Merging r155895:

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r155895 | eliben | 2012-04-30 23:15:40 -0700 (Mon, 30 Apr 2012) | 4 lines

Removed examples of stack frame inspection which no longer work for old JIT.
Added an example of MCJIT-based debugging.


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git-svn-id: https://llvm.org/svn/llvm-project/llvm/branches/release_31@155901 91177308-0d34-0410-b5e6-96231b3b80d8

1 files changed, 132 insertions, 101 deletions

diff --git a/docs/DebuggingJITedCode.html b/docs/DebuggingJITedCode.html
index 2ed3eb1d82..73161b630a 100644
--- a/docs/DebuggingJITedCode.html
+++ b/docs/DebuggingJITedCode.html
@@ -8,136 +8,166 @@
 </head>
 <body>
 
-<h1>Debugging JITed Code With GDB</h1>
+<h1>Debugging JIT-ed Code With GDB</h1>
 <ol>
-  <li><a href="#example">Example usage</a></li>
   <li><a href="#background">Background</a></li>
+  <li><a href="#gdbversion">GDB Version</a></li>
+  <li><a href="#mcjitdebug">Debugging MCJIT-ed code</a></li>
+  <ul>
+    <li><a href="#mcjitdebug_example">Example</a></li>
+  </ul>
 </ol>
-<div class="doc_author">Written by Reid Kleckner</div>
+<div class="doc_author">Written by Reid Kleckner and Eli Bendersky</div>
 
 <!--=========================================================================-->
-<h2><a name="example">Example usage</a></h2>
+<h2><a name="background">Background</a></h2>
 <!--=========================================================================-->
 <div>
 
-<p>In order to debug code JITed by LLVM, you need GDB 7.0 or newer, which is
+<p>Without special runtime support, debugging dynamically generated code with
+GDB (as well as most debuggers) can be quite painful.  Debuggers generally read
+debug information from the object file of the code, but for JITed code, there is
+no such file to look for.
+</p>
+
+<p>In order to communicate the necessary debug info to GDB, an interface for
+registering JITed code with debuggers has been designed and implemented for
+GDB and LLVM MCJIT.  At a high level, whenever MCJIT generates new machine code,
+it does so in an in-memory object file that contains the debug information in
+DWARF format.  MCJIT then adds this in-memory object file to a global list of
+dynamically generated object files and calls a special function
+(<tt>__jit_debug_register_code</tt>) marked noinline that GDB knows about.  When
+GDB attaches to a process, it puts a breakpoint in this function and loads all
+of the object files in the global list.  When MCJIT calls the registration
+function, GDB catches the breakpoint signal, loads the new object file from
+the inferior's memory, and resumes the execution.  In this way, GDB can get the
+necessary debug information.
+</p>
+</div>
+
+<!--=========================================================================-->
+<h2><a name="gdbversion">GDB Version</a></h2>
+<!--=========================================================================-->
+
+<p>In order to debug code JIT-ed by LLVM, you need GDB 7.0 or newer, which is
 available on most modern distributions of Linux.  The version of GDB that Apple
 ships with XCode has been frozen at 6.3 for a while.  LLDB may be a better
-option for debugging JITed code on Mac OS X.
+option for debugging JIT-ed code on Mac OS X.
 </p>
 
-<p>Consider debugging the following code compiled with clang and run through
-lli:
-</p>
 
-<pre class="doc_code">
-#include &lt;stdio.h&gt;
+<!--=========================================================================-->
+<h2><a name="mcjitdebug">Debugging MCJIT-ed code</a></h2>
+<!--=========================================================================-->
+<div>
+
+<p>The emerging MCJIT component of LLVM allows full debugging of JIT-ed code with
+GDB.  This is due to MCJIT's ability to use the MC emitter to provide full
+DWARF debugging information to GDB.</p>
 
-void foo() {
-    printf("%d\n", *(int*)NULL);  // Crash here
-}
+<p>Note that lli has to be passed the <tt>-use-mcjit</tt> flag to JIT the code
+with MCJIT instead of the old JIT.</p>
 
-void bar() {
-    foo();
-}
+<h3><a name="mcjitdebug_example">Example</a></h3>
 
-void baz() {
-    bar();
-}
+<div>
+
+<p>Consider the following C code (with line numbers added to make the example
+easier to follow):</p>
 
-int main(int argc, char **argv) {
-    baz();
-}
+<pre class="doc_code">
+1   int compute_factorial(int n)
+2   {
+3       if (n <= 1)
+4           return 1;
+5
+6       int f = n;
+7       while (--n > 1) 
+8           f *= n;
+9       return f;
+10  }
+11
+12
+13  int main(int argc, char** argv)
+14  {
+15      if (argc < 2)
+16          return -1;
+17      char firstletter = argv[1][0];
+18      int result = compute_factorial(firstletter - '0');
+19  
+20      // Returned result is clipped at 255...
+21      return result;
+22  }
 </pre>
 
-<p>Here are the commands to run that application under GDB and print the stack
-trace at the crash:
+<p>Here is a sample command line session that shows how to build and run this
+code via lli inside GDB:
 </p>
 
 <pre class="doc_code">
-# Compile foo.c to bitcode.  You can use either clang or llvm-gcc with this
-# command line.  Both require -fexceptions, or the calls are all marked
-# 'nounwind' which disables DWARF exception handling info.  Custom frontends
-# should avoid adding this attribute to JITed code, since it interferes with
-# DWARF CFA generation at the moment.
-$ clang foo.c -fexceptions -emit-llvm -c -o foo.bc
-
-# Run foo.bc under lli with -jit-emit-debug.  If you built lli in debug mode,
-# -jit-emit-debug defaults to true.
-$ $GDB_INSTALL/gdb --args lli -jit-emit-debug foo.bc
-...
-
-# Run the code.
-(gdb) run
-Starting program: /tmp/gdb/lli -jit-emit-debug foo.bc
+$ $BINPATH/clang -cc1 -O0 -g -emit-llvm showdebug.c
+$ gdb --quiet --args $BINPATH/lli -use-mcjit showdebug.ll 5
+Reading symbols from $BINPATH/lli...done.
+(gdb) b showdebug.c:6
+No source file named showdebug.c.
+Make breakpoint pending on future shared library load? (y or [n]) y
+Breakpoint 1 (showdebug.c:6) pending.
+(gdb) r
+Starting program: $BINPATH/lli -use-mcjit showdebug.ll 5
 [Thread debugging using libthread_db enabled]
 
-Program received signal SIGSEGV, Segmentation fault.
-0x00007ffff7f55164 in foo ()
-
-# Print the backtrace, this time with symbols instead of ??.
+Breakpoint 1, compute_factorial (n=5) at showdebug.c:6
+6	    int f = n;
+(gdb) p n
+$1 = 5
+(gdb) p f
+$2 = 0
+(gdb) n
+7	    while (--n > 1) 
+(gdb) p f
+$3 = 5
+(gdb) b showdebug.c:9
+Breakpoint 2 at 0x7ffff7ed404c: file showdebug.c, line 9.
+(gdb) c
+Continuing.
+
+Breakpoint 2, compute_factorial (n=1) at showdebug.c:9
+9	    return f;
+(gdb) p f
+$4 = 120
 (gdb) bt
-#0  0x00007ffff7f55164 in foo ()
-#1  0x00007ffff7f550f9 in bar ()
-#2  0x00007ffff7f55099 in baz ()
-#3  0x00007ffff7f5502a in main ()
-#4  0x00000000007c0225 in llvm::JIT::runFunction(llvm::Function*,
-    std::vector&lt;llvm::GenericValue,
-    std::allocator&lt;llvm::GenericValue&gt; &gt; const&amp;) ()
-#5  0x00000000007d6d98 in
-    llvm::ExecutionEngine::runFunctionAsMain(llvm::Function*,
-    std::vector&lt;std::string,
-    std::allocator&lt;std::string&gt; &gt; const&amp;, char const* const*) ()
-#6  0x00000000004dab76 in main ()
+#0  compute_factorial (n=1) at showdebug.c:9
+#1  0x00007ffff7ed40a9 in main (argc=2, argv=0x16677e0) at showdebug.c:18
+#2  0x3500000001652748 in ?? ()
+#3  0x00000000016677e0 in ?? ()
+#4  0x0000000000000002 in ?? ()
+#5  0x0000000000d953b3 in llvm::MCJIT::runFunction (this=0x16151f0, F=0x1603020, ArgValues=...) at /home/ebenders_test/llvm_svn_rw/lib/ExecutionEngine/MCJIT/MCJIT.cpp:161
+#6  0x0000000000dc8872 in llvm::ExecutionEngine::runFunctionAsMain (this=0x16151f0, Fn=0x1603020, argv=..., envp=0x7fffffffe040)
+    at /home/ebenders_test/llvm_svn_rw/lib/ExecutionEngine/ExecutionEngine.cpp:397
+#7  0x000000000059c583 in main (argc=4, argv=0x7fffffffe018, envp=0x7fffffffe040) at /home/ebenders_test/llvm_svn_rw/tools/lli/lli.cpp:324
+(gdb) finish
+Run till exit from #0  compute_factorial (n=1) at showdebug.c:9
+0x00007ffff7ed40a9 in main (argc=2, argv=0x16677e0) at showdebug.c:18
+18	    int result = compute_factorial(firstletter - '0');
+Value returned is $5 = 120
+(gdb) p result
+$6 = 23406408
+(gdb) n
+21	    return result;
+(gdb) p result
+$7 = 120
+(gdb) c
+Continuing.
+
+Program exited with code 0170.
+(gdb) 
+
 </pre>
 
-<p>As you can see, GDB can correctly unwind the stack and has the appropriate
-function names.
-</p>
 </div>
-
-<!--=========================================================================-->
-<h2><a name="background">Background</a></h2>
-<!--=========================================================================-->
-<div>
-
-<p>Without special runtime support, debugging dynamically generated code with
-GDB (as well as most debuggers) can be quite painful.  Debuggers generally read
-debug information from the object file of the code, but for JITed code, there is
-no such file to look for.
-</p>
-
-<p>Depending on the architecture, this can impact the debugging experience in
-different ways.  For example, on most 32-bit x86 architectures, you can simply
-compile with -fno-omit-frame-pointer for GCC and -disable-fp-elim for LLVM.
-When GDB creates a backtrace, it can properly unwind the stack, but the stack
-frames owned by JITed code have ??'s instead of the appropriate symbol name.
-However, on Linux x86_64 in particular, GDB relies on the DWARF call frame
-address (CFA) debug information to unwind the stack, so even if you compile
-your program to leave the frame pointer untouched, GDB will usually be unable
-to unwind the stack past any JITed code stack frames.
-</p>
-
-<p>In order to communicate the necessary debug info to GDB, an interface for
-registering JITed code with debuggers has been designed and implemented for
-GDB and LLVM.  At a high level, whenever LLVM generates new machine code, it
-also generates an object file in memory containing the debug information.  LLVM
-then adds the object file to the global list of object files and calls a special
-function (__jit_debug_register_code) marked noinline that GDB knows about.  When
-GDB attaches to a process, it puts a breakpoint in this function and loads all
-of the object files in the global list.  When LLVM calls the registration
-function, GDB catches the breakpoint signal, loads the new object file from
-LLVM's memory, and resumes the execution.  In this way, GDB can get the
-necessary debug information.
-</p>
-
-<p>At the time of this writing, LLVM only supports architectures that use ELF
-object files and it only generates symbols and DWARF CFA information.  However,
-it would be easy to add more information to the object file, so we don't need to
-coordinate with GDB to get better debug information.
-</p>
 </div>
 
+
 <!-- *********************************************************************** -->
 <hr>
 <address>
@@ -145,7 +175,8 @@ coordinate with GDB to get better debug information.
   src="http://jigsaw.w3.org/css-validator/images/vcss-blue" alt="Valid CSS"></a>
   <a href="http://validator.w3.org/check/referer"><img
   src="http://www.w3.org/Icons/valid-html401-blue" alt="Valid HTML 4.01"></a>
-  <a href="mailto:reid.kleckner@gmail.com">Reid Kleckner</a><br>
+  <a href="mailto:reid.kleckner@gmail.com">Reid Kleckner</a>,
+  <a href="mailto:eliben@gmail.com">Eli Bendersky</a><br>
   <a href="http://llvm.org/">The LLVM Compiler Infrastructure</a><br>
   Last modified: $Date$
 </address>