12 KiB
Tools for Analyzing Chrome's Binary Size
These tools currently focus on supporting Android. They somewhat work with Linux builds. As for Windows, some great tools already exist and are documented here:
There is also a dedicated mailing-list for binary size discussions:
Bugs are tracked here:
[TOC]
diagnose_bloat.py
Determine the cause of binary size bloat between two commits. Works for Android and Linux (although Linux symbol diffs have issues, as noted below).
How it Works
- Builds multiple revisions using release GN args.
- Default is to build just two revisions (before & after commit)
- Rather than building, can fetch build artifacts and
.size
files from perf bots (--cloud
)
- Measures all outputs using
resource_size.py
andsupersize
. - Saves & displays a breakdown of the difference in binary sizes.
Example Usage
# Build and diff monochrome_public_apk HEAD^ and HEAD.
tools/binary_size/diagnose_bloat.py HEAD -v
# Build and diff monochrome_apk HEAD^ and HEAD.
tools/binary_size/diagnose_bloat.py HEAD --enable-chrome-android-internal -v
# Build and diff monochrome_public_apk HEAD^ and HEAD without is_official_build.
tools/binary_size/diagnose_bloat.py HEAD --gn-args="is_official_build=false" -v
# Diff BEFORE_REV and AFTER_REV using build artifacts downloaded from perf bots.
tools/binary_size/diagnose_bloat.py AFTER_REV --reference-rev BEFORE_REV --cloud -v
# Fetch a .size, libmonochrome.so, and MonochromePublic.apk from perf bots (Googlers only):
tools/binary_size/diagnose_bloat.py AFTER_REV --cloud --unstripped --single
# Build and diff all contiguous revs in range BEFORE_REV..AFTER_REV for src/v8.
tools/binary_size/diagnose_bloat.py AFTER_REV --reference-rev BEFORE_REV --subrepo v8 --all -v
# Display detailed usage info (there are many options).
tools/binary_size/diagnose_bloat.py -h
Super Size
Collect, archive, and analyze Chrome's binary size. Supports Android and Linux (although Linux has issues).
.size
files are archived on perf builders so that regressions can be quickly
analyzed (via diagnose_bloat.py --cloud
).
.size
files are archived on official builders so that symbols can be diff'ed
between milestones.
Technical Details
What's in a .size File?
.size
files are gzipped plain text files that contain:
- A list of section sizes, including:
- .so sections as reported by
readelf -S
- .pak and .dex sections for apk files
- .so sections as reported by
- Metadata (apk size, GN args, filenames, timestamps, git revision, build id),
- A list of symbols, including name, address, size, padding (caused by alignment), and associated source/object files.
How are Symbols Collected?
Native Symbols
- Symbol list is Extracted from linker
.map
file.- Map files contain some unique pieces of information compared to
nm
output, such as** merge strings
entries, and some unnamed symbols (which although unnamed, contain the.o
path).
- Map files contain some unique pieces of information compared to
.o
files are mapped to.cc
files by parsing.ninja
files.- This means that
.h
files are never listed as sources. No information about inlined symbols is gathered.
- This means that
** merge strings
symbols are further broken down into individual string literal symbols. This is done by reading string literals from.o
files, and then searching for them within the** merge strings
sections.- Symbol aliases:
- Aliases have the same address and size, but report their
.pss
as.size / .num_aliases
. - Type 1: Different names. Caused by identical code folding.
- These are collected from debug information via
nm elf-file
.
- These are collected from debug information via
- Type 2: Same names, different paths. Caused by inline functions defined in
.h
files.- These are collected by running
nm
on each.o
file. - Normally represented using one alias per path, but are sometimes
collapsed into a single symbol with a path of
{shared}/$SYMBOL_COUNT
. This collapsing is done only for symbols owned by a large number of paths.
- These are collected by running
- Type 3: String literals that are de-duped at link-time.
- These are found as part of the string literal extraction process.
- Aliases have the same address and size, but report their
Pak Symbols
- Grit creates a mapping between numeric id and textual id for grd files.
- A side effect of pak whitelist generation is a mapping of
.cc
to numeric id. - A complete per-apk mapping of numeric id to textual id is stored in the
output_dir/size-info
dir.
- A side effect of pak whitelist generation is a mapping of
supersize
uses these two mappings to find associated source files for the pak entries found in all of the apk's.pak
files.- Pak entries with the same name are merged into a single symbol.
- This is the case of pak files for translations.
- The original grd file paths are stored in the full name of each symbol.
- Pak entries with the same name are merged into a single symbol.
Dex Symbols
- Java compile targets create a mapping between java fully qualified names
(FQN) and source files.
- For
.java
files the FQN of the public class is mapped to the file. - For
.srcjar
files the FQN of the public class is mapped to the.srcjar
file path. - A complete per-apk class FQN to source mapping is stored in the
output_dir/size-info
dir.
- For
- The
apkanalyzer
sdk tool is used to find the size and FQN of entries in the dex file.- If a proguard
.mapping
file is available, that is used to get back the original FQN.
- If a proguard
- The output from
apkanalyzer
is used bysupersize
along with the mapping file to find associated source files for the dex entries found in all of the apk's.dex
files.
Common Symbols
- Shared bytes are stored in symbols with names starting with
Overhead:
.- Elf file, dex file, pak files, apk files all have compression overhead.
- These are treated as padding-only symbols to de-emphasize them in diffs.
- It is expected that these symbols have minor fluctuations since they are affected by changes in compressibility.
- All other files in an apk have one symbol each under the
.other
section with their corresponding path in the apk as their associated path.
What Other Processing Happens?
-
Path normalization:
- Prefixes are removed:
out/Release/
,gen/
,obj/
- Archive names made more pathy:
foo/bar.a(baz.o)
->foo/bar.a/baz.o
- Shared symbols do not store the complete source paths. Instead, the
common ancestor is computed and stored as the path.
- Example:
base/{shared}/3
(the "3" means three different files contain the symbol)
- Example:
- Prefixes are removed:
-
Name normalization:
(anonymous::)
is removed from names (and stored as a symbol flag).[clone]
suffix removed (and stored as a symbol flag).vtable for FOO
->Foo [vtable]
- Mangling done by linkers is undone (e.g. prefixing with "unlikely.")
- Names are processed into:
name
: Name without template and argument parameterstemplate_name
: Name without argument parameters.full_name
: Name with all parameters.
-
Clustering:
- Compiler & linker optimizations can cause symbols to be broken into multiple parts to become candidates for inlining ("partial inlining").
- These symbols are sometimes suffixed with "
[clone]
" (removed by normalization). - Clustering creates groups containing all pieces of a symbol (in the case where multiple pieces remain after inlining).
- Clustering is done by default on
SizeInfo.symbols
. To view unclustered symbols, useSizeInfo.raw_symbols
.
-
Diffing:
- Some heuristics for matching up before/after symbols.
-
Simulated compression:
- Only some
.pak
files are compressed and others are kept uncompressed. - To get a reasonable idea of actual impact to final apk size, we use a
constant compression factor for all the compressed
.pak
files.- This prevents swings in compressed sizes for all symbols when new entries are added or old entries are removed.
- The constant is chosen so that it minimizes overall discrepancy with actual total compressed sizes.
- Only some
Is Super Size a Generic Tool?
No. Most of the logic is would could work for any ELF executable. However, being a generic tool is not a goal. Some examples of existing Chrome-specific logic:
- Assumes
.ninja
build rules are available. - Heuristic for locating
.so
given.apk
. - Requires
size-info
dir in output directory to analyze.pak
and.dex
files.
Usage: archive
Collect size information and dump it into a .size
file.
*** note Note: Refer to diagnose_bloat.py for list of GN args to build a Release binary (or just use the tool with --single).
Googlers: If you just want a .size
for a commit on master:
GIT_REV="HEAD~200"
tools/binary_size/diagnose_bloat.py --single --cloud --unstripped $GIT_REV
Example Usage:
# Android:
ninja -C out/Release -j 1000 apks/ChromePublic.apk
tools/binary_size/supersize archive chrome.size --apk-file out/Release/apks/ChromePublic.apk -v
# Linux:
ninja -C out/Release -j 1000 chrome
tools/binary_size/supersize archive chrome.size --elf-file out/Release/chrome -v
Usage: html_report
Creates an interactive size breakdown (by source path) as a stand-alone html report.
Example output: https://notwoods.github.io/chrome-supersize-reports/
Example Usage:
# Creates the data file ./report.ndjson, generated based on ./chrome.size
tools/binary_size/supersize html_report chrome.size --report-file report.ndjson -v
# Includes every symbol in the data file, although it will take longer to load.
tools/binary_size/supersize html_report chrome.size --report-file report.ndjson --all-symbols
# Create a data file showing a diff between two .size files.
tools/binary_size/supersize html_report after.size --diff-with before.size --report-file report.ndjson
Usage: start_server
Locally view the data file generated by html_report
, by starting a web server
that links to a data file.
Example Usage:
# Starts a local server to view the data in ./report.ndjson
tools/binary_size/supersize start_server report.ndjson
# Set a custom address and port.
tools/binary_size/supersize start_server report.ndjson -a localhost -p 8080
Usage: diff
A convenience command equivalent to: console before.size after.size --query='Print(Diff(size_info1, size_info2))'
Example Usage:
tools/binary_size/supersize diff before.size after.size --all
Usage: console
Starts a Python interpreter where you can run custom queries, or run pre-made
queries from canned_queries.py
.
Example Usage:
# Prints size infomation and exits (does not enter interactive mode).
tools/binary_size/supersize console chrome.size --query='Print(size_info)'
# Enters a Python REPL (it will print more guidance).
tools/binary_size/supersize console chrome.size
Example session:
>>> ShowExamples() # Get some inspiration.
...
>>> sorted = size_info.symbols.WhereInSection('t').Sorted()
>>> Print(sorted) # Have a look at the largest symbols.
...
>>> sym = sorted.WhereNameMatches('TrellisQuantizeBlock')[0]
>>> Disassemble(sym) # Time to learn assembly.
...
>>> help(canned_queries)
...
>>> Print(canned_queries.TemplatesByName(depth=-1))
...
>>> syms = size_info.symbols.WherePathMatches(r'skia').Sorted()
>>> Print(syms, verbose=True) # Show full symbol names with parameter types.
...
>>> # Dump all string literals from skia files to "strings.txt".
>>> Print((t[1] for t in ReadStringLiterals(syms)), to_file='strings.txt')
Roadmap
- Better Linux support (clang+lld+lto vs gcc+gold).
- More
console
features:- Add
SplitByName()
- LikeGroupByName()
, but recursive. - A canned query, that does what ShowGlobals does (as described in Windows Binary Sizes).
- Add
- Integrate with
resource_sizes.py
so that it tracks size of major components separately: chrome vs blink vs skia vs v8. - Add dependency graph info, perhaps just on a per-file basis.
- No idea how to do this, but Windows can do it via
tools\win\linker_verbose_tracking.py
- No idea how to do this, but Windows can do it via