From mboxrd@z Thu Jan 1 00:00:00 1970 Return-Path: Received: from mail-pj1-x1030.google.com (mail-pj1-x1030.google.com [IPv6:2607:f8b0:4864:20::1030]) by sourceware.org (Postfix) with ESMTPS id 95390385189B for ; Mon, 14 Nov 2022 08:13:46 +0000 (GMT) DMARC-Filter: OpenDMARC Filter v1.4.1 sourceware.org 95390385189B Authentication-Results: sourceware.org; dmarc=none (p=none dis=none) header.from=vrull.eu Authentication-Results: sourceware.org; spf=pass smtp.mailfrom=vrull.eu Received: by mail-pj1-x1030.google.com with SMTP id m14-20020a17090a3f8e00b00212dab39bcdso13090288pjc.0 for ; Mon, 14 Nov 2022 00:13:46 -0800 (PST) DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/relaxed; d=vrull.eu; s=google; h=cc:to:subject:message-id:date:from:in-reply-to:references :mime-version:from:to:cc:subject:date:message-id:reply-to; bh=8BwvVSDqFGMk2c+hy42xMS6DcFiTrb6bF1a76t7H8WY=; b=K9VOZYmLj5llsm1nODqyplYg++SHVn7nrm9g7if3b4InXGh9TZhdogYJ4g1kBZYhpj JOcjz97jI9qT2pSBnjTESfbIiwMNl4/ZUt/+n3xp9Pf03nSAnFpi4O8J/5EfbDD+6Yex WSRSgWktt2pm8oi2Wp1b+qsmQ+3S6K0gsx+YLWmUH56+uxZfJWtlsUto5/UkbcnXsdHO jdyDJxLUQQmKWQemNn/RONxbgiEPXaRTopmqQKPIHOyIpywglkcV++PrBL62BTsEh3fy v1SAnsOrdM+ow/PWYEBdQTkVcTgm6ZbwQ5n1zUDPq1PHhgJLsEkC0sP/hby9yskqTz8s B04g== X-Google-DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/relaxed; d=1e100.net; s=20210112; h=cc:to:subject:message-id:date:from:in-reply-to:references :mime-version:x-gm-message-state:from:to:cc:subject:date:message-id :reply-to; bh=8BwvVSDqFGMk2c+hy42xMS6DcFiTrb6bF1a76t7H8WY=; b=ZDTeDhlgLKe4UeCnOHqg7zoc+Ch3eVm0kVFeYlpeb2IvWs5FdO1mnOUTNBoe5yrhqD ogHrKDOt5p/ycWpJZyU/pAlOcfeZMPGp+lQEpG7dNMo6EDGbbEMi4Rjj6nqvsryeT2qp 9DQVFOz8ql+XPgl80+T6gxhMKlYM//BWAhuuR2kiYBd+DNb1fPO1Vmvj7IJfnPL70DZk bYgVkxfLkD4K1/ls9YLWk230MLqwoCijU1ZomT0Um0t0ikPNKnUBSKv52ZlxneLkz5yU QdvyGT9WjtGKKa0eIbQbOkBZXlZO9pvrgLF6zryVDyzh0vQ7SfJpnS+BH3RR/xVVa9lz zTEw== X-Gm-Message-State: ANoB5pkABNvlqHXQ6bQJNALXWSclTnMP9QA36UQYGY9OvaYKpObFPM+P eKuEjBPRSZPOEn+T+WhRx0y0+weSfZtqxmmG1k3z+A== X-Google-Smtp-Source: AA0mqf6S/ppqr3EPQkM3mupfouOZSvOSVoa5vdWCLN9G1OAxWqSzd3E4sbsGr46ZrVDhUwrWbfolecTix12Vkix4lCg= X-Received: by 2002:a17:90a:9ce:b0:212:e521:7cbd with SMTP id 72-20020a17090a09ce00b00212e5217cbdmr12759630pjo.230.1668413625213; Mon, 14 Nov 2022 00:13:45 -0800 (PST) MIME-Version: 1.0 References: <20221113150912.1292332-1-christoph.muellner@vrull.eu> In-Reply-To: From: =?UTF-8?Q?Christoph_M=C3=BCllner?= Date: Mon, 14 Nov 2022 09:13:31 +0100 Message-ID: Subject: Re: [RFC PATCH] ipa-guarded-deref: Add new pass to dereference function pointers To: Richard Biener Cc: gcc-patches@gcc.gnu.org, Manolis Tsamis , Martin Jambor , Jan Hubicka , Philipp Tomsich Content-Type: multipart/alternative; boundary="000000000000783dc605ed69d10c" X-Spam-Status: No, score=-9.9 required=5.0 tests=BAYES_00,DKIM_SIGNED,DKIM_VALID,DKIM_VALID_AU,DKIM_VALID_EF,GIT_PATCH_0,HTML_MESSAGE,JMQ_SPF_NEUTRAL,KAM_SHORT,RCVD_IN_DNSWL_NONE,SPF_HELO_NONE,SPF_PASS,TXREP autolearn=ham autolearn_force=no version=3.4.6 X-Spam-Checker-Version: SpamAssassin 3.4.6 (2021-04-09) on server2.sourceware.org List-Id: --000000000000783dc605ed69d10c Content-Type: text/plain; charset="UTF-8" Content-Transfer-Encoding: quoted-printable On Mon, Nov 14, 2022 at 8:31 AM Richard Biener wrote: > On Sun, Nov 13, 2022 at 4:09 PM Christoph Muellner > wrote: > > > > From: Christoph M=C3=BCllner > > > > This patch adds a new pass that looks up function pointer assignments, > > and adds guarded direct calls to the call sites of the function > > pointers. > > > > E.g.: Lets assume an assignment to a function pointer as follows: > > b->cb =3D &myfun; > > Other part of the program can use the function pointer as follows: > > b->cb (); > > With this pass the invocation will be transformed to: > > if (b->cb =3D=3D myfun) > > myfun(); > > else > > b->cb () > > > > The impact of the dynamic guard is expected to be less than the speedup > > gained by enabled optimizations (e.g. inlining or constant propagation). > > We have speculative devirtualization doing this very transform, shouldn't > you > instead improve that instead of inventing another specialized pass? > Yes, it can be integrated into ipa-devirt. The reason we initially decided to move it into its own file was that C++ devirtualization and function pointer dereferencing/devirtualization will likely not use the same analysis. E.g. ODR only applies to C++, C++ tables are not directly exposed to the user. So we figured that different things should not be merged together, but a reuse of common code to avoid duplication is mandatory. The patch uses the same API like speculative devirtualization in the propagation phase (ipa_make_edge_direct_to_target) and does not do anything in the transformation phase. So there is no duplication of functionality. I will move the code into ipa-devirt. Thanks! > > Thanks, > Richard. > > > PR ipa/107666 > > gcc/ChangeLog: > > > > * Makefile.in: Add new pass. > > * common.opt: Add flag -fipa-guarded-deref. > > * lto-section-in.cc: Add new section "ipa_guarded_deref". > > * lto-streamer.h (enum lto_section_type): Add new section. > > * passes.def: Add new pass. > > * timevar.def (TV_IPA_GUARDED_DEREF): Add time var. > > * tree-pass.h (make_pass_ipa_guarded_deref): New prototype. > > * ipa-guarded-deref.cc: New file. > > > > Signed-off-by: Christoph M=C3=BCllner > > --- > > gcc/Makefile.in | 1 + > > gcc/common.opt | 4 + > > gcc/ipa-guarded-deref.cc | 1115 ++++++++++++++++++++++++++++++++++++++ > > gcc/lto-section-in.cc | 1 + > > gcc/lto-streamer.h | 1 + > > gcc/passes.def | 1 + > > gcc/timevar.def | 1 + > > gcc/tree-pass.h | 1 + > > 8 files changed, 1125 insertions(+) > > create mode 100644 gcc/ipa-guarded-deref.cc > > > > diff --git a/gcc/Makefile.in b/gcc/Makefile.in > > index f672e6ea549..402c4a6ea3f 100644 > > --- a/gcc/Makefile.in > > +++ b/gcc/Makefile.in > > @@ -1462,6 +1462,7 @@ OBJS =3D \ > > ipa-sra.o \ > > ipa-devirt.o \ > > ipa-fnsummary.o \ > > + ipa-guarded-deref.o \ > > ipa-polymorphic-call.o \ > > ipa-split.o \ > > ipa-inline.o \ > > diff --git a/gcc/common.opt b/gcc/common.opt > > index bce3e514f65..8344940ae5b 100644 > > --- a/gcc/common.opt > > +++ b/gcc/common.opt > > @@ -1933,6 +1933,10 @@ fipa-bit-cp > > Common Var(flag_ipa_bit_cp) Optimization > > Perform interprocedural bitwise constant propagation. > > > > +fipa-guarded-deref > > +Common Var(flag_ipa_guarded_deref) Optimization > > +Perform guarded function pointer derferencing. > > + > > fipa-modref > > Common Var(flag_ipa_modref) Optimization > > Perform interprocedural modref analysis. > > diff --git a/gcc/ipa-guarded-deref.cc b/gcc/ipa-guarded-deref.cc > > new file mode 100644 > > index 00000000000..198fb9b33ad > > --- /dev/null > > +++ b/gcc/ipa-guarded-deref.cc > > @@ -0,0 +1,1115 @@ > > +/* IPA pass to transform indirect calls to guarded direct calls. > > + Copyright (C) 2022 Free Software Foundation, Inc. > > + Contributed by Christoph Muellner (Vrull GmbH) > > + Based on work by Erick Ochoa (Vrull GmbH) > > + > > +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 > > +. */ > > + > > +/* Indirect calls are used to separate callees from their call sites. > > + This helps to implement proper abstraction layers, but prevents > > + optimizations like constant-propagation or function specialization. > > + > > + Assuming that we identify a function pointer that gets assigned > > + only a small amount of times, we can convert the indirect calls > > + to the target function into guarded direct calls and let later > > + passes apply additional optimizations. > > + > > + This pass does this by: > > + * Identifying function pointers that are assigned up to N=3D1 times > > + to struct fields. > > + * Convert the indirect calls into a test for the call target > > + and a direct call > > + * If the test fails, then the indirect call will be executed. > > + > > + E.g.: > > + - function foo's address is taken and stored in a field of struct > > + o->func =3D foo; > > + - the program writes into this struct field only once > > + - it is possible, that we miss a store (we would need strong > guarantees) > > + therefore, we do the following conversion: > > + o->func () > > + <--> > > + if (o->func =3D=3D foo) > > + foo () > > + else > > + o->func () > > + > > + This pass is implemented as a full IPA pass that uses the LTO secti= on > > + "ipa_guarded_deref". */ > > + > > +#include "config.h" > > +#include "system.h" > > +#include "coretypes.h" > > +#include "backend.h" > > +#include "tree.h" > > +#include "gimple.h" > > +#include "alloc-pool.h" > > +#include "tree-pass.h" > > +#include "tree-cfg.h" > > +#include "ssa.h" > > +#include "cgraph.h" > > +#include "gimple-pretty-print.h" > > +#include "gimple-iterator.h" > > +#include "symbol-summary.h" > > +#include "ipa-utils.h" > > + > > +#include "attr-fnspec.h" > > +#include "gimple-ssa.h" > > +#include "data-streamer.h" > > +#include "lto-streamer.h" > > +#include "print-tree.h" > > +#include "calls.h" > > +#include "gimple-fold.h" > > +#include "tree-vrp.h" > > +#include "ipa-prop.h" > > +#include "ipa-fnsummary.h" > > +#include "demangle.h" > > +#include "dbgcnt.h" > > +#include "intl.h" > > +#include "stringpool.h" > > +#include "attribs.h" > > +#include "streamer-hooks.h" > > + > > +#include "alloc-pool.h" > > +#include "tree-pass.h" > > +#include "gimple-iterator.h" > > +#include "tree-dfa.h" > > +#include "cgraph.h" > > +#include "ipa-utils.h" > > +#include "symbol-summary.h" > > +#include "gimple-pretty-print.h" > > +#include "gimple-walk.h" > > +#include "print-tree.h" > > +#include "tree-streamer.h" > > +#include "alias.h" > > +#include "calls.h" > > +#include "ipa-modref-tree.h" > > +#include "ipa-modref.h" > > +#include "value-range.h" > > +#include "ipa-prop.h" > > +#include "ipa-fnsummary.h" > > +#include "attr-fnspec.h" > > +#include "symtab-clones.h" > > +#include "gimple-ssa.h" > > +#include "tree-phinodes.h" > > +#include "tree-ssa-operands.h" > > +#include "ssa-iterators.h" > > +#include "stringpool.h" > > +#include "tree-ssanames.h" > > +#include "attribs.h" > > +#include "tree-cfg.h" > > +#include "tree-eh.h" > > +#include "hash-traits.h" > > + > > +/* Struct that holds a function pointer type. > > + In our context a function pointer type is a record-field pair, > > + with the field being of a function pointer type. */ > > + > > +struct function_pointer_type > > +{ > > + /* Record type hosting the function pointer. */ > > + tree record; > > + /* field_decl of the function pointer. */ > > + tree field; > > +}; > > + > > +/* Add a default hash trait for the type function_pointer_type, so it > can be used > > + as key in hash collections (hash_map, hash_set, etc.). */ > > + > > +template <> > > +struct default_hash_traits > > + : typed_noop_remove > > +{ > > + GTY((skip)) typedef function_pointer_type value_type; > > + GTY((skip)) typedef function_pointer_type compare_type; > > + static hashval_t > > + hash (function_pointer_type p) > > + { > > + return TYPE_UID (p.record) ^ DECL_UID (p.field); > > + } > > + static const bool empty_zero_p =3D true; > > + static bool > > + is_empty (function_pointer_type p) > > + { > > + return p.record =3D=3D NULL_TREE; > > + } > > + static bool > > + is_deleted (function_pointer_type p ATTRIBUTE_UNUSED) > > + { > > + return false; > > + } > > + static bool > > + equal (const function_pointer_type &l, > > + const function_pointer_type &r) > > + { > > + return (l.record =3D=3D r.record) && (l.field =3D=3D r.field); > > + } > > + static void > > + mark_empty (function_pointer_type &p) > > + { > > + p.record =3D NULL_TREE; > > + p.field =3D NULL_TREE; > > + } > > + static void > > + mark_deleted (function_pointer_type &p) > > + { > > + p.record =3D NULL_TREE; > > + p.field =3D NULL_TREE; > > + } > > +}; > > + > > +/* Store a call target to a function-pointer-type. > > + With this class we can correlate a field-record-pair > > + with a function pointer field with a call target. > > + > > + We maintain a 1:N mapping here, i.e. a fpt can have exactly 1 call > target, > > + but a call target can be referenced by multiple fpts. > > + > > + Note, that the information needs to be extracted with > > + the function pointer type as key and the call target as value. > > + However, on call graph modification events, we need a reverse > > + lookup (currenlty we don't optimize this code path). */ > > + > > +class function_pointer_type_assignments > > +{ > > +private: > > + /* Track function-pointer-types and their assigned call targets. */ > > + hash_map m_assignments; > > + > > +public: > > + function_pointer_type_assignments () {} > > + > > + /* Get the call target for a function pointer type (if any). */ > > + cgraph_node *get_target (const function_pointer_type &v) > > + { > > + cgraph_node **pnode =3D m_assignments.get (v); > > + return pnode ? *pnode : NULL; > > + } > > + > > + /* Add a new assignment for a function pointer type. */ > > + > > + void > > + add_assignment (function_pointer_type fpt, cgraph_node *target) > > + { > > + bool existed_p; > > + cgraph_node *&node =3D m_assignments.get_or_insert (fpt, > &existed_p); > > + if (existed_p) > > + /* More, than one target -> set call target to NULL > (unknown). */ > > + node =3D NULL; > > + else > > + node =3D target; > > + } > > + > > + /* Print all stored information. */ > > + > > + void > > + print (void) > > + { > > + if (!dump_file) > > + return; > > + > > + fprintf (dump_file, > > + "Collected the following function pointer > assignments:\n"); > > + > > + hash_map::iterator iter > > + =3D m_assignments.begin (); > > + for (; iter !=3D m_assignments.end (); ++iter) > > + { > > + function_pointer_type fpt =3D (*iter).first; > > + cgraph_node* callee =3D (*iter).second; > > + > > + if (fpt.record =3D=3D NULL_TREE > > + || fpt.field =3D=3D NULL_TREE > > + || callee =3D=3D NULL) > > + continue; > > + > > + fprintf (dump_file, " "); > > + print_generic_expr (dump_file, fpt.record, TDF_NONE); > > + fprintf (dump_file, "::"); > > + print_generic_expr (dump_file, fpt.field, TDF_NONE); > > + fprintf (dump_file, " :=3D %s\n", callee ? callee->name () : > ""); > > + } > > + } > > + > > + /* Callback for node removal. */ > > + > > + void > > + remove (cgraph_node *node) > > + { > > + /* Iterators are not removal-safe. > > + Therefore we need to advance the iterator before > > + we delete the element pointed to by the iterator. > > + To do so, we use a helper pointer. */ > > + function_pointer_type to_delete; > > + bool delete_fpt =3D false; > > + > > + /* We iterate over all entries, which is not optimal. > > + To improve this, we need a way for a reverse-lookup. */ > > + hash_map::iterator iter > > + =3D m_assignments.begin (); > > + for (; iter !=3D m_assignments.end (); ++iter) > > + { > > + /* Deletion comes *after* iterator advancement. */ > > + if (delete_fpt) > > + { > > + m_assignments.remove (to_delete); > > + delete_fpt =3D false; > > + } > > + > > + /* Get the cgraph node and check if it matches. */ > > + cgraph_node* n =3D (*iter).second; > > + if (n =3D=3D node) > > + { > > + /* Mark for removal (see above). */ > > + to_delete =3D (*iter).first; > > + delete_fpt =3D true; > > + } > > + } > > + > > + /* Deletion comes *after* iterator advancement. */ > > + if (delete_fpt) > > + { > > + m_assignments.remove (to_delete); > > + delete_fpt =3D false; > > + } > > + } > > + > > + void > > + serialize (struct output_block *ob, lto_symtab_encoder_t &encoder) > > + { > > + unsigned HOST_WIDE_INT elements =3D m_assignments.elements (); > > + > > + /* Write the number of elements. */ > > + streamer_write_uhwi (ob, elements); > > + > > + hash_map::iterator iter > > + =3D m_assignments.begin (); > > + for (; iter !=3D m_assignments.end (); ++iter) > > + { > > + /* Write the function pointer type. */ > > + function_pointer_type fpt =3D (*iter).first; > > + stream_write_tree_ref (ob, fpt.record); > > + stream_write_tree_ref (ob, fpt.field); > > + > > + /* Write the callee. */ > > + unsigned HOST_WIDE_INT symid; > > + cgraph_node* callee =3D (*iter).second; > > + if (callee) > > + symid =3D lto_symtab_encoder_encode (encoder, callee); > > + else > > + symid =3D 0; > > + > > + streamer_write_uhwi (ob, symid); > > + } > > + } > > + > > + void > > + deserialize (lto_input_block &ib, class data_in *data_in, > > + lto_symtab_encoder_t &encoder) > > + { > > + size_t elements =3D streamer_read_uhwi (&ib); > > + for (size_t i =3D 0; i < elements; i++) > > + { > > + /* Read the function pointer type. */ > > + function_pointer_type fpt; > > + fpt.record =3D stream_read_tree_ref (&ib, data_in); > > + fpt.field =3D stream_read_tree_ref (&ib, data_in); > > + > > + /* Read the callee. */ > > + cgraph_node *callee =3D NULL; > > + unsigned HOST_WIDE_INT symid =3D streamer_read_uhwi (&ib); > > + if (symid) > > + { > > + symtab_node *scallee =3D lto_symtab_encoder_deref (encode= r, > symid); > > + callee =3D dyn_cast (scallee); > > + } > > + > > + /* Add the function pointer type assignment. */ > > + add_assignment (fpt, callee); > > + } > > + } > > + > > + ~function_pointer_type_assignments () {} > > +}; > > + > > +/* Store a record-field-pair to a call graph edge. > > + With this class we can correlate an indirect call with > > + the field-record-pair of its call site. > > + > > + Note, that the information needs to be extracted with > > + the edge as key and the function pointer type as value. */ > > + > > +class indirect_call_summary > > + : public call_summary > > +{ > > +public: > > + indirect_call_summary (symbol_table *table) > > + : call_summary (table) > > + { } > > + > > + /* Hook that is called by summary when an edge is duplicated. */ > > + virtual void duplicate (cgraph_edge *src ATTRIBUTE_UNUSED, > > + cgraph_edge *dst ATTRIBUTE_UNUSED, > > + function_pointer_type *old_fpt, > > + function_pointer_type *new_fpt) > > + { > > + /* We may not have record-field-pair, because not every edge > > + is an indirect call. */ > > + if (!old_fpt) > > + return; > > + > > + new_fpt->record =3D old_fpt->record; > > + new_fpt->field =3D old_fpt->field; > > + } > > + > > + /* Print all stored information. */ > > + > > + void > > + print (void) > > + { > > + if (!dump_file) > > + return; > > + > > + fprintf (dump_file, > > + "Collected the following indirect calls:\n"); > > + > > + cgraph_node *caller =3D NULL; > > + FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (caller) > > + { > > + for (cgraph_edge *e =3D caller->indirect_calls; e; e =3D > e->next_callee) > > + { > > + function_pointer_type *fpt =3D get (e); > > + if (fpt && fpt->record && fpt->field) > > + { > > + fprintf (dump_file, " "); > > + fprintf (dump_file, "%s -> ", caller->name ()); > > + print_generic_expr (dump_file, fpt->record, TDF_NONE); > > + fprintf (dump_file, "::"); > > + print_generic_expr (dump_file, fpt->field, TDF_NONE); > > + fprintf (dump_file, "\n"); > > + } > > + } > > + } > > + } > > + > > + void > > + serialize (struct output_block *ob, lto_symtab_encoder_t encoder) > > + { > > + unsigned HOST_WIDE_INT elements =3D 0; > > + > > + /* We iterate over all (cnodes x edges) and store all that have > > + additional information stored. */ > > + > > + lto_symtab_encoder_iterator it; > > + for (it =3D lsei_start_function_in_partition (encoder); !lsei_en= d_p > (it); > > + lsei_next_function_in_partition (&it)) > > + { > > + cgraph_node *node =3D lsei_cgraph_node (it); > > + if (node->has_gimple_body_p ()) > > + elements++; > > + } > > + > > + /* Write the number of elements. */ > > + streamer_write_uhwi (ob, elements); > > + > > + for (it =3D lsei_start_function_in_partition (encoder); !lsei_en= d_p > (it); > > + lsei_next_function_in_partition (&it)) > > + { > > + cgraph_node *caller =3D lsei_cgraph_node (it); > > + if (!caller->has_gimple_body_p ()) > > + continue; > > + > > + /* Write caller. */ > > + unsigned HOST_WIDE_INT symid =3D lto_symtab_encoder_encode > (encoder, > > + > caller); > > + streamer_write_uhwi (ob, symid); > > + > > + for (cgraph_edge *e =3D caller->indirect_calls; e; e =3D > e->next_callee) > > + { > > + function_pointer_type *fpt =3D get (e); > > + if (fpt && fpt->record && fpt->field) > > + { > > + /* Write the function pointer type. */ > > + stream_write_tree_ref (ob, fpt->record); > > + stream_write_tree_ref (ob, fpt->field); > > + } > > + else > > + { > > + stream_write_tree_ref (ob, NULL_TREE); > > + stream_write_tree_ref (ob, NULL_TREE); > > + } > > + } > > + } > > + } > > + > > + void > > + deserialize (lto_input_block &ib, class data_in *data_in, > > + lto_symtab_encoder_t &encoder) > > + { > > + /* Read the number of elements. */ > > + size_t elements =3D streamer_read_uhwi (&ib); > > + > > + for (size_t i =3D 0; i < elements; i++) > > + { > > + /* Read caller. */ > > + unsigned HOST_WIDE_INT symid =3D streamer_read_uhwi (&ib); > > + symtab_node *scaller =3D lto_symtab_encoder_deref (encoder, > symid); > > + cgraph_node *caller =3D dyn_cast (scaller); > > + > > + for (cgraph_edge *e =3D caller->indirect_calls; e; e =3D > e->next_callee) > > + { > > + tree record =3D stream_read_tree_ref (&ib, data_in); > > + tree field =3D stream_read_tree_ref (&ib, data_in); > > + if (record =3D=3D NULL_TREE && field =3D=3D NULL_TREE) > > + continue; > > + > > + function_pointer_type *fpt =3D get_create (e); > > + fpt->record =3D record; > > + fpt->field =3D field; > > + } > > + } > > + } > > +}; > > + > > +class gimple_walker > > +{ > > +public: > > + gimple_walker () {} > > + > > + void walk (void* data); > > + > > +protected: > > + /* Overload these callbacks. */ > > + virtual void walk_gassign (__attribute__ ((unused)) cgraph_node*, > > + __attribute__ ((unused)) gassign*, > > + __attribute__ ((unused)) void*) {} > > + virtual void walk_gcall (__attribute__ ((unused)) cgraph_node*, > > + __attribute__ ((unused)) gcall*, > > + __attribute__ ((unused)) void*) {} > > + > > +private: > > + /* Will walk declarations, locals, ssa names, and basic blocks. */ > > + void _walk_cnode (cgraph_node *cnode, void *data); > > + > > + /* Iterate over all basic blocks in CNODE. */ > > + void _walk_bb (cgraph_node *cnode, basic_block bb, void *data); > > + > > + /* Iterate over all gimple_stmt in BB. */ > > + void _walk_gimple (cgraph_node *cnode, gimple *stmt, void *data); > > +}; > > + > > +void > > +gimple_walker::walk (void *data) > > +{ > > + hash_set fndecls2; > > + cgraph_node *node =3D NULL; > > + > > + FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (node) > > + { > > + node->get_body (); > > + tree decl =3D node->decl; > > + gcc_assert (decl); > > + const bool already_in_set =3D fndecls2.contains (decl); > > + > > + /* I think it is possible for different nodes to point to the sa= me > > + declaration. */ > > + if (already_in_set) > > + continue; > > + > > + if (dump_file) > > + dump_function_to_file (node->decl, dump_file, TDF_NONE); > > + > > + _walk_cnode (node, data); > > + > > + /* Add to set of known declarations. */ > > + fndecls2.add (decl); > > + } > > +} > > + > > +/* Walk over all basic blocks in CNODE. */ > > + > > +void > > +gimple_walker::_walk_cnode (cgraph_node *cnode, void *data) > > +{ > > + cnode->get_body (); > > + tree decl =3D cnode->decl; > > + gcc_assert (decl); > > + > > + function *func =3D DECL_STRUCT_FUNCTION (decl); > > + gcc_assert (func); > > + > > + basic_block bb =3D NULL; > > + > > + push_cfun (func); > > + FOR_EACH_BB_FN (bb, func) > > + { > > + _walk_bb (cnode, bb, data); > > + } > > + pop_cfun (); > > +} > > + > > +/* Walk over each gimple statement in BB. */ > > + > > +void > > +gimple_walker::_walk_bb (cgraph_node *cnode, basic_block bb, void *dat= a) > > +{ > > + gimple_stmt_iterator gsi; > > + for (gsi =3D gsi_start_bb (bb); !gsi_end_p (gsi); gsi_next (&gsi)) > > + { > > + gimple *stmt =3D gsi_stmt (gsi); > > + _walk_gimple (cnode, stmt, data); > > + } > > +} > > + > > +/* Switch for different gimple instruction types. */ > > + > > +void > > +gimple_walker::_walk_gimple (cgraph_node *cnode, gimple *stmt, void > *data) > > +{ > > + const enum gimple_code code =3D gimple_code (stmt); > > + switch (code) > > + { > > + case GIMPLE_ASSIGN: > > + { > > + gassign *assign =3D dyn_cast (stmt); > > + walk_gassign (cnode, assign, data); > > + break; > > + } > > + case GIMPLE_CALL: > > + { > > + gcall *call =3D dyn_cast (stmt); > > + walk_gcall (cnode, call, data); > > + break; > > + } > > + default: > > + break; > > + } > > +} > > + > > +class gimple_assignment_collector : public gimple_walker > > +{ > > +protected: > > + virtual void walk_gassign (cgraph_node *cnode, gassign *stmt, void > *data) > > + { > > + if (dump_file) > > + fprintf (dump_file, "%s: Entering.\n", __func__); > > + > > + function_pointer_type_assignments *fpas > > + =3D (function_pointer_type_assignments*) data; > > + > > + tree lhs =3D gimple_assign_lhs (stmt); > > + gcc_assert (lhs); > > + > > + /* We only care about a rhs which is a variable or a constant. > > + Therefore, we only need to look at unary or single rhs. */ > > + const enum gimple_rhs_class gclass =3D gimple_assign_rhs_class > (stmt); > > + if (gclass !=3D GIMPLE_UNARY_RHS > > + && gclass !=3D GIMPLE_SINGLE_RHS) > > + { > > + if (dump_file) > > + fprintf (dump_file, "%s: RHS class not matching.\n", > __func__); > > + return; > > + } > > + > > + tree rhs =3D gimple_assign_rhs1 (stmt); > > + > > + if (dump_file) > > + { > > + fprintf (dump_file, "%s: Analysing assignment:\n", __func__); > > + fprintf (dump_file, " Function: %s\n", cnode->name ()); > > + fprintf (dump_file, " LHS: "); > > + print_generic_expr (dump_file, lhs, TDF_NONE); > > + fprintf (dump_file, "\n RHS: "); > > + print_generic_expr (dump_file, rhs, TDF_NONE); > > + fprintf (dump_file, "\n"); > > + } > > + > > + /* We are only interested in function pointers. */ > > + tree rhs_t =3D TREE_TYPE (rhs); > > + tree lhs_t =3D TREE_TYPE (lhs); > > + if (TREE_CODE (rhs_t) !=3D POINTER_TYPE > > + || TREE_CODE (lhs_t) !=3D POINTER_TYPE) > > + { > > + if (dump_file) > > + fprintf (dump_file, "%s: LHS not pointer type.\n", __func__= ); > > + return; > > + } > > + if (TREE_CODE (TREE_TYPE (rhs_t)) !=3D FUNCTION_TYPE > > + || TREE_CODE (TREE_TYPE (lhs_t)) !=3D FUNCTION_TYPE) > > + { > > + if (dump_file) > > + fprintf (dump_file, "%s: RHS not function type.\n", > __func__); > > + return; > > + } > > + > > + /* We only care about function pointers assigned to fields. > > + So we look for COMPONENT_REF. */ > > + const enum tree_code code =3D TREE_CODE (lhs); > > + if (code !=3D COMPONENT_REF) > > + { > > + if (dump_file) > > + fprintf (dump_file, "%s: LHS not component ref.\n", > __func__); > > + return; > > + } > > + > > + tree base =3D TREE_OPERAND (lhs, 0); > > + tree base_t =3D TREE_TYPE (base); > > + > > + /* We either have a record or a pointer to a record. */ > > + if (TREE_CODE (base_t) =3D=3D POINTER_TYPE) > > + base_t =3D TREE_TYPE (base_t); > > + > > + if (TREE_CODE (base_t) !=3D RECORD_TYPE) > > + { > > + if (dump_file) > > + { > > + fprintf (dump_file, "%s: Base type not record type.\n", > __func__); > > + fprintf (dump_file, "%s: base: ", __func__); > > + print_generic_expr (dump_file, base, TDF_DETAILS); > > + fprintf (dump_file, "%s: base_t: ", __func__); > > + print_generic_expr (dump_file, base_t, TDF_DETAILS); > > + } > > + return; > > + } > > + > > + /* We only care about addr expressions. */ > > + if (TREE_CODE (rhs) !=3D ADDR_EXPR) > > + { > > + if (dump_file) > > + fprintf (dump_file, "%s: RHS is not addr expr.\n", __func__= ); > > + return; > > + } > > + > > + tree possible_decl =3D TREE_OPERAND (rhs, 0); > > + if (TREE_CODE (possible_decl) !=3D FUNCTION_DECL) > > + { > > + if (dump_file) > > + fprintf (dump_file, "%s: RHS addr expr is not a function > decl.\n", > > + __func__); > > + return; > > + } > > + > > + tree field =3D TREE_OPERAND (lhs, 1); > > + > > + /* Add record type and field decl to global summary. */ > > + function_pointer_type pair; > > + pair.record =3D base_t; > > + pair.field =3D field; > > + cgraph_node *node =3D cgraph_node::get (possible_decl); > > + > > + /* This is a candidate for optimization. */ > > + if (dump_file) > > + { > > + cgraph_node *orig =3D cgraph_node::get (cfun->decl); > > + fprintf (dump_file, "Candidate found in %s:\n", orig->name ()= ); > > + print_gimple_stmt (dump_file, stmt, dump_flags); > > + } > > + > > + fpas->add_assignment (pair, node); > > + } > > + > > + virtual void walk_gcall (cgraph_node *cnode, gcall *stmt, void *data) > > + { > > + (void)cnode; > > + > > + if (dump_file) > > + fprintf (dump_file, "%s: Entering.\n", __func__); > > + > > + function_pointer_type_assignments *fpas > > + =3D (function_pointer_type_assignments*) data; > > + > > + gcc_assert (stmt); > > + tree lhs =3D gimple_call_lhs (stmt); > > + if (!lhs) > > + return; > > + > > + tree lhs_t =3D TREE_TYPE (lhs); > > + /* We are only interested in function pointers. */ > > + if (TREE_CODE (lhs_t) !=3D POINTER_TYPE) > > + return; > > + if (TREE_CODE (TREE_TYPE (lhs_t)) !=3D FUNCTION_TYPE) > > + return; > > + > > + /* We only care about function pointers assigned to fields. > > + So we look for COMPONENT_REF. */ > > + const enum tree_code code =3D TREE_CODE (lhs); > > + if (code !=3D COMPONENT_REF) > > + return; > > + > > + /* We either have a record or a pointer to a record. */ > > + tree base =3D TREE_OPERAND (lhs, 0); > > + tree base_t =3D TREE_TYPE (base); > > + if (TREE_CODE (base_t) !=3D POINTER_TYPE) > > + return; > > + base_t =3D TREE_TYPE (base_t); > > + if (TREE_CODE (base_t) !=3D RECORD_TYPE) > > + return; > > + if (!TYPE_P (base_t)) > > + return; > > + > > + tree field =3D TREE_OPERAND (lhs, 1); > > + > > + /* Add record type and field decl to global summary. */ > > + function_pointer_type pair; > > + pair.record =3D base_t; > > + pair.field =3D field; > > + > > + /* This is a reason to not optimize this pointer. */ > > + if (dump_file) > > + { > > + cgraph_node *orig =3D cgraph_node::get (cfun->decl); > > + fprintf (dump_file, "Counter-candidate found in %s:\n", > orig->name ()); > > + print_gimple_stmt (dump_file, stmt, dump_flags); > > + } > > + > > + fpas->add_assignment (pair, NULL); > > + } > > +}; > > + > > +/* Globals (prefixed by '_'). */ > > +static function_pointer_type_assignments > *_function_pointer_type_assignments; > > +static indirect_call_summary *_indirect_call_summaries; > > +static struct cgraph_node_hook_list *_cgraph_removal_hook_holder; > > + > > +/* Function updates our global summary. */ > > + > > +static void > > +remove_cgraph_callback (cgraph_node *node, void *data ATTRIBUTE_UNUSED) > > +{ > > + if (dump_file) > > + fprintf (dump_file, "%s: node removal: %s\n", __func__, node->name > ()); > > + _function_pointer_type_assignments->remove (node); > > +} > > + > > +/* Register notification callbacks. */ > > + > > +static void > > +guarded_deref_register_cgraph_hooks (void) > > +{ > > + _cgraph_removal_hook_holder > > + =3D symtab->add_cgraph_removal_hook (&remove_cgraph_callback, NULL= ); > > +} > > + > > +/* Unregister notification callbacks. */ > > + > > +static void > > +guarded_deref_unregister_cgraph_hooks (void) > > +{ > > + if (_cgraph_removal_hook_holder) > > + symtab->remove_cgraph_removal_hook (_cgraph_removal_hook_holder); > > + _cgraph_removal_hook_holder =3D NULL; > > +} > > + > > +static void > > +guarded_deref_find_indirect (struct cgraph_node *node, > > + indirect_call_summary *ics) > > +{ > > + if (!node || node->inlined_to || !node->has_gimple_body_p ()) > > + return; > > + > > + for (cgraph_edge *e =3D node->indirect_calls; e; e =3D e->next_calle= e) > > + { > > + gimple *stmt =3D e->call_stmt; > > + if (gimple_code (stmt) !=3D GIMPLE_CALL) > > + continue; > > + > > + gcall *call_stmt =3D dyn_cast (stmt); > > + tree target =3D gimple_call_fn (call_stmt); > > + if (!target) > > + continue; > > + > > + if (TREE_CODE (target) !=3D SSA_NAME) > > + continue; > > + > > + gimple *def =3D SSA_NAME_DEF_STMT (target); > > + > > + if (!gimple_assign_load_p (def)) > > + continue; > > + > > + const enum gimple_rhs_class gclass =3D gimple_assign_rhs_class > (def); > > + const bool valid =3D gclass =3D=3D GIMPLE_UNARY_RHS || gclass = =3D=3D > GIMPLE_SINGLE_RHS; > > + if (!valid) > > + continue; > > + > > + tree rhs =3D gimple_assign_rhs1 (def); > > + const enum tree_code code =3D TREE_CODE (rhs); > > + bool is_load =3D COMPONENT_REF =3D=3D code; > > + if (!is_load) > > + continue; > > + > > + tree base =3D TREE_OPERAND (rhs, 0); > > + tree field =3D TREE_OPERAND (rhs, 1); > > + if (RECORD_TYPE !=3D TREE_CODE (TREE_TYPE (base))) > > + continue; > > + > > + function_pointer_type *fpt =3D ics->get_create (e); > > + fpt->record =3D TREE_TYPE (base); > > + fpt->field =3D field; > > + } > > +} > > + > > +static void > > +guarded_deref_generate_summary (void) > > +{ > > + if (dump_file) > > + fprintf (dump_file, "%s: Entering.\n", __func__); > > + > > + /* Allocate globals. */ > > + _function_pointer_type_assignments =3D new > function_pointer_type_assignments; > > + _indirect_call_summaries =3D new indirect_call_summary (symtab); > > + > > + /* First collect all function pointer assignments. */ > > + gimple_assignment_collector collector; > > + collector.walk (_function_pointer_type_assignments); > > + > > + /* Now collect all indirect calls. */ > > + cgraph_node *cnode =3D NULL; > > + FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (cnode) > > + { > > + guarded_deref_find_indirect (cnode, _indirect_call_summaries); > > + } > > + > > + /* Print collected information. */ > > + _function_pointer_type_assignments->print (); > > + _indirect_call_summaries-> print (); > > + > > + /* Register hooks for cgraph changes in other passes. */ > > + guarded_deref_register_cgraph_hooks (); > > +} > > + > > +static void > > +guarded_deref_write_summary (void) > > +{ > > + if (dump_file) > > + fprintf (dump_file, "%s: Entering.\n", __func__); > > + > > + /* Only run if we are in a sane state. */ > > + if (!_function_pointer_type_assignments || !_indirect_call_summaries) > > + return; > > + > > + /* Print collected information. */ > > + _function_pointer_type_assignments->print (); > > + _indirect_call_summaries-> print (); > > + > > + /* Unregister cgraph change hooks. */ > > + guarded_deref_unregister_cgraph_hooks (); > > + > > + /* Create an output block to write out information into. */ > > + struct output_block *ob =3D create_output_block > (LTO_section_ipa_guarded_deref); > > + > > + /* Get the cgraph_node encoder. */ > > + lto_symtab_encoder_t encoder =3D ob->decl_state->symtab_node_encoder; > > + > > + /* Write collected function pointer assignments to the OB. */ > > + _function_pointer_type_assignments->serialize (ob, encoder); > > + > > + /* Write edge summaries. */ > > + _indirect_call_summaries->serialize (ob, encoder); > > + > > + /* Delete the information in memory. */ > > + delete _function_pointer_type_assignments; > > + _function_pointer_type_assignments =3D NULL; > > + delete _indirect_call_summaries; > > + _indirect_call_summaries =3D NULL; > > + > > + /* Write the contents of the output block into the instruction > stream. */ > > + produce_asm (ob, NULL); > > + > > + /* Now destroy the output block. */ > > + destroy_output_block (ob); > > +} > > + > > +static void > > +guarded_deref_read_summary (void) > > +{ > > + if (dump_file) > > + fprintf (dump_file, "%s: Entering.\n", __func__); > > + > > + if (_indirect_call_summaries || _function_pointer_type_assignments) > > + return; > > + > > + /* Allocate globals. */ > > + _indirect_call_summaries =3D new indirect_call_summary (symtab); > > + _function_pointer_type_assignments =3D new > function_pointer_type_assignments; > > + > > + struct lto_file_decl_data **file_data_vec =3D lto_get_file_decl_data= (); > > + struct lto_file_decl_data *file_data; > > + unsigned int j =3D 0; > > + while ((file_data =3D file_data_vec[j++])) > > + { > > + size_t len; > > + const char *data =3D lto_get_summary_section_data (file_data, > > + > LTO_section_ipa_guarded_deref, > > + &len); > > + if (!data) > > + continue; > > + > > + const struct lto_function_header *header > > + =3D (const struct lto_function_header*) data; > > + > > + const int cfg_offset =3D sizeof (*header); > > + const int main_offset =3D cfg_offset + header->cfg_size; > > + const int string_offset =3D main_offset + header->main_size; > > + class data_in *data_in; > > + > > + lto_input_block ib ((const char *) data + main_offset, > > + header->main_size, file_data->mode_table); > > + data_in =3D lto_data_in_create (file_data, > > + (const char *) data + string_offset, > > + header->string_size, vNULL); > > + > > + lto_symtab_encoder_t encoder =3D file_data->symtab_node_encoder; > > + > > + /* Read collected function pointer assignments from LTO stream. > */ > > + _function_pointer_type_assignments->deserialize (ib, data_in, > encoder); > > + > > + /* Read collected indirect call summary from LTO stream. */ > > + _indirect_call_summaries->deserialize (ib, data_in, encoder); > > + > > + lto_free_section_data (file_data, LTO_section_ipa_guarded_deref, > NULL, > > + data, len); > > + lto_data_in_delete (data_in); > > + } > > + > > + /* Print collected information. */ > > + _function_pointer_type_assignments->print (); > > + _indirect_call_summaries-> print (); > > + > > + /* Register hooks for cgraph changes in other passes. */ > > + guarded_deref_register_cgraph_hooks (); > > +} > > + > > +static unsigned int > > +guarded_deref_execute (void) > > +{ > > + if (dump_file) > > + fprintf (dump_file, "%s: Entering.\n", __func__); > > + > > + if (!_function_pointer_type_assignments > > + || !_indirect_call_summaries) > > + return 0; > > + > > + /* Unregister cgraph change hooks. */ > > + guarded_deref_unregister_cgraph_hooks (); > > + > > + /* Print collected information. */ > > + _function_pointer_type_assignments->print (); > > + _indirect_call_summaries-> print (); > > + > > + if (dump_file) > > + fprintf (dump_file, "%s: Starting propagation.\n", __func__); > > + > > + cgraph_node *cnode =3D NULL; > > + FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (cnode) > > + { > > + if (cnode->inlined_to) > > + continue; > > + > > + for (cgraph_edge *e =3D cnode->indirect_calls; e; e =3D > e->next_callee) > > + { > > + /* Get the function pointer type for the edge (if any). */ > > + function_pointer_type *fpt =3D _indirect_call_summaries->get = (e); > > + if (!fpt || !fpt->record || !fpt->field) > > + continue; > > + > > + if (dump_file) > > + { > > + fprintf (dump_file, "looking for...:"); > > + print_generic_expr (dump_file, fpt->record, TDF_NONE); > > + fprintf (dump_file, " "); > > + print_generic_expr (dump_file, fpt->field, TDF_NONE); > > + fprintf (dump_file, "\n"); > > + } > > + > > + /* Now get the call target (if any). */ > > + cgraph_node *target =3D > _function_pointer_type_assignments->get_target (*fpt); > > + if (!target || !target->decl) > > + continue; > > + > > + if (dump_file) > > + { > > + fprintf (dump_file, > > + "Replacing indirect call in %s by " > > + "speculative direct call to %s\n", > > + e->caller->name (), target->name ()); > > + } > > + > > + /* Convert the indirect call to a direct (speculative) call. > */ > > + ipa_make_edge_direct_to_target (e, target->decl, true); > > + > > + /* Update the function summaries. */ > > + ipa_update_overall_fn_summary (cnode); > > + } > > + } > > + > > + if (dump_file) > > + fprintf (dump_file, "%s: Finished propagation.\n", __func__); > > + > > + return 0; > > +} > > + > > +namespace { > > + > > +const pass_data pass_data_ipa_guarded_deref =3D > > +{ > > + IPA_PASS, /* type */ > > + "guarded-deref", /* name */ > > + OPTGROUP_NONE, /* optinfo_flags */ > > + TV_IPA_GUARDED_DEREF, /* tv_id */ > > + 0, /* properties_required */ > > + 0, /* properties_provided */ > > + 0, /* properties_destroyed */ > > + 0, /* todo_flags_start */ > > + 0, /* todo_flags_finish */ > > +}; > > + > > +class pass_ipa_guarded_deref : public ipa_opt_pass_d > > +{ > > +public: > > + pass_ipa_guarded_deref (gcc::context *ctxt) > > + : ipa_opt_pass_d (pass_data_ipa_guarded_deref, ctxt, > > + guarded_deref_generate_summary, /* > generate_summary */ > > + guarded_deref_write_summary, /* write_summary */ > > + guarded_deref_read_summary, /* read_summary */ > > + NULL, /* write_optimization_summary */ > > + NULL, /* read_optimization_summary */ > > + NULL, /* stmt_fixup */ > > + 0, /* function_transform_todo_flags_start */ > > + NULL, /* function_transform */ > > + NULL) /* variable_transform */ > > + {} > > + > > + /* opt_pass methods: */ > > + bool gate (function *) final override > > + { > > + return ((in_lto_p || flag_lto) && flag_ipa_guarded_deref); > > + } > > + > > + unsigned int execute (function *) final override > > + { > > + return guarded_deref_execute (); > > + } > > + > > +}; // class pass_ipa_guarded_deref > > + > > +} // anon namespace > > + > > +ipa_opt_pass_d * > > +make_pass_ipa_guarded_deref (gcc::context *ctxt) > > +{ > > + return new pass_ipa_guarded_deref (ctxt); > > +} > > diff --git a/gcc/lto-section-in.cc b/gcc/lto-section-in.cc > > index ba87c727670..22f6b66a291 100644 > > --- a/gcc/lto-section-in.cc > > +++ b/gcc/lto-section-in.cc > > @@ -57,6 +57,7 @@ const char *lto_section_name[LTO_N_SECTION_TYPES] =3D > > "ipa_sra", > > "odr_types", > > "ipa_modref", > > + "ipa_guarded_deref", > > }; > > > > /* Hooks so that the ipa passes can call into the lto front end to get > > diff --git a/gcc/lto-streamer.h b/gcc/lto-streamer.h > > index 2e3abd97959..744e8738376 100644 > > --- a/gcc/lto-streamer.h > > +++ b/gcc/lto-streamer.h > > @@ -229,6 +229,7 @@ enum lto_section_type > > LTO_section_ipa_sra, > > LTO_section_odr_types, > > LTO_section_ipa_modref, > > + LTO_section_ipa_guarded_deref, > > LTO_N_SECTION_TYPES /* Must be last. */ > > }; > > > > diff --git a/gcc/passes.def b/gcc/passes.def > > index 193b5794749..60c029e0515 100644 > > --- a/gcc/passes.def > > +++ b/gcc/passes.def > > @@ -154,6 +154,7 @@ along with GCC; see the file COPYING3. If not see > > NEXT_PASS (pass_ipa_whole_program_visibility); > > NEXT_PASS (pass_ipa_profile); > > NEXT_PASS (pass_ipa_icf); > > + NEXT_PASS (pass_ipa_guarded_deref); > > NEXT_PASS (pass_ipa_devirt); > > NEXT_PASS (pass_ipa_cp); > > NEXT_PASS (pass_ipa_sra); > > diff --git a/gcc/timevar.def b/gcc/timevar.def > > index 63d9b005180..38fd7798768 100644 > > --- a/gcc/timevar.def > > +++ b/gcc/timevar.def > > @@ -72,6 +72,7 @@ DEFTIMEVAR (TV_CGRAPH_FUNC_EXPANSION , "callgraph > functions expansion") > > DEFTIMEVAR (TV_CGRAPH_IPA_PASSES , "callgraph ipa passes") > > DEFTIMEVAR (TV_IPA_ODR , "ipa ODR types") > > DEFTIMEVAR (TV_IPA_FNSUMMARY , "ipa function summary") > > +DEFTIMEVAR (TV_IPA_GUARDED_DEREF , "ipa guarded deref") > > DEFTIMEVAR (TV_IPA_UNREACHABLE , "ipa dead code removal") > > DEFTIMEVAR (TV_IPA_INHERITANCE , "ipa inheritance graph") > > DEFTIMEVAR (TV_IPA_VIRTUAL_CALL , "ipa virtual call target") > > diff --git a/gcc/tree-pass.h b/gcc/tree-pass.h > > index 8480d41384b..6cc200bd83e 100644 > > --- a/gcc/tree-pass.h > > +++ b/gcc/tree-pass.h > > @@ -525,6 +525,7 @@ extern ipa_opt_pass_d *make_pass_ipa_inline > (gcc::context *ctxt); > > extern simple_ipa_opt_pass *make_pass_ipa_free_lang_data (gcc::context > *ctxt); > > extern simple_ipa_opt_pass *make_pass_ipa_free_fn_summary (gcc::context > *ctxt); > > extern ipa_opt_pass_d *make_pass_ipa_cp (gcc::context *ctxt); > > +extern ipa_opt_pass_d *make_pass_ipa_guarded_deref (gcc::context *ctxt= ); > > extern ipa_opt_pass_d *make_pass_ipa_sra (gcc::context *ctxt); > > extern ipa_opt_pass_d *make_pass_ipa_icf (gcc::context *ctxt); > > extern ipa_opt_pass_d *make_pass_ipa_devirt (gcc::context *ctxt); > > -- > > 2.38.1 > > > --000000000000783dc605ed69d10c--