Using and interpreting DWARF stack traces

The Dart VM AOT compiler can encode code source mapping information as DWARF debugging information instead of using in-snapshot CodeSourceMap objects. Unlike CodeSourceMap objects, this DWARF information can then be stripped from snapshots provided to users, which lowers the binary size.

Turning on DWARF encoding of code source mapping information

To output code source mapping information as DWARF debugging information, use the --dwarf-stack-traces flag. By default, generated assembly or ELF snapshots include the DWARF information directly.

Note: DWARF debugging information is not obfuscated when using the --obfuscate flag. To avoid unobfuscated information leaking to users when using --dwarf-stack-traces, use the --strip option when creating ELF snapshots.

To output DWARF debugging information to a separate file that can be saved as an artifact for later debugging, use the --save-debugging-info=<...> flag. The generated file is not guaranteed to be any specific format and may change in the future. See Translating DWARF stack traces for how to use this file.

Differences when using DWARF code source mapping information

When using DWARF code source mapping information, stack traces only include PC address information for frames. This means that a developer will need the generated DWARF information to get function, file, and line number information for each frame.

Take the following example program, saved as throws.dart in the root of a Dart SDK checkout:

@pragma('vm:prefer-inline')
void bar() => throw null;

@pragma('vm:never-inline')
void foo() => bar();

void main() => foo();

Below is the result of running the file both without and with --dwarf-stack-traces in a 64-bit Linux development environment:

$ python tools/build.py -a x64 -m release runtime_kernel runtime_precompiled

$ pkg/vm/tool/gen_kernel --platform out/ReleaseX64/vm_platform_strong.dill -o throws.dill throws.dart

$ out/ReleaseX64/gen_snapshot --snapshot_kind=app-aot-elf --elf=snapshot.so throws.dill

# Here, we save the debugging information to a separate file debug.data as well
# as including it in the generated ELF snapshot for future examples.
$ out/ReleaseX64/gen_snapshot --dwarf-stack-traces --save-debugging-info=debug.data --snapshot_kind=app-aot-elf --elf=dwarf_snapshot.so throws.dill

$ out/ReleaseX64/dart_precompiled_runtime snapshot.so
Unhandled exception:
Throw of null.
#0      bar (file:///.../sdk/throws.dart:2)
#1      foo (file:///.../sdk/throws.dart:5)
#2      main (file:///.../sdk/throws.dart:7)
#3      _startIsolate.<anonymous closure> (dart:isolate-patch/isolate_patch.dart:307)
#4      _RawReceivePortImpl._handleMessage (dart:isolate-patch/isolate_patch.dart:174)

$ out/ReleaseX64/dart_precompiled_runtime dwarf_snapshot.so
Unhandled exception:
Throw of null.
Warning: This VM has been configured to produce stack traces that violate the Dart standard.
*** *** *** *** *** *** *** *** *** *** *** *** *** *** *** ***
pid: 148677, tid: 139648739401792, name Dart_Initialize
isolate_instructions: 7f028072e000 vm_instructions: 0
    #00 abs 00007f028098381e virt 000000000025c81e /.../sdk/snapshot.so
    #01 abs 00007f0280983742 virt 000000000025c742 /.../sdk/snapshot.so
    #02 abs 00007f02809837d5 virt 000000000025c7d5 /.../sdk/snapshot.so
    #03 abs 00007f028099d8af virt 00000000002768af /.../sdk/snapshot.so
    #04 abs 00007f02808f42ff virt 00000000001cd2ff /.../sdk/snapshot.so
    #05 abs 00007f028099d7a2 virt 00000000002767a2 /.../sdk/snapshot.so
    #06 abs 00007f028086df98 virt 0000000000146f98 /.../sdk/snapshot.so

For a DWARF-based stack trace, we are guaranteed to have an absolute PC address for each frame (the hexadecimal number following abs) as well as the absolute addresses for the start of the isolate instructions and the VM instructions (the line starting with isolate_instructions). This information is used by our tool and libraries for converting DWARF stack traces, described later.

If we are running from a snapshot which is a native format for dynamic libraries (e.g., ELF on Linux or Mach-O on Mac OS X), then we will also have a virtual PC address for each frame (the hexadecimal number following virt). If we have appropriate DWARF information for the snapshot (e.g., part of the unstripped ELF snapshot on Linux, or a separately generated .DSYM package when compiling the generated assembly on Mac OS X), we can use the virtual address along with the DWARF information to get back function, file, and line number information using native tools:

# Virtual address from frame #00
$ addr2line -f -i -e dwarf_snapshot.so 000000000025c81e
bar
file:///.../sdk/throws.dart:2
foo
file:///.../sdk/throws.dart:5

# Virtual address from frame #01
$ addr2line -f -i -e dwarf_snapshot.so 000000000025c742
Precompiled____main_6919
file:///.../dart/sdk/throws.dart:7

However, as seen here, the information may not be exactly as expected from the non-DWARF stack trace. In addition, the DWARF stack trace may include frames that are internal to the Dart VM and would not normally be provided in non-DWARF stack traces. Note that there are seven frames in the DWARF stack trace above, but only 5 in the non-DWARF stack trace. Frame #02 happens to correspond to one of these elided frames:

# Virtual address from frame #02
$ addr2line -f -i -e dwarf_snapshot.so 000000000025c7d5
Precompiled____main_main_6920
file:///.../sdk/throws.dart:?

Translating DWARF stack traces

To ease translation of DWARF stack traces, we provide a platform-independent tool and libraries. They can translate DWARF stack traces using the DWARF debugging information contained in unstripped ELF snapshots or saved separately using --save-debugging-info=<...>. For most uses, the tool should suffice, but the libraries it uses are also available for integration into Dart-based workflows.

Using the stack trace converter tool

A simple way to translate DWARF stack traces is to use the tool decode from the package native_stack_traces. The tool has one required argument -e, which takes the name of the file containing DWARF debugging information as an input. This can either be an unstripped ELF snapshot or a file generated by --save-debugging-info=<...>.

Using the earlier example, we can run the snapshot and convert any generated stack traces as follows:

# Using the unstripped ELF snapshot and piping all output to the tool's stdin.
$ out/ReleaseX64/dart_precompiled_runtime dwarf_snapshot.so |& out/ReleaseX64/dart pkg/native_stack_traces/bin/decode.dart -e dwarf_snapshot.so
Unhandled exception:
Throw of null.
Warning: This VM has been configured to produce stack traces that violate the Dart standard.
*** *** *** *** *** *** *** *** *** *** *** *** *** *** *** ***
pid: 158029, tid: 140495595888704, name Dart_Initialize
isolate_instructions: 7fc7ad076000 vm_instructions: 0
#0	bar (file:///.../sdk/throws.dart:2)
#1	foo (file:///.../sdk/throws.dart:5)
#2	main (file:///.../sdk/throws.dart:7)
#3	_startIsolate.<anonymous closure> (dart:isolate-patch/isolate_patch.dart:307)
#4	_RawReceivePortImpl._handleMessage (dart:isolate-patch/isolate_patch.dart:174)

# Using the separately saved debugging information and piping all output to the tool's stdin.
$ out/ReleaseX64/dart_precompiled_runtime dwarf_snapshot.so |& out/ReleaseX64/dart pkg/native_stack_traces/bin/decode.dart -e debug.data
Unhandled exception:
Throw of null.
Warning: This VM has been configured to produce stack traces that violate the Dart standard.
*** *** *** *** *** *** *** *** *** *** *** *** *** *** *** ***
pid: 158242, tid: 139697980215360, name Dart_Initialize
isolate_instructions: 7f0df76e1000 vm_instructions: 0
#0	bar (file:///.../sdk/throws.dart:2)
#1	foo (file:///.../sdk/throws.dart:5)
#2	main (file:///.../sdk/throws.dart:7)
#3	_startIsolate.<anonymous closure> (dart:isolate-patch/isolate_patch.dart:307)
#4	_RawReceivePortImpl._handleMessage (dart:isolate-patch/isolate_patch.dart:174)

# Saving all output to the file "output.txt".
$ out/ReleaseX64/dart_precompiled_runtime dwarf_snapshot.so >output.txt 2>&1

# Reading the input to convert from the file "output.txt" instead of stdin.
$ out/ReleaseX64/dart pkg/native_stack_traces/bin/decode.dart -e debug.data -i output.txt
Unhandled exception:
Throw of null.
Warning: This VM has been configured to produce stack traces that violate the Dart standard.
*** *** *** *** *** *** *** *** *** *** *** *** *** *** *** ***
pid: 159139, tid: 139991440654400, name Dart_Initialize
isolate_instructions: 7f524b090000 vm_instructions: 0
#0	bar (file:///.../sdk/throws.dart:2)
#1	foo (file:///.../sdk/throws.dart:5)
#2	main (file:///.../sdk/throws.dart:7)
#3	_startIsolate.<anonymous closure> (dart:isolate-patch/isolate_patch.dart:307)
#4	_RawReceivePortImpl._handleMessage (dart:isolate-patch/isolate_patch.dart:174)

# Output the converted input to the file "converted.txt" instead of stdout.
$ out/ReleaseX64/dart pkg/native_stack_traces/bin/decode.dart -e debug.data -i output.txt -o converted.txt

$ cat converted.txt
Unhandled exception:
Throw of null.
Warning: This VM has been configured to produce stack traces that violate the Dart standard.
*** *** *** *** *** *** *** *** *** *** *** *** *** *** *** ***
pid: 159139, tid: 139991440654400, name Dart_Initialize
isolate_instructions: 7f524b090000 vm_instructions: 0
#0	bar (file:///.../sdk/throws.dart:2)
#1	foo (file:///.../sdk/throws.dart:5)
#2	main (file:///.../sdk/throws.dart:7)
#3	_startIsolate.<anonymous closure> (dart:isolate-patch/isolate_patch.dart:307)
#4	_RawReceivePortImpl._handleMessage (dart:isolate-patch/isolate_patch.dart:174)

Note: As seen here, only lines that contain stack trace frames are converted. In particular, we do not strip the extra stack trace header lines that are only part of DWARF-based stack traces.

Using the stack trace converter libraries

This section describes two different libraries used to retrieve and convert information associated with DWARF-based stack traces:

  • package:vm/dwarf/dwarf.dart, for ‘Dwarf’ and ‘CallInfo’ objects
  • package:vm/dwarf/convert.dart, for PCOffset objects and various operations on stack traces

DWARF debugging information

A Dwarf object represents the DWARF debugging information from either unstripped ELF snapshots or a file generated by --save-debugging-info=<...>.

The Dwarf.fromFile factory takes a filename and returns a ‘Dwarf’ object, if the given file exists and is a recognized format that contains DWARF information.

Call site information

A CallInfo object represents a call site in the code corresponding to a particular virtual address and contains the function name, file name, and line number for the call site and whether the code for the call site has been inlined at this use.

To look up the call information associated with a particular virtual address, use Dwarf::callInfo. If the virtual address is outside the range of those generated by the DWARF line number program(s), then it returns null, otherwise it returns an iterable of CallInfo objects. If the optional includeInternalFrames argument is false (the default), then the iterable can be empty if the virtual address points to code that does not correspond to user or library code, like generated function prologues.

Converting stack traces

To convert a stream of lines that may include DWARF stack traces, use the stack transformer DwarfStackTraceDecoder. Its constructor takes a Dwarf object, and the transformer, like decode.dart from the package native_stack_traces, only changes lines that correspond to stack trace frames.

Note: The stack transformer assumes that lines are not combined or broken across Strings in the input stream. If this is not already guaranteed, transform the stream with LineSplitter from dart:convert prior to transforming it with a DwarfStackTraceDecoder.

Extracting information from stack traces

A PCOffset object represents the PC address information extracted from a DWARF-based stack trace frame. It contains whether the PC address comes from the VM or isolate instructions section, and the offset of the PC address in that section.

The PCOffset::virtualAddress method takes a Dwarf object and returns a compatible virtual address for use with methods on that Dwarf object.

The function collectPCOffsets extracts PCOffsets for the frames of a stack trace.

Note: Since the absolute addresses of the VM and isolate instruction sections are part of the stack frame header, collectPCOffsets can only extract information from complete stack traces.