[llvm-dev] RFC: LLVM Assembly format for ThinLTO Summary

[Teresa Johnson via llvm-dev]

On Thu, May 3, 2018 at 2:58 PM, Peter Collingbourne <peter at pcc.me.uk> wrote:

> Hi Teresa,
>
> I have re-read your proposal, and I'm not getting how you plan to
> represent combined summaries with this. Unless I'm missing something, there
> doesn't seem to be a way to write out summaries that is independent of the
> global values that they relate to. Is that something that you plan to
> address later?
>

I envisioned that the combined index assembly files would only contain
GUIDs, not GV names, just as we do in the combined index bitcode files.
Does that answer your question?

Thanks,
Teresa


> Peter
>
> On Tue, Apr 24, 2018 at 7:43 AM, Teresa Johnson <tejohnson at google.com>
> wrote:
>
>> Hi everyone,
>>
>> I started working on a long-standing request to have the summary dumped
>> in a readable format to text, and specifically to emit to LLVM assembly.
>> Proposal below, please let me know your thoughts.
>>
>> Thanks,
>> Teresa
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>> *RFC: LLVM Assembly format for ThinLTO
>> Summary========================================Background-----------------ThinLTO
>> operates on small summaries computed during the compile step (i.e. with “-c
>> -flto=thin”), which are then analyzed and updated during the Thin Link
>> stage, and utilized to perform IR updates during the post-link ThinLTO
>> backends. The summaries are emitted as LLVM Bitcode, however, not currently
>> in the LLVM assembly.There are two ways to generate a bitcode file
>> containing summary records for a module: 1. Compile with “clang -c
>> -flto=thin”2. Build from LLVM assembly using “opt -module-summary”Either of
>> these will result in the ModuleSummaryIndex analysis pass (which builds the
>> summary index in memory for a module) to be added to the pipeline just
>> before bitcode emission.Additionally, a combined index is created by
>> merging all the per-module indexes during the Thin Link, which is
>> optionally emitted as a bitcode file.Currently, the only way to view these
>> records is via “llvm-bcanalyzer -dump”, then manually decoding the raw
>> bitcode dumps.Relatedly, there is YAML reader/writer support for CFI
>> related summary fields (-wholeprogramdevirt-read-summary and
>> -wholeprogramdevirt-write-summary). Last summer, GSOC student Charles
>> Saternos implemented support to dump the summary in YAML from llvm-lto2
>> (D34080), including the rest of the summary fields (D34063), however, there
>> was pushback on the related RFC for dumping via YAML or another format
>> rather than emitting as LLVM assembly.Goals: 1. Define LLVM assembly format
>> for summary index2. Define interaction between parsing of summary from LLVM
>> assembly and synthesis of new summary index from IR.3. Implement printing
>> and parsing of summary index LLVM assemblyProposed LLVM Assembly
>> Format----------------------------------------------There are several top
>> level data structures within the ModuleSummaryIndex: 1.
>> ModulePathStringTable: Holds the paths to the modules summarized in the
>> index (only one entry for per-module indexes and multiple in the combined
>> index), along with their hashes (for incremental builds and global
>> promotion).2. GlobalValueMap: A map from global value GUIDs to the
>> corresponding function/variable/alias summary (or summaries for the
>> combined index and weak linkage).3. CFI-related data structures (TypeIdMap,
>> CfiFunctionDefs, and CfiFunctionDecls)I have a WIP patch to AsmWriter.cpp
>> to print the ModuleSummaryIndex that I was using to play with the format.
>> It currently prints 1 and 2 above. I’ve left the CFI related summary data
>> structures as a TODO for now, until the format is at least conceptually
>> agreed, but from looking at those I don’t see an issue with using the same
>> format (with a note/question for Peter on CFI type test representation
>> below).I modeled the proposed format on metadata, with a few key
>> differences noted below. Like metadata, I propose enumerating the entries
>> with the SlotTracker, and prefixing them with a special character. Avoiding
>> characters already used in some fashion (i.e. “!” for metadata and “#” for
>> attributes), I initially have chosen “^”. Open to suggestions
>> though.Consider the following example:extern void foo();int X;int bar() {
>>  foo();  return X;}void barAlias() __attribute__ ((alias ("bar")));int
>> main() {  barAlias();  return bar();}The proposed format has one entry per
>> ModulePathStringTable entry and one per GlobalValueMap/GUID, and looks
>> like:^0 = module: {path: testA.o, hash: 5487197307045666224}^1 = gv: {guid:
>> 1881667236089500162, name: X, summaries: {variable: {module: ^0, flags:
>> {linkage: common, notEligibleToImport: 0, live: 0, dsoLocal: 1}}}}^2 = gv:
>> {guid: 6699318081062747564, name: foo}^3 = gv: {guid: 15822663052811949562,
>> name: main, summaries: {function: {module: ^0, flags: {linkage: extern,
>> notEligibleToImport: 1, live: 0, dsoLocal: 1}, insts: 5, funcFlags:
>> {readNone: 0, readOnly: 0, noRecurse: 0, returnDoesNotAlias: 0}, calls:
>> {{callee: ^5, hotness: unknown}, {callee: ^4, hotness: unknown}}}}}^4 = gv:
>> {guid: 16434608426314478903, name: bar, summaries: {function: {module: ^0,
>> flags: {linkage: extern, notEligibleToImport: 1, live: 0, dsoLocal: 1},
>> insts: 3, funcFlags: {readNone: 0, readOnly: 0, noRecurse: 0,
>> returnDoesNotAlias: 0}, calls: {{callee: ^2, hotness: unknown}}, refs:
>> {^1}}}}^5 = gv: {guid: 18040127437030252312, name: barAlias, summaries:
>> {alias: {module: ^0, flags: {linkage: extern, notEligibleToImport: 0, live:
>> 0, dsoLocal: 1}, aliasee: ^4}}}Like metadata, the fields are tagged
>> (currently using lower camel case, maybe upper camel case would be
>> preferable).The proposed format has a structure that reflects the data
>> structures in the summary index. For example, consider the entry “^4”. This
>> corresponds to the function “bar”. The entry for that GUID in the
>> GlobalValueMap contains a list of summaries. For per-module summaries such
>> as this, there will be at most one summary (with no summary list for an
>> external function like “foo”). In the combined summary there may be
>> multiple, e.g. in the case of linkonce_odr functions which have definitions
>> in multiple modules. The summary list for bar (“^4”) contains a
>> FunctionSummary, so the summary is tagged “function:”. The FunctionSummary
>> contains both a flags structure (inherited from the base GlobalValueSummary
>> class), and a funcFlags structure (specific to FunctionSummary). It
>> therefore contains a brace-enclosed list of flag tags/values for each.Where
>> a global value summary references another global value summary (e.g. via a
>> call list, reference list, or aliasee), the entry is referenced by its
>> slot. E.g. the alias “barAlias” (“^5”) references its aliasee “bar” as
>> “^4”.Note that in comparison metadata assembly entries tend to be much more
>> decomposed since many metadata fields are themselves metadata (so then
>> entries tend to be shorter with references to other metadata
>> nodes).Currently, I am emitting the summary entries at the end, after the
>> metadata nodes. Note that the ModuleSummaryIndex is not currently
>> referenced from the Module, and isn’t currently created when parsing the
>> Module IR bitcode (there is a separate derived class for reading the
>> ModuleSummaryIndex from bitcode). This is because they are not currently
>> used at the same time. However, in the future there is no reason why we
>> couldn’t tag the global values in the Module’s LLVM assembly with the
>> corresponding summary entry if the ModuleSummaryIndex is available when
>> printing the Module in the assembly writer. I.e. we could do the following
>> for “main” from the above example when printing the IR definition (note the
>> “^3” at the end):define  dso_local i32 @main() #0 !dbg !17 ^3 {For CFI data
>> structures, the format would be similar. It appears that TypeIds are
>> referred to by string name in the top level TypeIdMap (std::map indexed by
>> std::string type identifier), whereas they are referenced by GUID within
>> the FunctionSummary class (i.e. the TypeTests vector and the VFuncId
>> structure). For the LLVM assembly I think there should be a top level entry
>> for each TypeIdMap, which lists both the type identifier string and its
>> GUID (followed by its associated information stored in the map), and the
>> TypeTests/VFuncId references on the FunctionSummary entries can reference
>> it by summary slot number. I.e. something like:^1 = typeid: {guid: 12345,
>> identifier: name_of_type, …^2 = gv: {... {function: {.... typeTests: {^1,
>> …Peter - is that correct and does that sound ok?Issues when Parsing of
>> Summaries from
>> Assembly--------------------------------------------------------------------When
>> reading an LLVM assembly file containing module summary entries, a
>> ModuleSummaryIndex will be created from the entries.Things to consider are
>> the behavior when: - Invoked with “opt -module-summary” (which currently
>> builds a new summary index from the IR). Options:1. recompute summary and
>> throw away summary in the assembly file2. ignore -module-summary and build
>> the summary from the LLVM assembly3. give an error4. compare the two
>> summaries (one created from the assembly and the new one created by the
>> analysis phase from the IR), and error if they are different.My opinion is
>> to do a),  so that the behavior using -module-summary doesn’t change. We
>> also need a way to force building of a fresh module summary for cases where
>> the user has modified the LLVM assembly of the IR (see below). - How to
>> handle older LLVM assembly files that don’t contain new summary fields.
>> Options:1. Force the LLVM assembly file to be recreated with a new summary.
>> I.e. “opt -module-summary -o - | llvm-dis”.2. Auto-upgrade, by silently
>> creating conservative values for the new summary entries.I lean towards b)
>> (when possible) for user-friendliness and to reduce required churn on test
>> inputs. - How to handle partial or incorrect LLVM assembly summary entries.
>> How to handle partial summaries depends in part on how we answer the prior
>> question about auto-upgrading. I think the best option like there is to
>> handle it automatically when possible. However, I do think we should error
>> on glaring errors like obviously missing information. For example, when
>> there is summary data in the LLVM assembly, but summary entries are missing
>> for some global values. E.g. if the user modified the assembly to add a
>> function but forgot to add a corresponding summary entry. We could still
>> have subtle issues (e.g. user adds a new call but forgets to update the
>> caller’s summary call list), but it will be harder to detect those.*
>>
>> --
>> Teresa Johnson |  Software Engineer |  tejohnson at google.com |
>>  408-460-2413
>>
>
>
>
> --
> --
> Peter
>



-- 
Teresa Johnson |  Software Engineer |  tejohnson at google.com |  408-460-2413
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