The following instructions apply to the standard toolchain
(the gc
Go compiler and tools).
Gccgo has native gdb support.
Note that
Delve is a better
alternative to GDB when debugging Go programs built with the standard
toolchain. It understands the Go runtime, data structures, and
expressions better than GDB. Delve currently supports Linux, OSX,
and Windows on amd64
.
For the most up-to-date list of supported platforms, please see
the Delve documentation.
GDB does not understand Go programs well. The stack management, threading, and runtime contain aspects that differ enough from the execution model GDB expects that they can confuse the debugger and cause incorrect results even when the program is compiled with gccgo. As a consequence, although GDB can be useful in some situations (e.g., debugging Cgo code, or debugging the runtime itself), it is not a reliable debugger for Go programs, particularly heavily concurrent ones. Moreover, it is not a priority for the Go project to address these issues, which are difficult.
In short, the instructions below should be taken only as a guide to how to use GDB when it works, not as a guarantee of success. Besides this overview you might want to consult the GDB manual.
When you compile and link your Go programs with the gc
toolchain
on Linux, macOS, FreeBSD or NetBSD, the resulting binaries contain DWARFv4
debugging information that recent versions (≥7.5) of the GDB debugger can
use to inspect a live process or a core dump.
Pass the '-w'
flag to the linker to omit the debug information
(for example, go
build
-ldflags=-w
prog.go
).
The code generated by the gc
compiler includes inlining of
function invocations and registerization of variables. These optimizations
can sometimes make debugging with gdb
harder.
If you find that you need to disable these optimizations,
build your program using go
build
-gcflags=all="-N -l"
.
If you want to use gdb to inspect a core dump, you can trigger a dump
on a program crash, on systems that permit it, by setting
GOTRACEBACK=crash
in the environment (see the
runtime package
documentation for more info).
(gdb) list (gdb) list line (gdb) list file.go:line (gdb) break line (gdb) break file.go:line (gdb) disas
(gdb) bt (gdb) frame n
(gdb) info locals (gdb) info args (gdb) p variable (gdb) whatis variable
(gdb) info variables regexp
A recent extension mechanism to GDB allows it to load extension scripts for a given binary. The toolchain uses this to extend GDB with a handful of commands to inspect internals of the runtime code (such as goroutines) and to pretty print the built-in map, slice and channel types.
(gdb) p var
(gdb) p $len(var)
(gdb) p $dtype(var) (gdb) iface var
Known issue: GDB can’t automatically find the dynamic type of an interface value if its long name differs from its short name (annoying when printing stacktraces, the pretty printer falls back to printing the short type name and a pointer).
(gdb) info goroutines (gdb) goroutine n cmd (gdb) help goroutineFor example:
(gdb) goroutine 12 bt
If you'd like to see how this works, or want to extend it, take a look at src/runtime/runtime-gdb.py in
the Go source distribution. It depends on some special magic types
(hash<T,U>
) and variables (runtime.m
and
runtime.g
) that the linker
(src/cmd/link/internal/ld/dwarf.go) ensures are described in
the DWARF code.
If you're interested in what the debugging information looks like, run
objdump
-W
a.out
and browse through the .debug_*
sections.
"fmt.Print"
as an unstructured literal with a "."
that needs to be quoted. It objects even more strongly to method names of
the form pkg.(*MyType).Meth
.
go
build -ldflags=-compressdwarf=false
.
(For convenience you can put the -ldflags
option in
the GOFLAGS
environment variable so that you don't have to specify it each time.)
In this tutorial we will inspect the binary of the
regexp package's unit tests. To build the binary,
change to $GOROOT/src/regexp
and run go
test
-c
.
This should produce an executable file named regexp.test
.
Launch GDB, debugging regexp.test
:
$ gdb regexp.test GNU gdb (GDB) 7.2-gg8 Copyright (C) 2010 Free Software Foundation, Inc. License GPLv 3+: GNU GPL version 3 or later <http://gnu.org/licenses/gpl.html> Type "show copying" and "show warranty" for licensing/warranty details. This GDB was configured as "x86_64-linux". Reading symbols from /home/user/go/src/regexp/regexp.test... done. Loading Go Runtime support. (gdb)
The message "Loading Go Runtime support" means that GDB loaded the
extension from $GOROOT/src/runtime/runtime-gdb.py
.
To help GDB find the Go runtime sources and the accompanying support script,
pass your $GOROOT
with the '-d'
flag:
$ gdb regexp.test -d $GOROOT
If for some reason GDB still can't find that directory or that script, you can load
it by hand by telling gdb (assuming you have the go sources in
~/go/
):
(gdb) source ~/go/src/runtime/runtime-gdb.py Loading Go Runtime support.
Use the "l"
or "list"
command to inspect source code.
(gdb) l
List a specific part of the source parameterizing "list"
with a
function name (it must be qualified with its package name).
(gdb) l main.main
List a specific file and line number:
(gdb) l regexp.go:1 (gdb) # Hit enter to repeat last command. Here, this lists next 10 lines.
Variable and function names must be qualified with the name of the packages
they belong to. The Compile
function from the regexp
package is known to GDB as 'regexp.Compile'
.
Methods must be qualified with the name of their receiver types. For example,
the *Regexp
type’s String
method is known as
'regexp.(*Regexp).String'
.
Variables that shadow other variables are magically suffixed with a number in the debug info. Variables referenced by closures will appear as pointers magically prefixed with '&'.
Set a breakpoint at the TestFind
function:
(gdb) b 'regexp.TestFind' Breakpoint 1 at 0x424908: file /home/user/go/src/regexp/find_test.go, line 148.
Run the program:
(gdb) run Starting program: /home/user/go/src/regexp/regexp.test Breakpoint 1, regexp.TestFind (t=0xf8404a89c0) at /home/user/go/src/regexp/find_test.go:148 148 func TestFind(t *testing.T) {
Execution has paused at the breakpoint. See which goroutines are running, and what they're doing:
(gdb) info goroutines 1 waiting runtime.gosched * 13 running runtime.goexit
the one marked with the *
is the current goroutine.
Look at the stack trace for where we’ve paused the program:
(gdb) bt # backtrace #0 regexp.TestFind (t=0xf8404a89c0) at /home/user/go/src/regexp/find_test.go:148 #1 0x000000000042f60b in testing.tRunner (t=0xf8404a89c0, test=0x573720) at /home/user/go/src/testing/testing.go:156 #2 0x000000000040df64 in runtime.initdone () at /home/user/go/src/runtime/proc.c:242 #3 0x000000f8404a89c0 in ?? () #4 0x0000000000573720 in ?? () #5 0x0000000000000000 in ?? ()
The other goroutine, number 1, is stuck in runtime.gosched
, blocked on a channel receive:
(gdb) goroutine 1 bt #0 0x000000000040facb in runtime.gosched () at /home/user/go/src/runtime/proc.c:873 #1 0x00000000004031c9 in runtime.chanrecv (c=void, ep=void, selected=void, received=void) at /home/user/go/src/runtime/chan.c:342 #2 0x0000000000403299 in runtime.chanrecv1 (t=void, c=void) at/home/user/go/src/runtime/chan.c:423 #3 0x000000000043075b in testing.RunTests (matchString={void (struct string, struct string, bool *, error *)} 0x7ffff7f9ef60, tests= []testing.InternalTest = {...}) at /home/user/go/src/testing/testing.go:201 #4 0x00000000004302b1 in testing.Main (matchString={void (struct string, struct string, bool *, error *)} 0x7ffff7f9ef80, tests= []testing.InternalTest = {...}, benchmarks= []testing.InternalBenchmark = {...}) at /home/user/go/src/testing/testing.go:168 #5 0x0000000000400dc1 in main.main () at /home/user/go/src/regexp/_testmain.go:98 #6 0x00000000004022e7 in runtime.mainstart () at /home/user/go/src/runtime/amd64/asm.s:78 #7 0x000000000040ea6f in runtime.initdone () at /home/user/go/src/runtime/proc.c:243 #8 0x0000000000000000 in ?? ()
The stack frame shows we’re currently executing the regexp.TestFind
function, as expected.
(gdb) info frame Stack level 0, frame at 0x7ffff7f9ff88: rip = 0x425530 in regexp.TestFind (/home/user/go/src/regexp/find_test.go:148); saved rip 0x430233 called by frame at 0x7ffff7f9ffa8 source language minimal. Arglist at 0x7ffff7f9ff78, args: t=0xf840688b60 Locals at 0x7ffff7f9ff78, Previous frame's sp is 0x7ffff7f9ff88 Saved registers: rip at 0x7ffff7f9ff80
The command info
locals
lists all variables local to the function and their values, but is a bit
dangerous to use, since it will also try to print uninitialized variables. Uninitialized slices may cause gdb to try
to print arbitrary large arrays.
The function’s arguments:
(gdb) info args t = 0xf840688b60
When printing the argument, notice that it’s a pointer to a
Regexp
value. Note that GDB has incorrectly put the *
on the right-hand side of the type name and made up a 'struct' keyword, in traditional C style.
(gdb) p re (gdb) p t $1 = (struct testing.T *) 0xf840688b60 (gdb) p t $1 = (struct testing.T *) 0xf840688b60 (gdb) p *t $2 = {errors = "", failed = false, ch = 0xf8406f5690} (gdb) p *t->ch $3 = struct hchan<*testing.T>
That struct
hchan<*testing.T>
is the
runtime-internal representation of a channel. It is currently empty,
or gdb would have pretty-printed its contents.
Stepping forward:
(gdb) n # execute next line 149 for _, test := range findTests { (gdb) # enter is repeat 150 re := MustCompile(test.pat) (gdb) p test.pat $4 = "" (gdb) p re $5 = (struct regexp.Regexp *) 0xf84068d070 (gdb) p *re $6 = {expr = "", prog = 0xf840688b80, prefix = "", prefixBytes = []uint8, prefixComplete = true, prefixRune = 0, cond = 0 '\000', numSubexp = 0, longest = false, mu = {state = 0, sema = 0}, machine = []*regexp.machine} (gdb) p *re->prog $7 = {Inst = []regexp/syntax.Inst = {{Op = 5 '\005', Out = 0, Arg = 0, Rune = []int}, {Op = 6 '\006', Out = 2, Arg = 0, Rune = []int}, {Op = 4 '\004', Out = 0, Arg = 0, Rune = []int}}, Start = 1, NumCap = 2}
We can step into the String
function call with "s"
:
(gdb) s regexp.(*Regexp).String (re=0xf84068d070, noname=void) at /home/user/go/src/regexp/regexp.go:97 97 func (re *Regexp) String() string {
Get a stack trace to see where we are:
(gdb) bt #0 regexp.(*Regexp).String (re=0xf84068d070, noname=void) at /home/user/go/src/regexp/regexp.go:97 #1 0x0000000000425615 in regexp.TestFind (t=0xf840688b60) at /home/user/go/src/regexp/find_test.go:151 #2 0x0000000000430233 in testing.tRunner (t=0xf840688b60, test=0x5747b8) at /home/user/go/src/testing/testing.go:156 #3 0x000000000040ea6f in runtime.initdone () at /home/user/go/src/runtime/proc.c:243 ....
Look at the source code:
(gdb) l 92 mu sync.Mutex 93 machine []*machine 94 } 95 96 // String returns the source text used to compile the regular expression. 97 func (re *Regexp) String() string { 98 return re.expr 99 } 100 101 // Compile parses a regular expression and returns, if successful,
GDB's pretty printing mechanism is triggered by regexp matches on type names. An example for slices:
(gdb) p utf $22 = []uint8 = {0 '\000', 0 '\000', 0 '\000', 0 '\000'}
Since slices, arrays and strings are not C pointers, GDB can't interpret the subscripting operation for you, but you can look inside the runtime representation to do that (tab completion helps here):
(gdb) p slc $11 = []int = {0, 0} (gdb) p slc-><TAB> array slc len (gdb) p slc->array $12 = (int *) 0xf84057af00 (gdb) p slc->array[1] $13 = 0
The extension functions $len and $cap work on strings, arrays and slices:
(gdb) p $len(utf) $23 = 4 (gdb) p $cap(utf) $24 = 4
Channels and maps are 'reference' types, which gdb shows as pointers to C++-like types hash<int,string>*
. Dereferencing will trigger prettyprinting
Interfaces are represented in the runtime as a pointer to a type descriptor and a pointer to a value. The Go GDB runtime extension decodes this and automatically triggers pretty printing for the runtime type. The extension function $dtype
decodes the dynamic type for you (examples are taken from a breakpoint at regexp.go
line 293.)
(gdb) p i $4 = {str = "cbb"} (gdb) whatis i type = regexp.input (gdb) p $dtype(i) $26 = (struct regexp.inputBytes *) 0xf8400b4930 (gdb) iface i regexp.input: struct regexp.inputBytes *