Instrumentation Profile Format¶
Overview¶
Clang supports two types of profiling via instrumentation [1]: frontend-based and IR-based, and both could support a variety of use cases [2] . This document describes two binary serialization formats (raw and indexed) to store instrumented profiles with a specific emphasis on IRPGO use case, in the sense that when specific header fields and payload sections have different ways of interpretation across use cases, the documentation is based on IRPGO.
Note
Frontend-generated profiles are used together with coverage mapping for source-based code coverage. The coverage mapping format is different from profile format.
Raw Profile Format¶
The raw profile is generated by running the instrumented binary. The raw profile data from an executable or a shared library [3] consists of a header and multiple sections, with each section as a memory dump. The raw profile data needs to be reasonably compact and fast to generate.
There are no backward or forward version compatiblity guarantees for the raw profile format. That is, compilers and tools require a specific raw profile version to parse the profiles.
To feed profiles back into compilers for an optimized build (e.g., via
-fprofile-use
for IR instrumentation), a raw profile must to be converted into
indexed format.
General Storage Layout¶
The storage layout of raw profile data format is illustrated below. Basically, when the raw profile is read into an memory buffer, the actual byte offset of a section is inferred from the section’s order in the layout and size information of all the sections ahead of it.
+----+-----------------------+
| | Magic |
| +-----------------------+
| | Version |
| +-----------------------+
H | Size Info for |
E | Section 1 |
A +-----------------------+
D | Size Info for |
E | Section 2 |
R +-----------------------+
| | ... |
| +-----------------------+
| | Size Info for |
| | Section N |
+----+-----------------------+
P | Section 1 |
A +-----------------------+
Y | Section 2 |
L +-----------------------+
O | ... |
A +-----------------------+
D | Section N |
+----+-----------------------+
Note
Sections might be padded to meet specific alignment requirements. For simplicity, header fields and data sections solely for padding purpose are omitted in the data layout graph above and the rest of this document.
Header¶
Magic
Magic number encodes profile format (raw, indexed or text). For the raw format, the magic number also encodes the endianness (big or little) and C pointer size (4 or 8 bytes) of the platform on which the profile is generated.
A factory method reads the magic number to construct reader properly and returns error upon unrecognized format. Specifically, the factory method and raw profile reader implementation make sure that a raw profile file could be read back on a platform with the opposite endianness and/or the other C pointer size.
Version
The lower 32 bits specify the actual version and the most significant 32 bits specify the variant types of the profile. IR-based instrumentation PGO and context-sensitive IR-based instrumentation PGO are two variant types.
BinaryIdsSize
The byte size of binary id section.
NumData
The number of profile metadata. The byte size of profile metadata section could be computed with this field.
NumCounter
The number of entries in the profile counter section. The byte size of counter section could be computed with this field.
NumBitmapBytes
The number of bytes in the profile bitmap section.
NamesSize
The number of bytes in the name section.
CountersDelta
This field records the in-memory address difference between the profile metadata and counter section in the instrumented binary, i.e.,
start(__llvm_prf_cnts) - start(__llvm_prf_data)
.It’s used jointly with the CounterPtr field to compute the counter offset relative to
start(__llvm_prf_cnts)
. Check out calculation-of-counter-offset for a visualized explanation.Note
The
__llvm_prf_data
object file section might not be loaded into memory when instrumented binary runs or might not get generated in the instrumented binary in the first place. In those cases,CountersDelta
is not used and other mechanisms are used to match counters with instrumented code. See lightweight instrumentation and binary profile correlation for examples.BitmapDelta
This field records the in-memory address difference between the profile metadata and bitmap section in the instrumented binary, i.e.,
start(__llvm_prf_bits) - start(__llvm_prf_data)
.It’s used jointly with the BitmapPtr to find the bitmap of a profile data record, in a similar way to how counters are referenced as explained by calculation-of-counter-offset .
Similar to CountersDelta field, this field may not be used in non-PGO variants of profiles.
NamesDelta
Records the in-memory address of name section. Not used except for raw profile reader error checking.
NumVTables
Records the number of instrumented vtable entries in the binary. Used for type profiling.
VNamesSize
Records the byte size in the virtual table names section. Used for type profiling.
ValueKindLast
Records the number of value kinds. Macro VALUE_PROF_KIND defines the value kinds with a description of the kind.
Payload Sections¶
Binary Ids¶
Stores the binary ids of the instrumented binaries to associate binaries with profiles for source code coverage. See binary id RFC for the design.
Profile Metadata¶
This section stores the metadata to map counters and value profiles back to instrumented code regions (e.g., LLVM IR for IRPGO).
The in-memory representation of the metadata is __llvm_profile_data. Some fields are used to reference data from other sections in the profile. The fields are documented as follows:
NameRef
The MD5 of the function’s PGO name. PGO name has the format
[<filepath><delimiter>]<mangled-name>
where<filepath>
and<delimiter>
are provided for local-linkage functions to tell possibly identical functions.
FuncHash
A checksum of the function’s IR, taking control flow graph and instrumented value sites into accounts. See computeCFGHash for details.
CounterPtr
The in-memory address difference between profile data and the start of corresponding counters. Counter position is stored this way (as a link-time constant) to reduce instrumented binary size compared with snapshotting the address of symbols directly. See commit a1532ed for further information.
Note
CounterPtr
might represent a different value for non-IRPGO use case. For example, for binary profile correlation, it represents the absolute address of counter. When in doubt, check source code.
BitmapPtr
The in-memory address difference between profile data and the start address of corresponding bitmap.
Note
Similar to CounterPtr, this field may represent a different value for non-IRPGO use case.
FunctionPointer
Records the function address when instrumented binary runs. This is used to map the profiled callee address of indirect calls to the
NameRef
during conversion from raw to indexed profiles.Values
Represents value profiles in a two dimensional array. The number of elements in the first dimension is the number of instrumented value sites across all kinds. Each element in the first dimension is the head of a linked list, and the each element in the second dimension is linked list element, carrying
<profiled-value, count>
as payload. This is used by compiler runtime when writing out value profiles.Note
Value profiling is supported by frontend and IR PGO instrumentation, but it’s not supported in all cases (e.g., lightweight instrumentation).
NumCounters
The number of counters for the instrumented function.
NumValueSites
This is an array of counters, and each counter represents the number of instrumented sites for a kind of value in the function.
NumBitmapBytes
The number of bitmap bytes for the function.
Profile Counters¶
For PGO [4], the counters within an instrumented function of a specific FuncHash are stored contiguously and in an order that is consistent with instrumentation points selection.
As mentioned above, the recorded counter offset is relative to the profile metadata. So how are function counters located in the raw profile data?
Basically, the profile reader iterates profile metadata (from the profile metadata section) and makes use of the recorded relative distances, as illustrated below.
+ --> start(__llvm_prf_data) --> +---------------------+ ------------+
| | Data 1 | |
| +---------------------+ =====|| |
| | Data 2 | || |
| +---------------------+ || |
| | ... | || |
Counter| +---------------------+ || |
Delta | | Data N | || |
| +---------------------+ || | CounterPtr1
| || |
| CounterPtr2 || |
| || |
| || |
+ --> start(__llvm_prf_cnts) --> +---------------------+ || |
| ... | || |
+---------------------+ -----||----+
| Counter for | ||
| Data 1 | ||
+---------------------+ ||
| ... | ||
+---------------------+ =====||
| Counter for |
| Data 2 |
+---------------------+
| ... |
+---------------------+
| Counter for |
| Data N |
+---------------------+
In the graph,
The profile header records
CounterDelta
with the value asstart(__llvm_prf_cnts) - start(__llvm_prf_data)
. We will call itCounterDeltaInitVal
below for convenience.For each profile data record
ProfileDataN
,CounterPtr
is recorded asstart(CounterN) - start(ProfileDataN)
, whereProfileDataN
is the N-th entry in__llvm_prf_data
, andCounterN
represents the corresponding profile counters.
Each time the reader advances to the next data record, it updates CounterDelta
to minus the size of one ProfileData
.
For the counter corresponding to the first data record, the byte offset
relative to the start of the counter section is calculated as CounterPtr1 - CounterDeltaInitVal
.
When profile reader advances to the second data record, note CounterDelta
is updated to CounterDeltaInitVal - sizeof(ProfileData)
.
Thus the byte offset relative to the start of the counter section is calculated
as CounterPtr2 - (CounterDeltaInitVal - sizeof(ProfileData))
.
Bitmap¶
This section is used for source-based Modified Condition/Decision Coverage code coverage. Check out Bitmap RFC for the design.
Names¶
This section contains possibly compressed concatenated string of functions’ PGO names. If compressed, zlib library is used.
Function names serve as keys in the PGO data hash table when raw profiles are
converted into indexed profiles. They are also crucial for llvm-profdata
to
show the profiles in a human-readable way.
Virtual Table Profile Data¶
This section is used for type profiling. Each entry corresponds to one virtual table and is defined by the following C++ struct
struct VTableProfData {
// The start address of the vtable, collected at runtime.
uint64_t StartAddress;
// The byte size of the vtable. `StartAddress` and `ByteSize` specifies an address range to look up.
uint32_t ByteSize;
// The hash of vtable's (PGO) name
uint64_t MD5HashOfName;
};
At profile use time, the compiler looks up a profiled address in the sorted vtable address ranges and maps the address to a specific vtable through hashed name.
Virtual Table Names¶
This section is similar to function names section above, except it contains the PGO names of profiled virtual tables. It’s a standalone section such that raw profile readers could directly find each name set by accessing the corresponding profile data section.
This section is stored in raw profiles such that llvm-profdata could show the profiles in a human-readable way.
Value Profile Data¶
This section contains the profile data for value profiling.
The value profiles corresponding to a profile metadata are serialized contiguously as one record, and value profile records are stored in the same order as the respective profile data, such that a raw profile reader advances the pointer to profile data and the pointer to value profile records simutaneously [5] to find value profiles for a per function, per FuncHash profile data.
Indexed Profile Format¶
Indexed profiles are generated from llvm-profdata
. In the indexed profiles,
function data are organized as on-disk hash table such that compilers can
look up profile data for functions in an IR module.
Compilers and tools must retain backward compatibility with indexed profiles. That is, a tool or a compiler built at newer versions of code must understand profiles generated by older tools or compilers.
General Storage Layout¶
The ASCII art depicts the general storage layout of indexed profiles. Specifically, the indexed profile header describes the byte offset of individual payload sections.
+-----------------------+---+
| Magic | |
+-----------------------+ |
| Version | |
+-----------------------+ |
| HashType | H
+-----------------------+ E
| Byte Offset | A
+------ | of section A | D
| +-----------------------+ E
| | Byte Of fset | R
+-----------| of section B | |
| | +-----------------------+ |
| | | ... | |
| | +-----------------------+ |
| | | Byte Offset | |
+---------------| of section Z | |
| | | +-----------------------+---+
| | | | Profile Summary | |
| | | +-----------------------+ P
| | +------>| Section A | A
| | +-----------------------+ Y
| +---------->| Section B | L
| +-----------------------+ O
| | ... | A
| +-----------------------+ D
+-------------->| Section Z | |
+-----------------------+---+
Note
Profile summary section is at the beginning of payload. It’s right after the header so its position is implicitly known after reading the header.
Header¶
The Header struct is the source of truth and struct fields should explain what’s in the header. At a high level, *Offset fields record section byte offsets, which are used by readers to locate interesting sections and skip uninteresting ones.
Note
To maintain backward compatibility of the indexed profiles, existing fields shouldn’t be deleted from struct definition; the field order shouldn’t be modified. New fields should be appended.
Payload Sections¶
(CS) Profile Summary¶
This section is right after profile header. It stores the serialized profile summary. For context-sensitive IR-based instrumentation PGO, this section stores an additional profile summary corresponding to the context-sensitive profiles.
Function data¶
This section stores functions and their profiling data as an on-disk hash table. Profile data for functions with the same name are grouped together and share one hash table entry (the functions may come from different shared libraries for instance). The profile data for them are organized as a sequence of key-value pair where the key is FuncHash, and the value is profiled information (represented by InstrProfRecord) for the function.
MemProf Profile data¶
This section stores function’s memory profiling data. See MemProf binary serialization format RFC for the design.
Binary Ids¶
The section is used to carry on binary id information from raw profiles.
Temporal Profile Traces¶
The section is used to carry on temporal profile information from raw profiles. See temporal profiling for the design.
Virtual Table Names¶
This section is used to store the names of vtables from raw profile in the indexed profile.
Unlike function names which are stored as keys of function data hash table, vtable names need to be stored in a standalone section in indexed profiles. This way, llvm-profdata could show the profiled vtable information in a human-readable way.
Profile Data Usage¶
llvm-profdata
is the command line tool to display and process instrumentation-
based profile data. For supported usages, check out llvm-profdata documentation.