mirror of
https://github.com/golang/go
synced 2024-11-05 17:26:11 -07:00
6e28bf3795
Fixes #12059. Change-Id: Ib5caf8133cd3ed888f9102dfbfeca11c506f3b5b Reviewed-on: https://go-review.googlesource.com/18337 Reviewed-by: Ian Lance Taylor <iant@golang.org>
508 lines
15 KiB
HTML
508 lines
15 KiB
HTML
<!--{
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"Title": "Debugging Go Code with GDB",
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"Path": "/doc/gdb"
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}-->
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<p><i>
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This applies to the <code>gc</code> toolchain. Gccgo has native gdb support.
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Besides this overview you might want to consult the
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<a href="http://sourceware.org/gdb/current/onlinedocs/gdb/">GDB manual</a>.
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</i></p>
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<p>
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GDB does not understand Go programs well.
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The stack management, threading, and runtime contain aspects that differ
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enough from the execution model GDB expects that they can confuse
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the debugger, even when the program is compiled with gccgo.
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As a consequence, although GDB can be useful in some situations, it is
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not a reliable debugger for Go programs, particularly heavily concurrent ones.
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Moreover, it is not a priority for the Go project to address these issues, which
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are difficult.
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In short, the instructions below should be taken only as a guide to how
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to use GDB when it works, not as a guarantee of success.
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</p>
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<p>
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In time, a more Go-centric debugging architecture may be required.
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</p>
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<h2 id="Introduction">Introduction</h2>
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<p>
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When you compile and link your Go programs with the <code>gc</code> toolchain
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on Linux, Mac OS X, FreeBSD or NetBSD, the resulting binaries contain DWARFv3
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debugging information that recent versions (>7.1) of the GDB debugger can
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use to inspect a live process or a core dump.
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</p>
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<p>
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Pass the <code>'-w'</code> flag to the linker to omit the debug information
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(for example, <code>go build -ldflags "-w" prog.go</code>).
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</p>
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<p>
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The code generated by the <code>gc</code> compiler includes inlining of
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function invocations and registerization of variables. These optimizations
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can sometimes make debugging with <code>gdb</code> harder. To disable them
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when debugging, pass the flags <code>-gcflags "-N -l"</code> to the
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<a href="/cmd/go"><code>go</code></a> command used to build the code being
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debugged.
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</p>
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<h3 id="Common_Operations">Common Operations</h3>
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<ul>
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<li>
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Show file and line number for code, set breakpoints and disassemble:
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<pre>(gdb) <b>list</b>
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(gdb) <b>list <i>line</i></b>
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(gdb) <b>list <i>file.go</i>:<i>line</i></b>
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(gdb) <b>break <i>line</i></b>
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(gdb) <b>break <i>file.go</i>:<i>line</i></b>
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(gdb) <b>disas</b></pre>
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</li>
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<li>
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Show backtraces and unwind stack frames:
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<pre>(gdb) <b>bt</b>
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(gdb) <b>frame <i>n</i></b></pre>
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</li>
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<li>
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Show the name, type and location on the stack frame of local variables,
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arguments and return values:
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<pre>(gdb) <b>info locals</b>
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(gdb) <b>info args</b>
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(gdb) <b>p variable</b>
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(gdb) <b>whatis variable</b></pre>
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</li>
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<li>
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Show the name, type and location of global variables:
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<pre>(gdb) <b>info variables <i>regexp</i></b></pre>
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</li>
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</ul>
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<h3 id="Go_Extensions">Go Extensions</h3>
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<p>
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A recent extension mechanism to GDB allows it to load extension scripts for a
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given binary. The tool chain uses this to extend GDB with a handful of
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commands to inspect internals of the runtime code (such as goroutines) and to
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pretty print the built-in map, slice and channel types.
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</p>
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<ul>
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<li>
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Pretty printing a string, slice, map, channel or interface:
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<pre>(gdb) <b>p <i>var</i></b></pre>
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</li>
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<li>
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A $len() and $cap() function for strings, slices and maps:
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<pre>(gdb) <b>p $len(<i>var</i>)</b></pre>
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</li>
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<li>
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A function to cast interfaces to their dynamic types:
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<pre>(gdb) <b>p $dtype(<i>var</i>)</b>
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(gdb) <b>iface <i>var</i></b></pre>
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<p class="detail"><b>Known issue:</b> GDB can’t automatically find the dynamic
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type of an interface value if its long name differs from its short name
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(annoying when printing stacktraces, the pretty printer falls back to printing
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the short type name and a pointer).</p>
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</li>
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<li>
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Inspecting goroutines:
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<pre>(gdb) <b>info goroutines</b>
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(gdb) <b>goroutine <i>n</i> <i>cmd</i></b>
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(gdb) <b>help goroutine</b></pre>
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For example:
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<pre>(gdb) <b>goroutine 12 bt</b></pre>
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</li>
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</ul>
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<p>
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If you'd like to see how this works, or want to extend it, take a look at <a
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href="/src/runtime/runtime-gdb.py">src/runtime/runtime-gdb.py</a> in
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the Go source distribution. It depends on some special magic types
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(<code>hash<T,U></code>) and variables (<code>runtime.m</code> and
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<code>runtime.g</code>) that the linker
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(<a href="/src/cmd/link/internal/ld/dwarf.go">src/cmd/link/internal/ld/dwarf.go</a>) ensures are described in
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the DWARF code.
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</p>
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<p>
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If you're interested in what the debugging information looks like, run
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'<code>objdump -W 6.out</code>' and browse through the <code>.debug_*</code>
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sections.
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</p>
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<h3 id="Known_Issues">Known Issues</h3>
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<ol>
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<li>String pretty printing only triggers for type string, not for types derived
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from it.</li>
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<li>Type information is missing for the C parts of the runtime library.</li>
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<li>GDB does not understand Go’s name qualifications and treats
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<code>"fmt.Print"</code> as an unstructured literal with a <code>"."</code>
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that needs to be quoted. It objects even more strongly to method names of
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the form <code>pkg.(*MyType).Meth</code>.
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<li>All global variables are lumped into package <code>"main"</code>.</li>
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</ol>
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<h2 id="Tutorial">Tutorial</h2>
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<p>
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In this tutorial we will inspect the binary of the
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<a href="/pkg/regexp/">regexp</a> package's unit tests. To build the binary,
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change to <code>$GOROOT/src/regexp</code> and run <code>go test -c</code>.
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This should produce an executable file named <code>regexp.test</code>.
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</p>
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<h3 id="Getting_Started">Getting Started</h3>
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<p>
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Launch GDB, debugging <code>regexp.test</code>:
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</p>
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<pre>
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$ <b>gdb regexp.test</b>
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GNU gdb (GDB) 7.2-gg8
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Copyright (C) 2010 Free Software Foundation, Inc.
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License GPLv 3+: GNU GPL version 3 or later <http://gnu.org/licenses/gpl.html>
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Type "show copying" and "show warranty" for licensing/warranty details.
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This GDB was configured as "x86_64-linux".
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Reading symbols from /home/user/go/src/regexp/regexp.test...
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done.
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Loading Go Runtime support.
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(gdb)
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</pre>
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<p>
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The message <code>"Loading Go Runtime support"</code> means that GDB loaded the
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extension from <code>$GOROOT/src/runtime/runtime-gdb.py</code>.
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</p>
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<p>
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To help GDB find the Go runtime sources and the accompanying support script,
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pass your <code>$GOROOT</code> with the <code>'-d'</code> flag:
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</p>
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<pre>
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$ <b>gdb regexp.test -d $GOROOT</b>
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</pre>
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<p>
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If for some reason GDB still can't find that directory or that script, you can load
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it by hand by telling gdb (assuming you have the go sources in
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<code>~/go/</code>):
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</p>
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<pre>
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(gdb) <b>source ~/go/src/runtime/runtime-gdb.py</b>
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Loading Go Runtime support.
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</pre>
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<h3 id="Inspecting_the_source">Inspecting the source</h3>
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<p>
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Use the <code>"l"</code> or <code>"list"</code> command to inspect source code.
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</p>
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<pre>
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(gdb) <b>l</b>
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</pre>
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<p>
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List a specific part of the source parametrizing <code>"list"</code> with a
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function name (it must be qualified with its package name).
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</p>
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<pre>
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(gdb) <b>l main.main</b>
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</pre>
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<p>
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List a specific file and line number:
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</p>
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<pre>
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(gdb) <b>l regexp.go:1</b>
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(gdb) <i># Hit enter to repeat last command. Here, this lists next 10 lines.</i>
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</pre>
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<h3 id="Naming">Naming</h3>
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<p>
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Variable and function names must be qualified with the name of the packages
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they belong to. The <code>Compile</code> function from the <code>regexp</code>
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package is known to GDB as <code>'regexp.Compile'</code>.
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</p>
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<p>
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Methods must be qualified with the name of their receiver types. For example,
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the <code>*Regexp</code> type’s <code>String</code> method is known as
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<code>'regexp.(*Regexp).String'</code>.
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</p>
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<p>
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Variables that shadow other variables are magically suffixed with a number in the debug info.
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Variables referenced by closures will appear as pointers magically prefixed with '&'.
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</p>
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<h3 id="Setting_breakpoints">Setting breakpoints</h3>
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<p>
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Set a breakpoint at the <code>TestFind</code> function:
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</p>
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<pre>
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(gdb) <b>b 'regexp.TestFind'</b>
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Breakpoint 1 at 0x424908: file /home/user/go/src/regexp/find_test.go, line 148.
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</pre>
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<p>
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Run the program:
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</p>
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<pre>
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(gdb) <b>run</b>
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Starting program: /home/user/go/src/regexp/regexp.test
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Breakpoint 1, regexp.TestFind (t=0xf8404a89c0) at /home/user/go/src/regexp/find_test.go:148
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148 func TestFind(t *testing.T) {
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</pre>
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<p>
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Execution has paused at the breakpoint.
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See which goroutines are running, and what they're doing:
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</p>
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<pre>
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(gdb) <b>info goroutines</b>
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1 waiting runtime.gosched
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* 13 running runtime.goexit
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</pre>
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<p>
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the one marked with the <code>*</code> is the current goroutine.
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</p>
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<h3 id="Inspecting_the_stack">Inspecting the stack</h3>
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<p>
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Look at the stack trace for where we’ve paused the program:
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</p>
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<pre>
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(gdb) <b>bt</b> <i># backtrace</i>
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#0 regexp.TestFind (t=0xf8404a89c0) at /home/user/go/src/regexp/find_test.go:148
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#1 0x000000000042f60b in testing.tRunner (t=0xf8404a89c0, test=0x573720) at /home/user/go/src/testing/testing.go:156
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#2 0x000000000040df64 in runtime.initdone () at /home/user/go/src/runtime/proc.c:242
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#3 0x000000f8404a89c0 in ?? ()
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#4 0x0000000000573720 in ?? ()
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#5 0x0000000000000000 in ?? ()
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</pre>
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<p>
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The other goroutine, number 1, is stuck in <code>runtime.gosched</code>, blocked on a channel receive:
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</p>
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<pre>
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(gdb) <b>goroutine 1 bt</b>
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#0 0x000000000040facb in runtime.gosched () at /home/user/go/src/runtime/proc.c:873
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#1 0x00000000004031c9 in runtime.chanrecv (c=void, ep=void, selected=void, received=void)
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at /home/user/go/src/runtime/chan.c:342
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#2 0x0000000000403299 in runtime.chanrecv1 (t=void, c=void) at/home/user/go/src/runtime/chan.c:423
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#3 0x000000000043075b in testing.RunTests (matchString={void (struct string, struct string, bool *, error *)}
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0x7ffff7f9ef60, tests= []testing.InternalTest = {...}) at /home/user/go/src/testing/testing.go:201
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#4 0x00000000004302b1 in testing.Main (matchString={void (struct string, struct string, bool *, error *)}
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0x7ffff7f9ef80, tests= []testing.InternalTest = {...}, benchmarks= []testing.InternalBenchmark = {...})
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at /home/user/go/src/testing/testing.go:168
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#5 0x0000000000400dc1 in main.main () at /home/user/go/src/regexp/_testmain.go:98
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#6 0x00000000004022e7 in runtime.mainstart () at /home/user/go/src/runtime/amd64/asm.s:78
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#7 0x000000000040ea6f in runtime.initdone () at /home/user/go/src/runtime/proc.c:243
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#8 0x0000000000000000 in ?? ()
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</pre>
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<p>
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The stack frame shows we’re currently executing the <code>regexp.TestFind</code> function, as expected.
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</p>
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<pre>
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(gdb) <b>info frame</b>
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Stack level 0, frame at 0x7ffff7f9ff88:
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rip = 0x425530 in regexp.TestFind (/home/user/go/src/regexp/find_test.go:148);
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saved rip 0x430233
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called by frame at 0x7ffff7f9ffa8
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source language minimal.
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Arglist at 0x7ffff7f9ff78, args: t=0xf840688b60
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Locals at 0x7ffff7f9ff78, Previous frame's sp is 0x7ffff7f9ff88
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Saved registers:
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rip at 0x7ffff7f9ff80
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</pre>
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<p>
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The command <code>info locals</code> lists all variables local to the function and their values, but is a bit
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dangerous to use, since it will also try to print uninitialized variables. Uninitialized slices may cause gdb to try
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to print arbitrary large arrays.
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</p>
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<p>
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The function’s arguments:
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</p>
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<pre>
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(gdb) <b>info args</b>
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t = 0xf840688b60
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</pre>
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<p>
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When printing the argument, notice that it’s a pointer to a
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<code>Regexp</code> value. Note that GDB has incorrectly put the <code>*</code>
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on the right-hand side of the type name and made up a 'struct' keyword, in traditional C style.
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</p>
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<pre>
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(gdb) <b>p re</b>
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(gdb) p t
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$1 = (struct testing.T *) 0xf840688b60
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(gdb) p t
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$1 = (struct testing.T *) 0xf840688b60
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(gdb) p *t
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$2 = {errors = "", failed = false, ch = 0xf8406f5690}
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(gdb) p *t->ch
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$3 = struct hchan<*testing.T>
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</pre>
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<p>
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That <code>struct hchan<*testing.T></code> is the runtime-internal representation of a channel. It is currently empty, or gdb would have pretty-printed it's contents.
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</p>
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<p>
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Stepping forward:
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</p>
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<pre>
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(gdb) <b>n</b> <i># execute next line</i>
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149 for _, test := range findTests {
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(gdb) <i># enter is repeat</i>
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150 re := MustCompile(test.pat)
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(gdb) <b>p test.pat</b>
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$4 = ""
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(gdb) <b>p re</b>
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$5 = (struct regexp.Regexp *) 0xf84068d070
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(gdb) <b>p *re</b>
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$6 = {expr = "", prog = 0xf840688b80, prefix = "", prefixBytes = []uint8, prefixComplete = true,
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prefixRune = 0, cond = 0 '\000', numSubexp = 0, longest = false, mu = {state = 0, sema = 0},
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machine = []*regexp.machine}
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(gdb) <b>p *re->prog</b>
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$7 = {Inst = []regexp/syntax.Inst = {{Op = 5 '\005', Out = 0, Arg = 0, Rune = []int}, {Op =
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6 '\006', Out = 2, Arg = 0, Rune = []int}, {Op = 4 '\004', Out = 0, Arg = 0, Rune = []int}},
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Start = 1, NumCap = 2}
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</pre>
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<p>
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We can step into the <code>String</code>function call with <code>"s"</code>:
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</p>
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<pre>
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(gdb) <b>s</b>
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regexp.(*Regexp).String (re=0xf84068d070, noname=void) at /home/user/go/src/regexp/regexp.go:97
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97 func (re *Regexp) String() string {
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</pre>
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||
|
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<p>
|
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Get a stack trace to see where we are:
|
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</p>
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|
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<pre>
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(gdb) <b>bt</b>
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#0 regexp.(*Regexp).String (re=0xf84068d070, noname=void)
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at /home/user/go/src/regexp/regexp.go:97
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#1 0x0000000000425615 in regexp.TestFind (t=0xf840688b60)
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at /home/user/go/src/regexp/find_test.go:151
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#2 0x0000000000430233 in testing.tRunner (t=0xf840688b60, test=0x5747b8)
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at /home/user/go/src/testing/testing.go:156
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#3 0x000000000040ea6f in runtime.initdone () at /home/user/go/src/runtime/proc.c:243
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....
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</pre>
|
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|
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<p>
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Look at the source code:
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</p>
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<pre>
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(gdb) <b>l</b>
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92 mu sync.Mutex
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93 machine []*machine
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94 }
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95
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96 // String returns the source text used to compile the regular expression.
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97 func (re *Regexp) String() string {
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98 return re.expr
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99 }
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100
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101 // Compile parses a regular expression and returns, if successful,
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</pre>
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<h3 id="Pretty_Printing">Pretty Printing</h3>
|
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|
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<p>
|
||
GDB's pretty printing mechanism is triggered by regexp matches on type names. An example for slices:
|
||
</p>
|
||
|
||
<pre>
|
||
(gdb) <b>p utf</b>
|
||
$22 = []uint8 = {0 '\000', 0 '\000', 0 '\000', 0 '\000'}
|
||
</pre>
|
||
|
||
<p>
|
||
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):
|
||
</p>
|
||
<pre>
|
||
|
||
(gdb) <b>p slc</b>
|
||
$11 = []int = {0, 0}
|
||
(gdb) <b>p slc-></b><i><TAB></i>
|
||
array slc len
|
||
(gdb) <b>p slc->array</b>
|
||
$12 = (int *) 0xf84057af00
|
||
(gdb) <b>p slc->array[1]</b>
|
||
$13 = 0</pre>
|
||
|
||
|
||
|
||
<p>
|
||
The extension functions $len and $cap work on strings, arrays and slices:
|
||
</p>
|
||
|
||
<pre>
|
||
(gdb) <b>p $len(utf)</b>
|
||
$23 = 4
|
||
(gdb) <b>p $cap(utf)</b>
|
||
$24 = 4
|
||
</pre>
|
||
|
||
<p>
|
||
Channels and maps are 'reference' types, which gdb shows as pointers to C++-like types <code>hash<int,string>*</code>. Dereferencing will trigger prettyprinting
|
||
</p>
|
||
|
||
<p>
|
||
Interfaces are represented in the runtime as a pointer to a type descriptor and a pointer to a value. The Go GDB runtime extension decodes this and automatically triggers pretty printing for the runtime type. The extension function <code>$dtype</code> decodes the dynamic type for you (examples are taken from a breakpoint at <code>regexp.go</code> line 293.)
|
||
</p>
|
||
|
||
<pre>
|
||
(gdb) <b>p i</b>
|
||
$4 = {str = "cbb"}
|
||
(gdb) <b>whatis i</b>
|
||
type = regexp.input
|
||
(gdb) <b>p $dtype(i)</b>
|
||
$26 = (struct regexp.inputBytes *) 0xf8400b4930
|
||
(gdb) <b>iface i</b>
|
||
regexp.input: struct regexp.inputBytes *
|
||
</pre>
|