Daily bump.
[official-gcc.git] / gcc / ipa-param-manipulation.h
blob0b038ea57f1b46e0c0fb8cb6be60bbed5573e2d3
1 /* Manipulation of formal and actual parameters of functions and function
2 calls.
3 Copyright (C) 2017-2020 Free Software Foundation, Inc.
5 This file is part of GCC.
7 GCC is free software; you can redistribute it and/or modify it under
8 the terms of the GNU General Public License as published by the Free
9 Software Foundation; either version 3, or (at your option) any later
10 version.
12 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
13 WARRANTY; without even the implied warranty of MERCHANTABILITY or
14 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
15 for more details.
17 You should have received a copy of the GNU General Public License
18 along with GCC; see the file COPYING3. If not see
19 <http://www.gnu.org/licenses/>.
23 This file defines classes and other data structures that are used to manipulate
24 the prototype of a function, especially to create, remove or split its formal
25 parameters, but also to remove its return value, and also its call statements
26 correspondingly.
28 The most basic one is a vector of structures ipa_adjusted_param. It is simply
29 a description how the new parameters should look like after the transformation
30 in what way they relate to the previous ones (if in any). Such relation to an
31 old parameter can be an outright copy or an IPA-SRA replacement. If an old
32 parameter is not listed or otherwise mentioned, it is removed as unused or at
33 least unnecessary. Note that this most basic structure does not work for
34 modifying calls of functions with variable number of arguments.
36 Class ipa_param_adjustments is only a little more than a thin encapsulation of
37 a vector of ipa_param_adjustments. Along with this vector it contains an index
38 of the first potential vararg argument and a boolean flag whether the return
39 value should be removed or not. Moreover, the class contains method
40 modify_call which can transform a call statement so that it correctly calls a
41 modified function. These two data structures were designed to have a small
42 memory footprint because they are allocated for each clone of a call graph node
43 that has its prototype changed and live until the end of IPA clone
44 materialization and call redirection phase.
46 On the other hand, class ipa_param_body_adjustments can afford to allocate more
47 data because its life span is much smaller, it is allocated and destroyed in
48 the course of materialization of each single clone that needs it or only when a
49 particular pass needs to change a function it is operating on. This class has
50 various methods required to change function declaration and the body of the
51 function according to instructions given either by class ipa_param_adjustments
52 or only a vector of ipa_adjusted_params.
54 When these classes are used in the context of call graph clone materialization
55 and subsequent call statement redirection - which is the point at which we
56 modify arguments in call statements - they need to cooperate with each other in
57 order to handle what we refer to as transitive (IPA-SRA) splits. These are
58 situations when a formal parameter of one function is split into several
59 smaller ones and some of them are then passed on in a call to another function
60 because the formal parameter of this callee has also been split.
62 Consider a simple example:
64 struct S {int a, b, c;};
65 struct Z {int x; S s;};
67 foo (S s)
69 use (s.b);
72 bar (Z z)
74 use (z.s.a);
75 foo (z.s);
78 baz ()
80 bar (*global);
83 Both bar and foo would have their parameter split. Foo would receive one
84 replacement representing s.b. Function bar would see its parameter split into
85 one replacement representing z.s.a and another representing z.s.b which would
86 be passed on to foo. It would be a so called transitive split IPA-SRA
87 replacement, one which is passed in a call as an actual argument to another
88 IPA-SRA replacement in another function.
90 Note that the call chain the example can be arbitrarily long and recursive and
91 that any function in it can be cloned by another IPA pass and any number of
92 adjacent functions in the call chain can be inlined into each other. Call
93 redirection takes place only after bodies of the function have been modified by
94 all of the above.
96 Call redirection has to be able to find the right decl or SSA_NAME that
97 corresponds to the transitive split in the caller. The SSA names are assigned
98 right after clone materialization/ modification and cannot be "added"
99 afterwards. Moreover, if the caller has been inlined the SSA_NAMEs in question
100 no longer belong to PARM_DECLs but to VAR_DECLs, indistinguishable from any
101 others.
103 Therefore, when clone materialization finds a call statement which it knows is
104 a part of a transitive split, it will modify it into:
106 foo (DUMMY_Z_VAR.s, repl_for_a, repl_for_b, <rest of original arguments>);
108 It will also store {DUMMY_S_VAR, 32} and {DUMMY_S_VAR, 64} representing offsets
109 of z.s.a and z.s.b (assuming a 32-bit int) into foo's cgraph node
110 clone->performed_splits vector (which is storing structures of type
111 ipa_param_performed_split also defined in this header file).
113 Call redirection will identify that expression DUMMY_Z_VAR.s is based on a
114 variable stored in performed_splits vector and learn that the following
115 arguments, already in SSA form, represent offsets 32 and 64 in a split original
116 parameter. It subtracts offset of DUMMY_Z_VAR.s from 32 and 64 and arrives at
117 offsets 0 and 32 within callee's original parameter. At this point it also
118 knows from the call graph that only the bit with offset 32 is needed and so
119 changes the call statement into final:
121 bar (repl_for_b, <rest of original arguments>); */
123 #ifndef IPA_PARAM_MANIPULATION_H
124 #define IPA_PARAM_MANIPULATION_H
126 /* Indices into ipa_param_prefixes to identify a human-readable prefix for newly
127 synthesized parameters. Keep in sync with the array. */
128 enum ipa_param_name_prefix_indices
130 IPA_PARAM_PREFIX_SYNTH,
131 IPA_PARAM_PREFIX_ISRA,
132 IPA_PARAM_PREFIX_SIMD,
133 IPA_PARAM_PREFIX_MASK,
134 IPA_PARAM_PREFIX_COUNT
137 /* We do not support manipulating functions with more than
138 1<<IPA_PARAM_MAX_INDEX_BITS parameters. */
139 #define IPA_PARAM_MAX_INDEX_BITS 16
141 /* Operation to be performed for the parameter in ipa_parm_adjustment
142 below. */
144 enum ipa_parm_op
146 /* Do not use or you will trigger an assert. */
147 IPA_PARAM_OP_UNDEFINED,
149 /* This new parameter is an unmodified parameter at index base_index. */
150 IPA_PARAM_OP_COPY,
152 /* This describes a brand new parameter. If it somehow relates to any
153 original parameters, the user needs to manage the transition itself. */
154 IPA_PARAM_OP_NEW,
156 /* Split parameter as indicated by fields base_index, offset and type. */
157 IPA_PARAM_OP_SPLIT
160 /* Structure that describes one parameter of a function after transformation.
161 Omitted parameters will be removed. */
163 struct GTY(()) ipa_adjusted_param
165 /* Type of the new parameter. Required for all operations except
166 IPA_PARM_OP_COPY when the original type will be preserved. */
167 tree type;
169 /* Alias reference type to be used in MEM_REFs when adjusting caller
170 arguments. Required for IPA_PARM_OP_SPLIT operation. */
171 tree alias_ptr_type;
173 /* Offset into the original parameter (for the cases when the new parameter
174 is a component of an original one). Required for IPA_PARM_OP_SPLIT
175 operation. */
176 unsigned unit_offset;
178 /* Zero based index of the original parameter this one is based on. Required
179 for IPA_PARAM_OP_COPY and IPA_PARAM_OP_SPLIT, users of IPA_PARAM_OP_NEW
180 only need to specify it if they use replacement lookup provided by
181 ipa_param_body_adjustments. */
182 unsigned base_index : IPA_PARAM_MAX_INDEX_BITS;
184 /* Zero based index of the parameter this one is based on in the previous
185 clone. If there is no previous clone, it must be equal to base_index. */
186 unsigned prev_clone_index : IPA_PARAM_MAX_INDEX_BITS;
188 /* Specify the operation, if any, to be performed on the parameter. */
189 enum ipa_parm_op op : 2;
191 /* If set, this structure describes a parameter copied over from a previous
192 IPA clone, any transformations are thus not to be re-done. */
193 unsigned prev_clone_adjustment : 1;
195 /* Index into ipa_param_prefixes specifying a prefix to be used with
196 DECL_NAMEs of newly synthesized parameters. */
197 unsigned param_prefix_index : 2;
199 /* Storage order of the original parameter (for the cases when the new
200 parameter is a component of an original one). */
201 unsigned reverse : 1;
203 /* A bit free for the user. */
204 unsigned user_flag : 1;
207 void ipa_dump_adjusted_parameters (FILE *f,
208 vec<ipa_adjusted_param, va_gc> *adj_params);
210 /* Structure to remember the split performed on a node so that edge redirection
211 (i.e. splitting arguments of call statements) know how split formal
212 parameters of the caller are represented. */
214 struct GTY(()) ipa_param_performed_split
216 /* The dummy VAR_DECL that was created instead of the split parameter that
217 sits in the call in the meantime between clone materialization and call
218 redirection. All entries in a vector of performed splits that correspond
219 to the same dumy decl must be grouped together. */
220 tree dummy_decl;
221 /* Offset into the original parameter. */
222 unsigned unit_offset;
225 /* Class used to record planned modifications to parameters of a function and
226 also to perform necessary modifications at the caller side at the gimple
227 level. Used to describe all cgraph node clones that have their parameters
228 changed, therefore the class should only have a small memory footprint. */
230 class GTY(()) ipa_param_adjustments
232 public:
233 /* Constructor from NEW_PARAMS showing how new parameters should look like
234 plus copying any pre-existing actual arguments starting from argument
235 with index ALWAYS_COPY_START (if non-negative, negative means do not copy
236 anything beyond what is described in NEW_PARAMS), and SKIP_RETURN, which
237 indicates that the function should return void after transformation. */
239 ipa_param_adjustments (vec<ipa_adjusted_param, va_gc> *new_params,
240 int always_copy_start, bool skip_return)
241 : m_adj_params (new_params), m_always_copy_start (always_copy_start),
242 m_skip_return (skip_return)
245 /* Modify a call statement arguments (and possibly remove the return value)
246 as described in the data fields of this class. */
247 gcall *modify_call (gcall *stmt,
248 vec<ipa_param_performed_split, va_gc> *performed_splits,
249 tree callee_decl, bool update_references);
250 /* Return if the first parameter is left intact. */
251 bool first_param_intact_p ();
252 /* Build a function type corresponding to the modified call. */
253 tree build_new_function_type (tree old_type, bool type_is_original_p);
254 /* Build a declaration corresponding to the target of the modified call. */
255 tree adjust_decl (tree orig_decl);
256 /* Fill a vector marking which parameters are intact by the described
257 modifications. */
258 void get_surviving_params (vec<bool> *surviving_params);
259 /* Fill a vector with new indices of surviving original parameters. */
260 void get_updated_indices (vec<int> *new_indices);
261 /* Return the original index for the given new parameter index. Return a
262 negative number if not available. */
263 int get_original_index (int newidx);
265 void dump (FILE *f);
266 void debug ();
268 /* How the known part of arguments should look like. */
269 vec<ipa_adjusted_param, va_gc> *m_adj_params;
271 /* If non-negative, copy any arguments starting at this offset without any
272 modifications so that functions with variable number of arguments can be
273 modified. This number should be equal to the number of original forma
274 parameters. */
275 int m_always_copy_start;
276 /* If true, make the function not return any value. */
277 bool m_skip_return;
279 private:
280 ipa_param_adjustments () {}
282 void init (vec<tree> *cur_params);
283 int get_max_base_index ();
284 bool method2func_p (tree orig_type);
287 /* Structure used to map expressions accessing split or replaced parameters to
288 new PARM_DECLs. */
290 struct ipa_param_body_replacement
292 /* The old decl of the original parameter. */
293 tree base;
294 /* The new decl it should be replaced with. */
295 tree repl;
296 /* When modifying clones during IPA clone materialization, this is a dummy
297 decl used to mark calls in which we need to apply transitive splitting,
298 these dummy delcls are inserted as arguments to such calls and then
299 followed by all the replacements with offset info stored in
300 ipa_param_performed_split.
302 Users of ipa_param_body_adjustments that modify standalone functions
303 outside of IPA clone materialization can use this field for their internal
304 purposes. */
305 tree dummy;
306 /* The offset within BASE that REPL represents. */
307 unsigned unit_offset;
310 struct ipa_replace_map;
312 /* Class used when actually performing adjustments to formal parameters of a
313 function to map accesses that need to be replaced to replacements. The
314 class attempts to work in two very different sets of circumstances: as a
315 part of tree-inine.c's tree_function_versioning machinery to clone functions
316 (when M_ID is not NULL) and in s standalone fashion, modifying an existing
317 function in place (when M_ID is NULL). While a lot of stuff handled in a
318 unified way in both modes, there are many aspects of the processs that
319 requires distinct paths. */
321 class ipa_param_body_adjustments
323 public:
324 /* Constructor to use from within tree-inline. */
325 ipa_param_body_adjustments (ipa_param_adjustments *adjustments,
326 tree fndecl, tree old_fndecl,
327 struct copy_body_data *id, tree *vars,
328 vec<ipa_replace_map *, va_gc> *tree_map);
329 /* Constructor to use for modifying a function outside of tree-inline from an
330 instance of ipa_param_adjustments. */
331 ipa_param_body_adjustments (ipa_param_adjustments *adjustments,
332 tree fndecl);
333 /* Constructor to use for modifying a function outside of tree-inline from a
334 simple vector of desired parameter modification. */
335 ipa_param_body_adjustments (vec<ipa_adjusted_param, va_gc> *adj_params,
336 tree fndecl);
338 /* The do-it-all function for modifying a function outside of
339 tree-inline. */
340 bool perform_cfun_body_modifications ();
342 /* Change the PARM_DECLs. */
343 void modify_formal_parameters ();
344 /* Register a replacement decl for the transformation done in APM. */
345 void register_replacement (ipa_adjusted_param *apm, tree replacement,
346 tree dummy = NULL_TREE);
347 /* Lookup a replacement for a given offset within a given parameter. */
348 tree lookup_replacement (tree base, unsigned unit_offset);
349 /* Lookup a replacement for an expression, if there is one. */
350 ipa_param_body_replacement *get_expr_replacement (tree expr,
351 bool ignore_default_def);
352 /* Lookup the new base for surviving names previously belonging to a
353 parameter. */
354 tree get_replacement_ssa_base (tree old_decl);
355 /* Modify a statement. */
356 bool modify_gimple_stmt (gimple **stmt, gimple_seq *extra_stmts);
357 /* Return the new chain of parameters. */
358 tree get_new_param_chain ();
360 /* Pointers to data structures defining how the function should be
361 modified. */
362 vec<ipa_adjusted_param, va_gc> *m_adj_params;
363 ipa_param_adjustments *m_adjustments;
365 /* Vector of old parameter declarations that must have their debug bind
366 statements re-mapped and debug decls created. */
368 auto_vec<tree, 16> m_reset_debug_decls;
370 /* Set to true if there are any IPA_PARAM_OP_SPLIT adjustments among stored
371 adjustments. */
372 bool m_split_modifications_p;
373 private:
374 void common_initialization (tree old_fndecl, tree *vars,
375 vec<ipa_replace_map *, va_gc> *tree_map);
376 tree carry_over_param (tree t);
377 unsigned get_base_index (ipa_adjusted_param *apm);
378 ipa_param_body_replacement *lookup_replacement_1 (tree base,
379 unsigned unit_offset);
380 tree replace_removed_params_ssa_names (tree old_name, gimple *stmt);
381 bool modify_expression (tree *expr_p, bool convert);
382 bool modify_assignment (gimple *stmt, gimple_seq *extra_stmts);
383 bool modify_call_stmt (gcall **stmt_p);
384 bool modify_cfun_body ();
385 void reset_debug_stmts ();
387 /* Declaration of the function that is being transformed. */
389 tree m_fndecl;
391 /* If non-NULL, the tree-inline master data structure guiding materialization
392 of the current clone. */
393 struct copy_body_data *m_id;
395 /* Vector of old parameter declarations (before changing them). */
397 auto_vec<tree, 16> m_oparms;
399 /* Vector of parameter declarations the function will have after
400 transformation. */
402 auto_vec<tree, 16> m_new_decls;
404 /* If the function type has non-NULL TYPE_ARG_TYPES, this is the vector of
405 these types after transformation, otherwise an empty one. */
407 auto_vec<tree, 16> m_new_types;
409 /* Vector of structures telling how to replace old parameters in the
410 function body. TODO: Even though there usually be only few, but should we
411 use a hash? */
413 auto_vec<ipa_param_body_replacement, 16> m_replacements;
415 /* Vector for remapping SSA_BASES from old parameter declarations that are
416 being removed as a part of the transformation. Before a new VAR_DECL is
417 created, it holds the old PARM_DECL, once the variable is built it is
418 stored here. */
420 auto_vec<tree> m_removed_decls;
422 /* Hash to quickly lookup the item in m_removed_decls given the old decl. */
424 hash_map<tree, unsigned> m_removed_map;
426 /* True iff the transformed function is a class method that is about to loose
427 its this pointer and must be converted to a normal function. */
429 bool m_method2func;
432 void push_function_arg_decls (vec<tree> *args, tree fndecl);
433 void push_function_arg_types (vec<tree> *types, tree fntype);
435 #endif /* IPA_PARAM_MANIPULATION_H */