@c Copyright (C) 2010-2016 Free Software Foundation, Inc. @c This is part of the GCC manual. @c For copying conditions, see the file gcc.texi. @c Contributed by Jan Hubicka and @c Diego Novillo @node LTO @chapter Link Time Optimization @cindex lto @cindex whopr @cindex wpa @cindex ltrans Link Time Optimization (LTO) gives GCC the capability of dumping its internal representation (GIMPLE) to disk, so that all the different compilation units that make up a single executable can be optimized as a single module. This expands the scope of inter-procedural optimizations to encompass the whole program (or, rather, everything that is visible at link time). @menu * LTO Overview:: Overview of LTO. * LTO object file layout:: LTO file sections in ELF. * IPA:: Using summary information in IPA passes. * WHOPR:: Whole program assumptions, linker plugin and symbol visibilities. * Internal flags:: Internal flags controlling @code{lto1}. @end menu @node LTO Overview @section Design Overview Link time optimization is implemented as a GCC front end for a bytecode representation of GIMPLE that is emitted in special sections of @code{.o} files. Currently, LTO support is enabled in most ELF-based systems, as well as darwin, cygwin and mingw systems. Since GIMPLE bytecode is saved alongside final object code, object files generated with LTO support are larger than regular object files. This ``fat'' object format makes it easy to integrate LTO into existing build systems, as one can, for instance, produce archives of the files. Additionally, one might be able to ship one set of fat objects which could be used both for development and the production of optimized builds. A, perhaps surprising, side effect of this feature is that any mistake in the toolchain that leads to LTO information not being used (e.g.@: an older @code{libtool} calling @code{ld} directly). This is both an advantage, as the system is more robust, and a disadvantage, as the user is not informed that the optimization has been disabled. The current implementation only produces ``fat'' objects, effectively doubling compilation time and increasing file sizes up to 5x the original size. This hides the problem that some tools, such as @code{ar} and @code{nm}, need to understand symbol tables of LTO sections. These tools were extended to use the plugin infrastructure, and with these problems solved, GCC will also support ``slim'' objects consisting of the intermediate code alone. At the highest level, LTO splits the compiler in two. The first half (the ``writer'') produces a streaming representation of all the internal data structures needed to optimize and generate code. This includes declarations, types, the callgraph and the GIMPLE representation of function bodies. When @option{-flto} is given during compilation of a source file, the pass manager executes all the passes in @code{all_lto_gen_passes}. Currently, this phase is composed of two IPA passes: @itemize @bullet @item @code{pass_ipa_lto_gimple_out} This pass executes the function @code{lto_output} in @file{lto-streamer-out.c}, which traverses the call graph encoding every reachable declaration, type and function. This generates a memory representation of all the file sections described below. @item @code{pass_ipa_lto_finish_out} This pass executes the function @code{produce_asm_for_decls} in @file{lto-streamer-out.c}, which takes the memory image built in the previous pass and encodes it in the corresponding ELF file sections. @end itemize The second half of LTO support is the ``reader''. This is implemented as the GCC front end @file{lto1} in @file{lto/lto.c}. When @file{collect2} detects a link set of @code{.o}/@code{.a} files with LTO information and the @option{-flto} is enabled, it invokes @file{lto1} which reads the set of files and aggregates them into a single translation unit for optimization. The main entry point for the reader is @file{lto/lto.c}:@code{lto_main}. @subsection LTO modes of operation One of the main goals of the GCC link-time infrastructure was to allow effective compilation of large programs. For this reason GCC implements two link-time compilation modes. @enumerate @item @emph{LTO mode}, in which the whole program is read into the compiler at link-time and optimized in a similar way as if it were a single source-level compilation unit. @item @emph{WHOPR or partitioned mode}, designed to utilize multiple CPUs and/or a distributed compilation environment to quickly link large applications. WHOPR stands for WHOle Program optimizeR (not to be confused with the semantics of @option{-fwhole-program}). It partitions the aggregated callgraph from many different @code{.o} files and distributes the compilation of the sub-graphs to different CPUs. Note that distributed compilation is not implemented yet, but since the parallelism is facilitated via generating a @code{Makefile}, it would be easy to implement. @end enumerate WHOPR splits LTO into three main stages: @enumerate @item Local generation (LGEN) This stage executes in parallel. Every file in the program is compiled into the intermediate language and packaged together with the local call-graph and summary information. This stage is the same for both the LTO and WHOPR compilation mode. @item Whole Program Analysis (WPA) WPA is performed sequentially. The global call-graph is generated, and a global analysis procedure makes transformation decisions. The global call-graph is partitioned to facilitate parallel optimization during phase 3. The results of the WPA stage are stored into new object files which contain the partitions of program expressed in the intermediate language and the optimization decisions. @item Local transformations (LTRANS) This stage executes in parallel. All the decisions made during phase 2 are implemented locally in each partitioned object file, and the final object code is generated. Optimizations which cannot be decided efficiently during the phase 2 may be performed on the local call-graph partitions. @end enumerate WHOPR can be seen as an extension of the usual LTO mode of compilation. In LTO, WPA and LTRANS are executed within a single execution of the compiler, after the whole program has been read into memory. When compiling in WHOPR mode, the callgraph is partitioned during the WPA stage. The whole program is split into a given number of partitions of roughly the same size. The compiler tries to minimize the number of references which cross partition boundaries. The main advantage of WHOPR is to allow the parallel execution of LTRANS stages, which are the most time-consuming part of the compilation process. Additionally, it avoids the need to load the whole program into memory. @node LTO object file layout @section LTO file sections LTO information is stored in several ELF sections inside object files. Data structures and enum codes for sections are defined in @file{lto-streamer.h}. These sections are emitted from @file{lto-streamer-out.c} and mapped in all at once from @file{lto/lto.c}:@code{lto_file_read}. The individual functions dealing with the reading/writing of each section are described below. @itemize @bullet @item Command line options (@code{.gnu.lto_.opts}) This section contains the command line options used to generate the object files. This is used at link time to determine the optimization level and other settings when they are not explicitly specified at the linker command line. Currently, GCC does not support combining LTO object files compiled with different set of the command line options into a single binary. At link time, the options given on the command line and the options saved on all the files in a link-time set are applied globally. No attempt is made at validating the combination of flags (other than the usual validation done by option processing). This is implemented in @file{lto/lto.c}:@code{lto_read_all_file_options}. @item Symbol table (@code{.gnu.lto_.symtab}) This table replaces the ELF symbol table for functions and variables represented in the LTO IL. Symbols used and exported by the optimized assembly code of ``fat'' objects might not match the ones used and exported by the intermediate code. This table is necessary because the intermediate code is less optimized and thus requires a separate symbol table. Additionally, the binary code in the ``fat'' object will lack a call to a function, since the call was optimized out at compilation time after the intermediate language was streamed out. In some special cases, the same optimization may not happen during link-time optimization. This would lead to an undefined symbol if only one symbol table was used. The symbol table is emitted in @file{lto-streamer-out.c}:@code{produce_symtab}. @item Global declarations and types (@code{.gnu.lto_.decls}) This section contains an intermediate language dump of all declarations and types required to represent the callgraph, static variables and top-level debug info. The contents of this section are emitted in @file{lto-streamer-out.c}:@code{produce_asm_for_decls}. Types and symbols are emitted in a topological order that preserves the sharing of pointers when the file is read back in (@file{lto.c}:@code{read_cgraph_and_symbols}). @item The callgraph (@code{.gnu.lto_.cgraph}) This section contains the basic data structure used by the GCC inter-procedural optimization infrastructure. This section stores an annotated multi-graph which represents the functions and call sites as well as the variables, aliases and top-level @code{asm} statements. This section is emitted in @file{lto-streamer-out.c}:@code{output_cgraph} and read in @file{lto-cgraph.c}:@code{input_cgraph}. @item IPA references (@code{.gnu.lto_.refs}) This section contains references between function and static variables. It is emitted by @file{lto-cgraph.c}:@code{output_refs} and read by @file{lto-cgraph.c}:@code{input_refs}. @item Function bodies (@code{.gnu.lto_.function_body.}) This section contains function bodies in the intermediate language representation. Every function body is in a separate section to allow copying of the section independently to different object files or reading the function on demand. Functions are emitted in @file{lto-streamer-out.c}:@code{output_function} and read in @file{lto-streamer-in.c}:@code{input_function}. @item Static variable initializers (@code{.gnu.lto_.vars}) This section contains all the symbols in the global variable pool. It is emitted by @file{lto-cgraph.c}:@code{output_varpool} and read in @file{lto-cgraph.c}:@code{input_cgraph}. @item Summaries and optimization summaries used by IPA passes (@code{.gnu.lto_.}, where @code{} is one of @code{jmpfuncs}, @code{pureconst} or @code{reference}) These sections are used by IPA passes that need to emit summary information during LTO generation to be read and aggregated at link time. Each pass is responsible for implementing two pass manager hooks: one for writing the summary and another for reading it in. The format of these sections is entirely up to each individual pass. The only requirement is that the writer and reader hooks agree on the format. @end itemize @node IPA @section Using summary information in IPA passes Programs are represented internally as a @emph{callgraph} (a multi-graph where nodes are functions and edges are call sites) and a @emph{varpool} (a list of static and external variables in the program). The inter-procedural optimization is organized as a sequence of individual passes, which operate on the callgraph and the varpool. To make the implementation of WHOPR possible, every inter-procedural optimization pass is split into several stages that are executed at different times during WHOPR compilation: @itemize @bullet @item LGEN time @enumerate @item @emph{Generate summary} (@code{generate_summary} in @code{struct ipa_opt_pass_d}). This stage analyzes every function body and variable initializer is examined and stores relevant information into a pass-specific data structure. @item @emph{Write summary} (@code{write_summary} in @code{struct ipa_opt_pass_d}). This stage writes all the pass-specific information generated by @code{generate_summary}. Summaries go into their own @code{LTO_section_*} sections that have to be declared in @file{lto-streamer.h}:@code{enum lto_section_type}. A new section is created by calling @code{create_output_block} and data can be written using the @code{lto_output_*} routines. @end enumerate @item WPA time @enumerate @item @emph{Read summary} (@code{read_summary} in @code{struct ipa_opt_pass_d}). This stage reads all the pass-specific information in exactly the same order that it was written by @code{write_summary}. @item @emph{Execute} (@code{execute} in @code{struct opt_pass}). This performs inter-procedural propagation. This must be done without actual access to the individual function bodies or variable initializers. Typically, this results in a transitive closure operation over the summary information of all the nodes in the callgraph. @item @emph{Write optimization summary} (@code{write_optimization_summary} in @code{struct ipa_opt_pass_d}). This writes the result of the inter-procedural propagation into the object file. This can use the same data structures and helper routines used in @code{write_summary}. @end enumerate @item LTRANS time @enumerate @item @emph{Read optimization summary} (@code{read_optimization_summary} in @code{struct ipa_opt_pass_d}). The counterpart to @code{write_optimization_summary}. This reads the interprocedural optimization decisions in exactly the same format emitted by @code{write_optimization_summary}. @item @emph{Transform} (@code{function_transform} and @code{variable_transform} in @code{struct ipa_opt_pass_d}). The actual function bodies and variable initializers are updated based on the information passed down from the @emph{Execute} stage. @end enumerate @end itemize The implementation of the inter-procedural passes are shared between LTO, WHOPR and classic non-LTO compilation. @itemize @item During the traditional file-by-file mode every pass executes its own @emph{Generate summary}, @emph{Execute}, and @emph{Transform} stages within the single execution context of the compiler. @item In LTO compilation mode, every pass uses @emph{Generate summary} and @emph{Write summary} stages at compilation time, while the @emph{Read summary}, @emph{Execute}, and @emph{Transform} stages are executed at link time. @item In WHOPR mode all stages are used. @end itemize To simplify development, the GCC pass manager differentiates between normal inter-procedural passes and small inter-procedural passes. A @emph{small inter-procedural pass} (@code{SIMPLE_IPA_PASS}) is a pass that does everything at once and thus it can not be executed during WPA in WHOPR mode. It defines only the @emph{Execute} stage and during this stage it accesses and modifies the function bodies. Such passes are useful for optimization at LGEN or LTRANS time and are used, for example, to implement early optimization before writing object files. The simple inter-procedural passes can also be used for easier prototyping and development of a new inter-procedural pass. @subsection Virtual clones One of the main challenges of introducing the WHOPR compilation mode was addressing the interactions between optimization passes. In LTO compilation mode, the passes are executed in a sequence, each of which consists of analysis (or @emph{Generate summary}), propagation (or @emph{Execute}) and @emph{Transform} stages. Once the work of one pass is finished, the next pass sees the updated program representation and can execute. This makes the individual passes dependent on each other. In WHOPR mode all passes first execute their @emph{Generate summary} stage. Then summary writing marks the end of the LGEN stage. At WPA time, the summaries are read back into memory and all passes run the @emph{Execute} stage. Optimization summaries are streamed and sent to LTRANS, where all the passes execute the @emph{Transform} stage. Most optimization passes split naturally into analysis, propagation and transformation stages. But some do not. The main problem arises when one pass performs changes and the following pass gets confused by seeing different callgraphs between the @emph{Transform} stage and the @emph{Generate summary} or @emph{Execute} stage. This means that the passes are required to communicate their decisions with each other. To facilitate this communication, the GCC callgraph infrastructure implements @emph{virtual clones}, a method of representing the changes performed by the optimization passes in the callgraph without needing to update function bodies. A @emph{virtual clone} in the callgraph is a function that has no associated body, just a description of how to create its body based on a different function (which itself may be a virtual clone). The description of function modifications includes adjustments to the function's signature (which allows, for example, removing or adding function arguments), substitutions to perform on the function body, and, for inlined functions, a pointer to the function that it will be inlined into. It is also possible to redirect any edge of the callgraph from a function to its virtual clone. This implies updating of the call site to adjust for the new function signature. Most of the transformations performed by inter-procedural optimizations can be represented via virtual clones. For instance, a constant propagation pass can produce a virtual clone of the function which replaces one of its arguments by a constant. The inliner can represent its decisions by producing a clone of a function whose body will be later integrated into a given function. Using @emph{virtual clones}, the program can be easily updated during the @emph{Execute} stage, solving most of pass interactions problems that would otherwise occur during @emph{Transform}. Virtual clones are later materialized in the LTRANS stage and turned into real functions. Passes executed after the virtual clone were introduced also perform their @emph{Transform} stage on new functions, so for a pass there is no significant difference between operating on a real function or a virtual clone introduced before its @emph{Execute} stage. Optimization passes then work on virtual clones introduced before their @emph{Execute} stage as if they were real functions. The only difference is that clones are not visible during the @emph{Generate Summary} stage. To keep function summaries updated, the callgraph interface allows an optimizer to register a callback that is called every time a new clone is introduced as well as when the actual function or variable is generated or when a function or variable is removed. These hooks are registered in the @emph{Generate summary} stage and allow the pass to keep its information intact until the @emph{Execute} stage. The same hooks can also be registered during the @emph{Execute} stage to keep the optimization summaries updated for the @emph{Transform} stage. @subsection IPA references GCC represents IPA references in the callgraph. For a function or variable @code{A}, the @emph{IPA reference} is a list of all locations where the address of @code{A} is taken and, when @code{A} is a variable, a list of all direct stores and reads to/from @code{A}. References represent an oriented multi-graph on the union of nodes of the callgraph and the varpool. See @file{ipa-reference.c}:@code{ipa_reference_write_optimization_summary} and @file{ipa-reference.c}:@code{ipa_reference_read_optimization_summary} for details. @subsection Jump functions Suppose that an optimization pass sees a function @code{A} and it knows the values of (some of) its arguments. The @emph{jump function} describes the value of a parameter of a given function call in function @code{A} based on this knowledge. Jump functions are used by several optimizations, such as the inter-procedural constant propagation pass and the devirtualization pass. The inliner also uses jump functions to perform inlining of callbacks. @node WHOPR @section Whole program assumptions, linker plugin and symbol visibilities Link-time optimization gives relatively minor benefits when used alone. The problem is that propagation of inter-procedural information does not work well across functions and variables that are called or referenced by other compilation units (such as from a dynamically linked library). We say that such functions and variables are @emph{externally visible}. To make the situation even more difficult, many applications organize themselves as a set of shared libraries, and the default ELF visibility rules allow one to overwrite any externally visible symbol with a different symbol at runtime. This basically disables any optimizations across such functions and variables, because the compiler cannot be sure that the function body it is seeing is the same function body that will be used at runtime. Any function or variable not declared @code{static} in the sources degrades the quality of inter-procedural optimization. To avoid this problem the compiler must assume that it sees the whole program when doing link-time optimization. Strictly speaking, the whole program is rarely visible even at link-time. Standard system libraries are usually linked dynamically or not provided with the link-time information. In GCC, the whole program option (@option{-fwhole-program}) asserts that every function and variable defined in the current compilation unit is static, except for function @code{main} (note: at link time, the current unit is the union of all objects compiled with LTO). Since some functions and variables need to be referenced externally, for example by another DSO or from an assembler file, GCC also provides the function and variable attribute @code{externally_visible} which can be used to disable the effect of @option{-fwhole-program} on a specific symbol. The whole program mode assumptions are slightly more complex in C++, where inline functions in headers are put into @emph{COMDAT} sections. COMDAT function and variables can be defined by multiple object files and their bodies are unified at link-time and dynamic link-time. COMDAT functions are changed to local only when their address is not taken and thus un-sharing them with a library is not harmful. COMDAT variables always remain externally visible, however for readonly variables it is assumed that their initializers cannot be overwritten by a different value. GCC provides the function and variable attribute @code{visibility} that can be used to specify the visibility of externally visible symbols (or alternatively an @option{-fdefault-visibility} command line option). ELF defines the @code{default}, @code{protected}, @code{hidden} and @code{internal} visibilities. The most commonly used is visibility is @code{hidden}. It specifies that the symbol cannot be referenced from outside of the current shared library. Unfortunately, this information cannot be used directly by the link-time optimization in the compiler since the whole shared library also might contain non-LTO objects and those are not visible to the compiler. GCC solves this problem using linker plugins. A @emph{linker plugin} is an interface to the linker that allows an external program to claim the ownership of a given object file. The linker then performs the linking procedure by querying the plugin about the symbol table of the claimed objects and once the linking decisions are complete, the plugin is allowed to provide the final object file before the actual linking is made. The linker plugin obtains the symbol resolution information which specifies which symbols provided by the claimed objects are bound from the rest of a binary being linked. Currently, the linker plugin works only in combination with the Gold linker, but a GNU ld implementation is under development. GCC is designed to be independent of the rest of the toolchain and aims to support linkers without plugin support. For this reason it does not use the linker plugin by default. Instead, the object files are examined by @command{collect2} before being passed to the linker and objects found to have LTO sections are passed to @command{lto1} first. This mode does not work for library archives. The decision on what object files from the archive are needed depends on the actual linking and thus GCC would have to implement the linker itself. The resolution information is missing too and thus GCC needs to make an educated guess based on @option{-fwhole-program}. Without the linker plugin GCC also assumes that symbols are declared @code{hidden} and not referred by non-LTO code by default. @node Internal flags @section Internal flags controlling @code{lto1} The following flags are passed into @command{lto1} and are not meant to be used directly from the command line. @itemize @item -fwpa @opindex fwpa This option runs the serial part of the link-time optimizer performing the inter-procedural propagation (WPA mode). The compiler reads in summary information from all inputs and performs an analysis based on summary information only. It generates object files for subsequent runs of the link-time optimizer where individual object files are optimized using both summary information from the WPA mode and the actual function bodies. It then drives the LTRANS phase. @item -fltrans @opindex fltrans This option runs the link-time optimizer in the local-transformation (LTRANS) mode, which reads in output from a previous run of the LTO in WPA mode. In the LTRANS mode, LTO optimizes an object and produces the final assembly. @item -fltrans-output-list=@var{file} @opindex fltrans-output-list This option specifies a file to which the names of LTRANS output files are written. This option is only meaningful in conjunction with @option{-fwpa}. @item -fresolution=@var{file} @opindex fresolution This option specifies the linker resolution file. This option is only meaningful in conjunction with @option{-fwpa} and as option to pass through to the LTO linker plugin. @end itemize