree, tree, tree (*valueize) (tree) = NULL);
63 @deftypefnx {GIMPLE function} tree gimple_build (gimple_seq *, location_t, enum tree_code, tree, tree, tree, tree (*valueize) (tree) = NULL);
64 @deftypefnx {GIMPLE function} tree gimple_build (gimple_seq *, location_t, enum tree_code, tree, tree, tree, tree, tree (*valueize) (tree) = NULL);
65 @deftypefnx {GIMPLE function} tree gimple_build (gimple_seq *, location_t, enum built_in_function, tree, tree, tree (*valueize) (tree) = NULL);
66 @deftypefnx {GIMPLE function} tree gimple_build (gimple_seq *, location_t, enum built_in_function, tree, tree, tree, tree (*valueize) (tree) = NULL);
67 @deftypefnx {GIMPLE function} tree gimple_build (gimple_seq *, location_t, enum built_in_function, tree, tree, tree, tree, tree (*valueize) (tree) = NULL);
68 @deftypefnx {GIMPLE function} tree gimple_convert (gimple_seq *, location_t, tree, tree);
71 which is supposed to replace @code{force_gimple_operand (fold_buildN (...), ...)}
72 and calls to @code{fold_convert}. Overloads without the @code{location_t}
73 argument exist. Built statements are inserted on the provided sequence
74 and simplification is performed using the optional valueization hook.
81 The language to write expression simplifications in resembles other
82 domain-specific languages GCC uses. Thus it is lispy. Lets start
83 with an example from the match.pd file:
87 (bit_and @@0 integer_all_onesp)
91 This example contains all required parts of an expression simplification.
92 A simplification is wrapped inside a @code{(simplify ...)} expression.
93 That contains at least two operands - an expression that is matched
94 with the GIMPLE or GENERIC IL and a replacement expression that is
95 returned if the match was successful.
97 Expressions have an operator ID, @code{bit_and} in this case. Expressions can
98 be lower-case tree codes with @code{_expr} stripped off or builtin
99 function code names in all-caps, like @code{BUILT_IN_SQRT}.
101 @code{@@n} denotes a so-called capture. It captures the operand and lets
102 you refer to it in other places of the match-and-simplify. In the
103 above example it is refered to in the replacement expression. Captures
104 are @code{@@} followed by a number or an identifier.
109 @{ build_zero_cst (type); @})
112 In this example @code{@@0} is mentioned twice which constrains the matched
113 expression to have two equal operands. This example also introduces
114 operands written in C code. These can be used in the expression
115 replacements and are supposed to evaluate to a tree node which has to
116 be a valid GIMPLE operand (so you cannot generate expressions in C code).
120 (trunc_mod integer_zerop@@0 @@1)
121 (if (!integer_zerop (@@1)))
125 Here @code{@@0} captures the first operand of the trunc_mod expression
126 which is also predicated with @code{integer_zerop}. Expression operands
127 may be either expressions, predicates or captures. Captures
128 can be unconstrained or capture expresions or predicates.
130 This example introduces an optional operand of simplify,
131 the if-expression. This condition is evaluated after the
132 expression matched in the IL and is required to evaluate to true
133 to enable the replacement expression. The expression operand
134 of the @code{if} is a standard C expression which may contain references
137 A @code{if} expression can be used to specify a common condition
138 for multiple simplify patterns, avoiding the need
139 to repeat that multiple times:
142 (if (!TYPE_SATURATING (type)
143 && !FLOAT_TYPE_P (type) && !FIXED_POINT_TYPE_P (type))
145 (minus (plus @@0 @@1) @@0)
148 (minus (minus @@0 @@1) @@0)
154 Captures can also be used for capturing results of sub-expressions.
159 (pointer_plus (addr@@2 @@0) INTEGER_CST_P@@1)
160 (if (is_gimple_min_invariant (@@2)))
163 tree base = get_addr_base_and_unit_offset (@@0, &off);
164 off += tree_to_uhwi (@@1);
165 /* Now with that we should be able to simply write
166 (addr (mem_ref (addr @@base) (plus @@off @@1))) */
167 build1 (ADDR_EXPR, type,
168 build2 (MEM_REF, TREE_TYPE (TREE_TYPE (@@2)),
169 build_fold_addr_expr (base),
170 build_int_cst (ptr_type_node, off)));
175 In the above example, @code{@@2} captures the result of the expression
176 @code{(addr @@0)}. For outermost expression only its type can be captured,
177 and the keyword @code{type} is reserved for this purpose. The above
178 example also gives a way to conditionalize patterns to only apply
179 to @code{GIMPLE} or @code{GENERIC} by means of using the pre-defined
180 preprocessor macros @code{GIMPLE} and @code{GENERIC} and using
181 preprocessor directives.
185 (bit_and:c integral_op_p@@0 (bit_ior:c (bit_not @@0) @@1))
189 Here we introduce flags on match expressions. There is currently
190 a single flag, @code{c}, which denotes that the expression should
191 be also matched commutated. Thus the above match expression
192 is really the following four match expressions:
194 (bit_and integral_op_p@@0 (bit_ior (bit_not @@0) @@1))
195 (bit_and (bit_ior (bit_not @@0) @@1) integral_op_p@@0)
196 (bit_and integral_op_p@@0 (bit_ior @@1 (bit_not @@0)))
197 (bit_and (bit_ior @@1 (bit_not @@0)) integral_op_p@@0)
199 Usual canonicalizations you know from GENERIC expressions are
200 applied before matching, so for example constant operands always
201 come second in commutative expressions.
203 More features exist to avoid too much repetition.
206 (for op (plus pointer_plus minus bit_ior bit_xor)
208 (op @@0 integer_zerop)
212 A @code{for} expression can be used to repeat a pattern for each
213 operator specified, substituting @code{op}. @code{for} can be
214 nested and a @code{for} can have multiple operators to iterate.
217 (for opa (plus minus)
219 (for opc (plus minus)
223 In this example the pattern will be repeated four times with
224 @code{opa, opb, opc} being @code{plus, minus, plus},
225 @code{plus, minus, minus}, @code{minus, plus, plus},
226 @code{minus, plus, minus}.
228 To avoid repeating operator lists in @code{for} you can name
232 (define_operator_list pmm plus minus mult)
235 and use them in @code{for} operator lists where they get expanded.
238 (for opa (pmm trunc_div)
242 So this example iterates over @code{plus}, @code{minus}, @code{mult}
243 and @code{trunc_div}.
245 Using operator lists can also remove the need to explicitely write
246 a @code{for}. All operator list uses that appear in a @code{simplify}
247 or @code{match} pattern in operator positions will implicitely
248 be added to a new @code{for}. For example
251 (define_operator_list SQRT BUILT_IN_SQRTF BUILT_IN_SQRT BUILT_IN_SQRTL)
252 (define_operator_list POW BUILT_IN_POWF BUILT_IN_POW BUILT_IN_POWL)
255 (POW (abs @@0) (mult @@1 @{ built_real (TREE_TYPE (@@1), dconsthalf); @})))
261 (for SQRT (BUILT_IN_SQRTF BUILT_IN_SQRT BUILT_IN_SQRTL)
262 POW (BUILT_IN_POWF BUILT_IN_POW BUILT_IN_POWL)
265 (POW (abs @@0) (mult @@1 @{ built_real (TREE_TYPE (@@1), dconsthalf); @}))))
268 Another building block are @code{with} expressions in the
269 result expression which nest the generated code in a new C block
270 followed by its argument:
274 (convert (mult @@0 @@1))
275 (with @{ tree utype = unsigned_type_for (type); @}
276 (convert (mult (convert:utype @@0) (convert:utype @@1)))))
279 This allows code nested in the @code{with} to refer to the declared
280 variables. In the above case we use the feature to specify the
281 type of a generated expression with the @code{:type} syntax where
282 @code{type} needs to be an identifier that refers to the desired type.
283 Usually the types of the generated result expressions are
284 determined from the context, but sometimes like in the above case
285 it is required that you specify them explicitely.
287 As intermediate conversions are often optional there is a way to
288 avoid the need to repeat patterns both with and without such
289 conversions. Namely you can mark a conversion as being optional
294 (eq (convert@@0 @@1) (convert? @@2))
295 (eq @@1 (convert @@2)))
298 which will match both @code{(eq (convert @@1) (convert @@2))} and
299 @code{(eq (convert @@1) @@2)}. The optional converts are supposed
300 to be all either present or not, thus
301 @code{(eq (convert? @@1) (convert? @@2))} will result in two
302 patterns only. If you want to match all four combinations you
303 have access to two additional conditional converts as in
304 @code{(eq (convert1? @@1) (convert2? @@2))}.
306 Predicates available from the GCC middle-end need to be made
307 available explicitely via @code{define_predicates}:
311 integer_onep integer_zerop integer_all_onesp)
314 You can also define predicates using the pattern matching language
315 and the @code{match} form:
320 (if (TYPE_OVERFLOW_WRAPS (type)
321 || may_negate_without_overflow_p (t))))
326 This shows that for @code{match} expressions there is @code{t}
327 available which captures the outermost expression (something
328 not possible in the @code{simplify} context). As you can see
329 @code{match} has an identifier as first operand which is how
330 you refer to the predicate in patterns. Multiple @code{match}
331 for the same identifier add additional cases where the predicate
334 Predicates can also match an expression in which case you need
335 to provide a template specifying the identifier and where to
336 get its operands from:
339 (match (logical_inverted_value @@0)
340 (eq @@0 integer_zerop))
341 (match (logical_inverted_value @@0)
342 (bit_not truth_valued_p@@0))
345 You can use the above predicate like
349 (bit_and @@0 (logical_inverted_value @@0))
350 @{ build_zero_cst (type); @})
353 Which will match a bitwise and of an operand with its logical