/* IPA function body analysis. Copyright (C) 2003-2019 Free Software Foundation, Inc. Contributed by Jan Hubicka This file is part of GCC. GCC is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GCC is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GCC; see the file COPYING3. If not see . */ #ifndef GCC_IPA_SUMMARY_H #define GCC_IPA_SUMMARY_H #include "sreal.h" #include "ipa-predicate.h" /* Hints are reasons why IPA heuristics should preffer specializing given function. They are represtented as bitmap of the following values. */ enum ipa_hints_vals { /* When specialization turns indirect call into a direct call, it is good idea to do so. */ INLINE_HINT_indirect_call = 1, /* Inlining may make loop iterations or loop stride known. It is good idea to do so because it enables loop optimizatoins. */ INLINE_HINT_loop_iterations = 2, INLINE_HINT_loop_stride = 4, /* Inlining within same strongly connected component of callgraph is often a loss due to increased stack frame usage and prologue setup costs. */ INLINE_HINT_same_scc = 8, /* Inlining functions in strongly connected component is not such a great win. */ INLINE_HINT_in_scc = 16, /* If function is declared inline by user, it may be good idea to inline it. Set by simple_edge_hints in ipa-inline-analysis.c. */ INLINE_HINT_declared_inline = 32, /* Programs are usually still organized for non-LTO compilation and thus if functions are in different modules, inlining may not be so important. Set by simple_edge_hints in ipa-inline-analysis.c. */ INLINE_HINT_cross_module = 64, /* If array indexes of loads/stores become known there may be room for further optimization. */ INLINE_HINT_array_index = 128, /* We know that the callee is hot by profile. */ INLINE_HINT_known_hot = 256 }; typedef int ipa_hints; /* Simple description of whether a memory load or a condition refers to a load from an aggregate and if so, how and where from in the aggregate. Individual fields have the same meaning like fields with the same name in struct condition. */ struct agg_position_info { HOST_WIDE_INT offset; bool agg_contents; bool by_ref; }; /* Representation of function body size and time depending on the call context. We keep simple array of record, every containing of predicate and time/size to account. */ struct GTY(()) size_time_entry { /* Predicate for code to be executed. */ predicate exec_predicate; /* Predicate for value to be constant and optimized out in a specialized copy. When deciding on specialization this makes it possible to see how much the executed code paths will simplify. */ predicate nonconst_predicate; int size; sreal GTY((skip)) time; }; /* Function inlining information. */ struct GTY(()) ipa_fn_summary { /* Keep all field empty so summary dumping works during its computation. This is useful for debugging. */ ipa_fn_summary () : estimated_self_stack_size (0), self_size (0), min_size (0), inlinable (false), single_caller (false), fp_expressions (false), estimated_stack_size (false), stack_frame_offset (false), time (0), size (0), conds (NULL), size_time_table (NULL), loop_iterations (NULL), loop_stride (NULL), array_index (NULL), growth (0), scc_no (0) { } /* Copy constructor. */ ipa_fn_summary (const ipa_fn_summary &s) : estimated_self_stack_size (s.estimated_self_stack_size), self_size (s.self_size), min_size (s.min_size), inlinable (s.inlinable), single_caller (s.single_caller), fp_expressions (s.fp_expressions), estimated_stack_size (s.estimated_stack_size), stack_frame_offset (s.stack_frame_offset), time (s.time), size (s.size), conds (s.conds), size_time_table (s.size_time_table), loop_iterations (s.loop_iterations), loop_stride (s.loop_stride), array_index (s.array_index), growth (s.growth), scc_no (s.scc_no) {} /* Default constructor. */ ~ipa_fn_summary (); /* Information about the function body itself. */ /* Estimated stack frame consumption by the function. */ HOST_WIDE_INT estimated_self_stack_size; /* Size of the function body. */ int self_size; /* Minimal size increase after inlining. */ int min_size; /* False when there something makes inlining impossible (such as va_arg). */ unsigned inlinable : 1; /* True wen there is only one caller of the function before small function inlining. */ unsigned int single_caller : 1; /* True if function contains any floating point expressions. */ unsigned int fp_expressions : 1; /* Information about function that will result after applying all the inline decisions present in the callgraph. Generally kept up to date only for functions that are not inline clones. */ /* Estimated stack frame consumption by the function. */ HOST_WIDE_INT estimated_stack_size; /* Expected offset of the stack frame of function. */ HOST_WIDE_INT stack_frame_offset; /* Estimated size of the function after inlining. */ sreal GTY((skip)) time; int size; /* Conditional size/time information. The summaries are being merged during inlining. */ conditions conds; vec *size_time_table; /* Predicate on when some loop in the function becomes to have known bounds. */ predicate * GTY((skip)) loop_iterations; /* Predicate on when some loop in the function becomes to have known stride. */ predicate * GTY((skip)) loop_stride; /* Predicate on when some array indexes become constants. */ predicate * GTY((skip)) array_index; /* Estimated growth for inlining all copies of the function before start of small functions inlining. This value will get out of date as the callers are duplicated, but using up-to-date value in the badness metric mean a lot of extra expenses. */ int growth; /* Number of SCC on the beginning of inlining process. */ int scc_no; /* Record time and size under given predicates. */ void account_size_time (int, sreal, const predicate &, const predicate &); /* We keep values scaled up, so fractional sizes can be accounted. */ static const int size_scale = 2; }; class GTY((user)) ipa_fn_summary_t: public fast_function_summary { public: ipa_fn_summary_t (symbol_table *symtab): fast_function_summary (symtab) {} static ipa_fn_summary_t *create_ggc (symbol_table *symtab) { struct ipa_fn_summary_t *summary = new (ggc_alloc ()) ipa_fn_summary_t (symtab); summary->disable_insertion_hook (); return summary; } /* Remove ipa_fn_summary for all callees of NODE. */ void remove_callees (cgraph_node *node); virtual void insert (cgraph_node *, ipa_fn_summary *); virtual void remove (cgraph_node *node, ipa_fn_summary *) { remove_callees (node); } virtual void duplicate (cgraph_node *src, cgraph_node *dst, ipa_fn_summary *src_data, ipa_fn_summary *dst_data); }; extern GTY(()) fast_function_summary *ipa_fn_summaries; /* Information kept about callgraph edges. */ struct ipa_call_summary { /* Keep all field empty so summary dumping works during its computation. This is useful for debugging. */ ipa_call_summary () : predicate (NULL), param (vNULL), call_stmt_size (0), call_stmt_time (0), loop_depth (0), is_return_callee_uncaptured (false) { } /* Copy constructor. */ ipa_call_summary (const ipa_call_summary &s): predicate (s.predicate), param (s.param), call_stmt_size (s.call_stmt_size), call_stmt_time (s.call_stmt_time), loop_depth (s.loop_depth), is_return_callee_uncaptured (s.is_return_callee_uncaptured) { } /* Default destructor. */ ~ipa_call_summary (); class predicate *predicate; /* Vector indexed by parameters. */ vec param; /* Estimated size and time of the call statement. */ int call_stmt_size; int call_stmt_time; /* Depth of loop nest, 0 means no nesting. */ unsigned int loop_depth; /* Indicates whether the caller returns the value of it's callee. */ bool is_return_callee_uncaptured; }; class ipa_call_summary_t: public fast_call_summary { public: ipa_call_summary_t (symbol_table *symtab): fast_call_summary (symtab) {} /* Hook that is called by summary when an edge is duplicated. */ virtual void duplicate (cgraph_edge *src, cgraph_edge *dst, ipa_call_summary *src_data, ipa_call_summary *dst_data); }; extern fast_call_summary *ipa_call_summaries; /* In ipa-fnsummary.c */ void ipa_debug_fn_summary (struct cgraph_node *); void ipa_dump_fn_summaries (FILE *f); void ipa_dump_fn_summary (FILE *f, struct cgraph_node *node); void ipa_dump_hints (FILE *f, ipa_hints); void ipa_free_fn_summary (void); void inline_analyze_function (struct cgraph_node *node); void estimate_ipcp_clone_size_and_time (struct cgraph_node *, vec, vec, vec, int *, sreal *, sreal *, ipa_hints *); void ipa_merge_fn_summary_after_inlining (struct cgraph_edge *edge); void ipa_update_overall_fn_summary (struct cgraph_node *node); void compute_fn_summary (struct cgraph_node *, bool); void evaluate_properties_for_edge (struct cgraph_edge *e, bool inline_p, clause_t *clause_ptr, clause_t *nonspec_clause_ptr, vec *known_vals_ptr, vec *known_contexts_ptr, vec *); void estimate_node_size_and_time (struct cgraph_node *node, clause_t possible_truths, clause_t nonspec_possible_truths, vec known_vals, vec, vec known_aggs, int *ret_size, int *ret_min_size, sreal *ret_time, sreal *ret_nonspecialized_time, ipa_hints *ret_hints, vec inline_param_summary); void ipa_fnsummary_c_finalize (void); #endif /* GCC_IPA_FNSUMMARY_H */