docs/lldb-for-gdb-users.txt - fp2-dev/platform/external/lldb - Gitiles

 Here's a short precis of how to run lldb if you are familiar with the
 gdb command set:


 1) LLDB Command Structure:

 First some details on lldb command structure to help orient you...

 Unlike gdb's command set, which is rather free-form, we tried to make
 the lldb command syntax fairly structured.  The commands are all of the
 form

 <noun> <verb> [-options [option-value]] [argument [argument...]]

 The command line parsing is done before command execution, so it is
 uniform across all the commands.  The command syntax is very simple,
 basically arguments, options and option values are all white-space
 separated.  If you need to put a backslash or double-quote character
 in an argument you back-slash it in the argument.  That makes the
 command syntax more regular, but it also means you may have to
 quote some arguments in lldb that you wouldn't in gdb.

 Options can be placed anywhere on the command line, but if the arguments
 begin with a "-" then you have to tell lldb that you're done with options
 using the "--" option.  So for instance, the "process launch" command takes
 the "-s" option to mean "stop the process at the first instruction".  It's
 arguments are the arguments you are passing to the program.  So if you wanted
 to pass an argument that contained a "-" you would have to do:

 (lldb) process launch -- -program_arg value

 We also tried to reduce the number of special purpose argument
 parsers, which sometimes forces the user to be a little more explicit
 about stating their intentions.  The first instance you'll note of
 this is the breakpoint command.  In gdb, to set a breakpoint, you
 would just say:

 (gdb) break foo.c:12

 or

 (gdb) break foo

 if foo is a function.  As time went on, the parser that tells foo.c:12
 from foo from foo.c::foo (which means the function foo in the file
 foo.c) got more and more complex and bizarre, and especially in C++
 there are times where there's really no way to specify the function
 you want to break on.  The lldb commands are more verbose but also precise.
 So you say:

 (lldb) breakpoint set -f foo.c -l 12

 to set a file & line breakpoint.  To set a breakpoint on a function
 by name, you do:

 (lldb) breakpoint set -n foo

 This can allow us to be more expressive, so you can say:

 (lldb) breakpoint set -M foo

 to break on all C++ methods named foo, or:

 (lldb) breakpoint set -S alignLeftEdges:

 to set a breakpoint on all ObjC selectors called alignLeftEdges:.  It
 also makes it easy to compose specifications, like:

 (lldb) breakpoint set -s foo.dylib -n foo

 for all functions called foo in the shared library foo.dylib.  Suggestions
 on more interesting primitives of this sort are also very welcome.

 So for instance:

 (lldb) breakpoint set -n "-[SKTGraphicView alignLeftEdges:]"

 Just like gdb, the lldb command interpreter does a shortest unique
 string match on command names, so the previous command can also be
 typed:

 (lldb) b s -n "-[SKTGraphicView alignLeftEdges:]"

 lldb also supports command completion for source file names, symbol
 names, file names, etc. Completion is initiated by a hitting a <TAB>.
 Individual options in a command can have different completers, so for
 instance the -f option in "breakpoint" completes to source files, the
 -s option to currently loaded shared libraries, etc...  We can even do
 things like if you specify -s, and are completing on -f, we will only
 list source files in the shared library specified by -s...

 The individual commands are pretty extensively documented, using
 the "help" command.  And there is an "apropos" command that will
 search the help for a particular word and dump a summary help string
 for each matching command.

 Finally, there is a mechanism to construct aliases for commonly used
 commands.  So for instance if you get annoyed typing

 (lldb) b s -f foo.c -l 12

 you can do:

 (lldb) command alias bfl breakpoint set -f %1 -l %2
 (lldb) bfl foo.c 12

 We have added a few aliases for commonly used commands (e.g. "step",
 "next" and "continue") but we haven't tried to be exhaustive because
 in our experience it is more convenient to make the basic commands
 unique down to a letter or two, and then learn these sequences than
 fill the namespace with lots of aliases, and then have to type them
 all the way out.

 However, users are free to customize lldb's command set however they
 like, and since lldb reads the file ~/.lldbinit at startup, you can
 store all your aliases there and they will be generally available to
 you.  Your aliases are also documented in the help command so you can
 remind yourself of what you've set up.

 lldb also has a built-in Python interpreter, which is accessible by
 the "script" command.  All the functionality of the debugger is
 available as classes in the Python interpreter, so the more complex
 commands that in gdb you would introduce with the "define" command can
 be done by writing Python functions using the lldb-Python library,
 then loading the scripts into your running session and accessing them
 with the "script" command.


 2) A typical session:


 a) Setting the program to debug:


 As with gdb, you can start lldb and specify the file you wish to debug
 on the command line:

 $ lldb /Projects/Sketch/build/Debug/Sketch.app
 Current executable set to '/Projects/Sketch/build/Debug/Sketch.app' (x86_64).

 or you can specify it after the fact with the "file" command:

 (lldb) file /Projects/Sketch/build/Debug/Sketch.app
 Current executable set to '/Projects/Sketch/build/Debug/Sketch.app' (x86_64).


 b) Setting breakpoints:


 We've discussed how to set breakpoints above.  You can use "help break set"
 to see all the options for breakpoint setting.  For instance, we might do:

 (lldb) b s -S alignLeftEdges:
 Breakpoint created: 1: name = 'alignLeftEdges:', locations = 1, resolved = 1

 You can find out about the breakpoints you've set with:

 (lldb) break list
 Current breakpoints:
 1: name = 'alignLeftEdges:', locations = 1, resolved = 1
   1.1: where = Sketch`-[SKTGraphicView alignLeftEdges:] + 33 at /Projects/Sketch/SKTGraphicView.m:1405, address = 0x0000000100010d5b, resolved, hit count = 0

 Note that each "logical" breakpoint can have multiple "locations".
 The logical breakpoint has an integer id, and it's locations have an
 id within their parent breakpoint (the two are joined by a ".",
 e.g. 1.1 in the example above.)

 Also the breakpoints remain "live" so that if another shared library
 were to be loaded that had another implementation of the
 "alignLeftEdges:" selector, the new location would be added to
 breakpoint 1 (e.g. a "1.2" breakpoint would be set on the newly loaded
 selector).

 The other piece of information in the breakpoint listing is whether the
 breakpoint location was "resolved" or not.  A location gets resolved when
 the file address it corresponds to gets loaded into the program you are
 debugging.  For instance if you set a breakpoint in a shared library that
 then gets unloaded, that breakpoint location will remain, but it will no
 longer be "resolved".

 One other thing to note for gdb users is that lldb acts like gdb with:

 (gdb) set breakpoint pending on

 That is, lldb should always make a breakpoint from your specification, even
 if it couldn't find any locations that match the specification.  You can tell
 whether the expression was resolved or not by checking the locations field
 in "breakpoint list", and we report the breakpoint as "pending" when you
 set it so you can tell you've made a typo more easily, if that was indeed
 the reason no locations were found:

 (lldb) b s -f no_such_file.c -l 10000000
 Breakpoint created: 1: file ='no_such_file.c', line = 10000000, locations = 0 (pending)

 You can delete, disable, set conditions and ignore counts either on all the
 locations generated by your logical breakpoint, or on particular locations
 your specification resolved to.  For instance if we wanted to add a command
 to print a backtrace when we hit this breakpoint we could do:

 (lldb) b command add -c 1.1
 Enter your debugger command(s).  Type 'DONE' to end.
 > bt
 > DONE

 The "-c" option specifies that the breakpoint command is a set of lldb
 commmand interpreter commands.  Use "-s" if you want to implement your
 breakpoint command using the Python interface instead.


 c) Running the program:

 Then you can either launch the process with the command:

 (lldb) process launch

 or its alias:

 (lldb) r

 Or you can attach to a process by name with:

 (lldb) process attach -n Sketch

 the "attach by name"  also supports the "-w" option which waits for the
 next process of that name to show up, and attaches to that.  You can also
 attach by PID:

 (lldb) process attach -p 12345
 Process 46915 Attaching
 (lldb) Process 46915 Stopped
 1 of 3 threads stopped with reasons:
 * thread #1: tid = 0x2c03, 0x00007fff85cac76a, where = libSystem.B.dylib`__getdirentries64 + 10, stop reason = signal = SIGSTOP, queue = com.apple.main-thread

 Note that we tell you that "1 of 3 threads stopped with reasons" and
 then list those threads.  In a multi-threaded environment it is very
 common for more than one thread to hit your breakpoint(s) before the
 kernel actually returns control to the debugger.  In that case, you
 will see all the threads that stopped for some interesting reason
 listed in the stop message.


 d) Controlling execution:


 After launching, we can continue until we hit our breakpoint.  The primitive
 commands for process control all exist under the "thread" command:

 (lldb) thread continue
 Resuming thread 0x2c03 in process 46915
 Resuming process 46915
 (lldb)

 At present you can only operate on one thread at a time, but the
 design will ultimately support saying "step over the function in
 Thread 1, and step into the function in Thread 2, and continue Thread
 3" etc.  When we eventually support keeping some threads running while
 others are stopped this will be particularly important.  For
 convenience, however, all the stepping commands have easy aliases.
 So "thread continue" is just "c", etc.

 The other program stepping commands are pretty much the same as in gdb.
 You've got:

   1. (lldb) thread step-in
      The same as gdb's "step" -- there is also the alias "s" in lldb

   2. (lldb) thread step-over
      The same as gdb's "next" -- there is also the alias "n" in lldb

   3. (lldb) thread step-out
      The same as gdb's "finish" -- there is also the alias "f" in lldb

 And the "by instruction" versions:

 (lldb) thread step-inst
 (lldb) thread step-over-inst

 Finally, there's:

 (lldb) thread until 100

 which runs the thread in the current frame till it reaches line 100 in
 this frame or stops if it leaves the current frame.  This is a pretty
 close equivalent to gdb's "until" command.


 One thing here that might be a little disconcerting to gdb users here is that
 when you resume process execution, you immediately get a prompt back.  That's
 because the lldb interpreter remains live when you are running the target.
 This allows you to set a breakpoint, etc without having to explicitly interrupt
 the program you are debugging.  We're still working out all the operations
 that it is safe to do while running.  But this way of operation will set us
 up for "no stop" debugging when we get to implementing that.

 If you want to interrupt a running program do:

 (lldb) process interrupt

 To find out the state of the program, use:

 (lldb) process status
 Process 47958 is running.

 This is very convenient, but it does have the down-side that debugging
 programs that use stdin is no longer as straightforward.  For now, you
 have to specify another tty to use as the program stdout & stdin using
 the appropriate options to "process launch", or start your program in
 another terminal and catch it with "process attach -w".  We will come
 up with some more convenient way to juggle the terminal back & forth
 over time.


 e) Examining program state:

 Once you've stopped, lldb will choose a current thread, usually the
 one that stopped "for a reason", and a current frame in that thread.
 Many the commands for inspecting state work on this current
 thread/frame.

 To inspect the current state of your process, you can start with the
 threads:

 (lldb) thread list
 Process 46915 state is Stopped
 * thread #1: tid = 0x2c03, 0x00007fff85cac76a, where = libSystem.B.dylib`__getdirentries64 + 10, stop reason = signal = SIGSTOP, queue = com.apple.main-thread
   thread #2: tid = 0x2e03, 0x00007fff85cbb08a, where = libSystem.B.dylib`kevent + 10, queue = com.apple.libdispatch-manager
   thread #3: tid = 0x2f03, 0x00007fff85cbbeaa, where = libSystem.B.dylib`__workq_kernreturn + 10

 The * indicates that Thread 1 is the current thread.  To get a
 backtrace for that thread, do:

 (lldb) thread backtrace
 thread #1: tid = 0x2c03, stop reason = breakpoint 1.1, queue = com.apple.main-thread
   frame #0: 0x0000000100010d5b, where = Sketch`-[SKTGraphicView alignLeftEdges:] + 33 at /Projects/Sketch/SKTGraphicView.m:1405
   frame #1: 0x00007fff8602d152, where = AppKit`-[NSApplication sendAction:to:from:] + 95
   frame #2: 0x00007fff860516be, where = AppKit`-[NSMenuItem _corePerformAction] + 365
   frame #3: 0x00007fff86051428, where = AppKit`-[NSCarbonMenuImpl performActionWithHighlightingForItemAtIndex:] + 121
   frame #4: 0x00007fff860370c1, where = AppKit`-[NSMenu performKeyEquivalent:] + 272
   frame #5: 0x00007fff86035e69, where = AppKit`-[NSApplication _handleKeyEquivalent:] + 559
   frame #6: 0x00007fff85f06aa1, where = AppKit`-[NSApplication sendEvent:] + 3630
   frame #7: 0x00007fff85e9d922, where = AppKit`-[NSApplication run] + 474
   frame #8: 0x00007fff85e965f8, where = AppKit`NSApplicationMain + 364
   frame #9: 0x0000000100015ae3, where = Sketch`main + 33 at /Projects/Sketch/SKTMain.m:11
   frame #10: 0x0000000100000f20, where = Sketch`start + 52

 You can also provide a list of threads to backtrace, or the keyword
 "all" to see all threads:

 (lldb) thread backtrace all

 Next task is inspecting data:

 The most convenient way to inspect a frame's arguments and local variables is:

 (lldb) frame variable
 self = (SKTGraphicView *) 0x0000000100208b40
 _cmd = (struct objc_selector *) 0x000000010001bae1
 sender = (id) 0x00000001001264e0
 selection = (NSArray *) 0x00000001001264e0
 i = (NSUInteger) 0x00000001001264e0
 c = (NSUInteger) 0x00000001001253b0

 You can also choose particular variables to view:

 (lldb) frame variable self
 (SKTGraphicView *) self = 0x0000000100208b40

 The frame variable command is not a full expression parser but it
 does support some common operations like dereferencing:

 (lldb) fr v *self
 (SKTGraphicView *) self = 0x0000000100208b40
   (NSView) NSView = {
     (NSResponder) NSResponder = {
 ...

 and structure element references:

 (lldb) frame variable self.isa
 (struct objc_class *) self.isa = 0x0000000100023730

 The frame variable command will also perform "object printing" operations on
 variables (currently we only support NSPrintForDebugger) with:

 (lldb) fr v -o self
 (SKTGraphicView *) self = 0x0000000100208b40
 <SKTGraphicView: 0x100208b40>

 You can select another frame to view with:

 (lldb) frame select 9
 frame #9: 0x0000000100015ae3, where = Sketch`main + 33 at /Projects/Sketch/SKTMain.m:11
    8
    9
   10      int main(int argc, const char *argv[]) {
   11 ->       return NSApplicationMain(argc, argv);
   12          }
   13
   14

 Another neat trick that the variable list does is array references, so:

 (lldb) fr v argv[0]
 (char const *) argv[0] = 0x00007fff5fbffaf8 "/Projects/Sketch/build/Debug/Sketch.app/Contents/MacOS/Sketch"

 If you need to view more complex data or change program data, you can
 use the general "expression" command.  It takes an expression and
 evaluates it in the scope of the currently selected frame.  For instance:

 (lldb) expr self
 $0 = (SKTGraphicView *) 0x0000000100135430
 (lldb) expr self = 0x00
 $1 = (SKTGraphicView *) 0x0000000000000000
 (lldb) frame var self
 (SKTGraphicView *) self = 0x0000000000000000

 You can also call functions:

 (lldb) expr (int) printf ("I have a pointer 0x%llx.\n", self)
 $2 = (int) 22
 I have a pointer 0x0.

 One thing to note from this example is that lldb commands can be defined to
 take "raw" input.  "expression" is one of these.  So in the expression command,
 you don't have to quote your whole expression, nor backslash protect quotes,
 etc...

 Finally, the results of the expressions are stored in persistent variables
 (of the form $[0-9]+) that you can use in further expressions, like:

 (lldb) expr self = $0
 $4 = (SKTGraphicView *) 0x0000000100135430

 f) Customization:

 You can use the embedded Python interprter to add the following 'pwd' and 'cd' commands
 for your lldb session:

 (lldb) script import os
 (lldb) command alias pwd script print os.getcwd()
 (lldb) command regex cd "s/^(.*)$/script os.chdir(os.path.expanduser('%1'))/"

 ...

 (lldb) cd /tmp
 script os.chdir(os.path.expanduser('/tmp'))
 (lldb) pwd
 /private/tmp
 (lldb)

 Or for a more capable 'cd' command, create ~/utils.py like this:

 import os

 def chdir(debugger, args, result, dict):
     """Change the working directory, or cd to ${HOME}."""
     dir = args.strip()
     if dir:
         os.chdir(args)
     else:
         os.chdir(os.path.expanduser('~'))
     print "Current working directory: %s" % os.getcwd()

 and, have the following in your ~/.lldbinit file:

 script import os, sys
 script sys.path.append(os.path.expanduser('~'))
 script import utils
 command alias pwd script print os.getcwd()
 command script add -f utils.chdir cd

 and, then in your lldb session, you can have:

 (lldb) help cd

 Change the working directory, or cd to ${HOME}.
 Syntax: cd
 (lldb) cd
 Current working directory: /Volumes/data/Users/johnny
 (lldb) cd /tmp
 Current working directory: /private/tmp
 (lldb) pwd
 /private/tmp
 (lldb)

 For more examples of customization, look under the ToT/examples/customization
 directory.
	Here's a short precis of how to run lldb if you are familiar with the
	gdb command set:


	1) LLDB Command Structure:

	First some details on lldb command structure to help orient you...

	Unlike gdb's command set, which is rather free-form, we tried to make
	the lldb command syntax fairly structured. The commands are all of the
	form

	<noun> <verb> [-options [option-value]] [argument [argument...]]

	The command line parsing is done before command execution, so it is
	uniform across all the commands. The command syntax is very simple,
	basically arguments, options and option values are all white-space
	separated. If you need to put a backslash or double-quote character
	in an argument you back-slash it in the argument. That makes the
	command syntax more regular, but it also means you may have to
	quote some arguments in lldb that you wouldn't in gdb.

	Options can be placed anywhere on the command line, but if the arguments
	begin with a "-" then you have to tell lldb that you're done with options
	using the "--" option. So for instance, the "process launch" command takes
	the "-s" option to mean "stop the process at the first instruction". It's
	arguments are the arguments you are passing to the program. So if you wanted
	to pass an argument that contained a "-" you would have to do:

	(lldb) process launch -- -program_arg value

	We also tried to reduce the number of special purpose argument
	parsers, which sometimes forces the user to be a little more explicit
	about stating their intentions. The first instance you'll note of
	this is the breakpoint command. In gdb, to set a breakpoint, you
	would just say:

	(gdb) break foo.c:12

	or

	(gdb) break foo

	if foo is a function. As time went on, the parser that tells foo.c:12
	from foo from foo.c::foo (which means the function foo in the file
	foo.c) got more and more complex and bizarre, and especially in C++
	there are times where there's really no way to specify the function
	you want to break on. The lldb commands are more verbose but also precise.
	So you say:

	(lldb) breakpoint set -f foo.c -l 12

	to set a file & line breakpoint. To set a breakpoint on a function
	by name, you do:

	(lldb) breakpoint set -n foo

	This can allow us to be more expressive, so you can say:

	(lldb) breakpoint set -M foo

	to break on all C++ methods named foo, or:

	(lldb) breakpoint set -S alignLeftEdges:

	to set a breakpoint on all ObjC selectors called alignLeftEdges:. It
	also makes it easy to compose specifications, like:

	(lldb) breakpoint set -s foo.dylib -n foo

	for all functions called foo in the shared library foo.dylib. Suggestions
	on more interesting primitives of this sort are also very welcome.

	So for instance:

	(lldb) breakpoint set -n "-[SKTGraphicView alignLeftEdges:]"

	Just like gdb, the lldb command interpreter does a shortest unique
	string match on command names, so the previous command can also be
	typed:

	(lldb) b s -n "-[SKTGraphicView alignLeftEdges:]"

	lldb also supports command completion for source file names, symbol
	names, file names, etc. Completion is initiated by a hitting a <TAB>.
	Individual options in a command can have different completers, so for
	instance the -f option in "breakpoint" completes to source files, the
	-s option to currently loaded shared libraries, etc... We can even do
	things like if you specify -s, and are completing on -f, we will only
	list source files in the shared library specified by -s...

	The individual commands are pretty extensively documented, using
	the "help" command. And there is an "apropos" command that will
	search the help for a particular word and dump a summary help string
	for each matching command.

	Finally, there is a mechanism to construct aliases for commonly used
	commands. So for instance if you get annoyed typing

	(lldb) b s -f foo.c -l 12

	you can do:

	(lldb) command alias bfl breakpoint set -f %1 -l %2
	(lldb) bfl foo.c 12

	We have added a few aliases for commonly used commands (e.g. "step",
	"next" and "continue") but we haven't tried to be exhaustive because
	in our experience it is more convenient to make the basic commands
	unique down to a letter or two, and then learn these sequences than
	fill the namespace with lots of aliases, and then have to type them
	all the way out.

	However, users are free to customize lldb's command set however they
	like, and since lldb reads the file ~/.lldbinit at startup, you can
	store all your aliases there and they will be generally available to
	you. Your aliases are also documented in the help command so you can
	remind yourself of what you've set up.

	lldb also has a built-in Python interpreter, which is accessible by
	the "script" command. All the functionality of the debugger is
	available as classes in the Python interpreter, so the more complex
	commands that in gdb you would introduce with the "define" command can
	be done by writing Python functions using the lldb-Python library,
	then loading the scripts into your running session and accessing them
	with the "script" command.



	2) A typical session:


	a) Setting the program to debug:


	As with gdb, you can start lldb and specify the file you wish to debug
	on the command line:

	$ lldb /Projects/Sketch/build/Debug/Sketch.app
	Current executable set to '/Projects/Sketch/build/Debug/Sketch.app' (x86_64).

	or you can specify it after the fact with the "file" command:

	(lldb) file /Projects/Sketch/build/Debug/Sketch.app
	Current executable set to '/Projects/Sketch/build/Debug/Sketch.app' (x86_64).


	b) Setting breakpoints:


	We've discussed how to set breakpoints above. You can use "help break set"
	to see all the options for breakpoint setting. For instance, we might do:

	(lldb) b s -S alignLeftEdges:
	Breakpoint created: 1: name = 'alignLeftEdges:', locations = 1, resolved = 1

	You can find out about the breakpoints you've set with:

	(lldb) break list
	Current breakpoints:
	1: name = 'alignLeftEdges:', locations = 1, resolved = 1
	1.1: where = Sketch`-[SKTGraphicView alignLeftEdges:] + 33 at /Projects/Sketch/SKTGraphicView.m:1405, address = 0x0000000100010d5b, resolved, hit count = 0

	Note that each "logical" breakpoint can have multiple "locations".
	The logical breakpoint has an integer id, and it's locations have an
	id within their parent breakpoint (the two are joined by a ".",
	e.g. 1.1 in the example above.)

	Also the breakpoints remain "live" so that if another shared library
	were to be loaded that had another implementation of the
	"alignLeftEdges:" selector, the new location would be added to
	breakpoint 1 (e.g. a "1.2" breakpoint would be set on the newly loaded
	selector).

	The other piece of information in the breakpoint listing is whether the
	breakpoint location was "resolved" or not. A location gets resolved when
	the file address it corresponds to gets loaded into the program you are
	debugging. For instance if you set a breakpoint in a shared library that
	then gets unloaded, that breakpoint location will remain, but it will no
	longer be "resolved".

	One other thing to note for gdb users is that lldb acts like gdb with:

	(gdb) set breakpoint pending on

	That is, lldb should always make a breakpoint from your specification, even
	if it couldn't find any locations that match the specification. You can tell
	whether the expression was resolved or not by checking the locations field
	in "breakpoint list", and we report the breakpoint as "pending" when you
	set it so you can tell you've made a typo more easily, if that was indeed
	the reason no locations were found:

	(lldb) b s -f no_such_file.c -l 10000000
	Breakpoint created: 1: file ='no_such_file.c', line = 10000000, locations = 0 (pending)

	You can delete, disable, set conditions and ignore counts either on all the
	locations generated by your logical breakpoint, or on particular locations
	your specification resolved to. For instance if we wanted to add a command
	to print a backtrace when we hit this breakpoint we could do:

	(lldb) b command add -c 1.1
	Enter your debugger command(s). Type 'DONE' to end.
	> bt
	> DONE

	The "-c" option specifies that the breakpoint command is a set of lldb
	commmand interpreter commands. Use "-s" if you want to implement your
	breakpoint command using the Python interface instead.


	c) Running the program:

	Then you can either launch the process with the command:

	(lldb) process launch

	or its alias:

	(lldb) r

	Or you can attach to a process by name with:

	(lldb) process attach -n Sketch

	the "attach by name" also supports the "-w" option which waits for the
	next process of that name to show up, and attaches to that. You can also
	attach by PID:

	(lldb) process attach -p 12345
	Process 46915 Attaching
	(lldb) Process 46915 Stopped
	1 of 3 threads stopped with reasons:
	* thread #1: tid = 0x2c03, 0x00007fff85cac76a, where = libSystem.B.dylib`__getdirentries64 + 10, stop reason = signal = SIGSTOP, queue = com.apple.main-thread

	Note that we tell you that "1 of 3 threads stopped with reasons" and
	then list those threads. In a multi-threaded environment it is very
	common for more than one thread to hit your breakpoint(s) before the
	kernel actually returns control to the debugger. In that case, you
	will see all the threads that stopped for some interesting reason
	listed in the stop message.


	d) Controlling execution:


	After launching, we can continue until we hit our breakpoint. The primitive
	commands for process control all exist under the "thread" command:

	(lldb) thread continue
	Resuming thread 0x2c03 in process 46915
	Resuming process 46915
	(lldb)

	At present you can only operate on one thread at a time, but the
	design will ultimately support saying "step over the function in
	Thread 1, and step into the function in Thread 2, and continue Thread
	3" etc. When we eventually support keeping some threads running while
	others are stopped this will be particularly important. For
	convenience, however, all the stepping commands have easy aliases.
	So "thread continue" is just "c", etc.

	The other program stepping commands are pretty much the same as in gdb.
	You've got:

	1. (lldb) thread step-in
	The same as gdb's "step" -- there is also the alias "s" in lldb

	2. (lldb) thread step-over
	The same as gdb's "next" -- there is also the alias "n" in lldb

	3. (lldb) thread step-out
	The same as gdb's "finish" -- there is also the alias "f" in lldb

	And the "by instruction" versions:

	(lldb) thread step-inst
	(lldb) thread step-over-inst

	Finally, there's:

	(lldb) thread until 100

	which runs the thread in the current frame till it reaches line 100 in
	this frame or stops if it leaves the current frame. This is a pretty
	close equivalent to gdb's "until" command.


	One thing here that might be a little disconcerting to gdb users here is that
	when you resume process execution, you immediately get a prompt back. That's
	because the lldb interpreter remains live when you are running the target.
	This allows you to set a breakpoint, etc without having to explicitly interrupt
	the program you are debugging. We're still working out all the operations
	that it is safe to do while running. But this way of operation will set us
	up for "no stop" debugging when we get to implementing that.

	If you want to interrupt a running program do:

	(lldb) process interrupt

	To find out the state of the program, use:

	(lldb) process status
	Process 47958 is running.

	This is very convenient, but it does have the down-side that debugging
	programs that use stdin is no longer as straightforward. For now, you
	have to specify another tty to use as the program stdout & stdin using
	the appropriate options to "process launch", or start your program in
	another terminal and catch it with "process attach -w". We will come
	up with some more convenient way to juggle the terminal back & forth
	over time.


	e) Examining program state:

	Once you've stopped, lldb will choose a current thread, usually the
	one that stopped "for a reason", and a current frame in that thread.
	Many the commands for inspecting state work on this current
	thread/frame.

	To inspect the current state of your process, you can start with the
	threads:

	(lldb) thread list
	Process 46915 state is Stopped
	* thread #1: tid = 0x2c03, 0x00007fff85cac76a, where = libSystem.B.dylib`__getdirentries64 + 10, stop reason = signal = SIGSTOP, queue = com.apple.main-thread
	thread #2: tid = 0x2e03, 0x00007fff85cbb08a, where = libSystem.B.dylib`kevent + 10, queue = com.apple.libdispatch-manager
	thread #3: tid = 0x2f03, 0x00007fff85cbbeaa, where = libSystem.B.dylib`__workq_kernreturn + 10

	The * indicates that Thread 1 is the current thread. To get a
	backtrace for that thread, do:

	(lldb) thread backtrace
	thread #1: tid = 0x2c03, stop reason = breakpoint 1.1, queue = com.apple.main-thread
	frame #0: 0x0000000100010d5b, where = Sketch`-[SKTGraphicView alignLeftEdges:] + 33 at /Projects/Sketch/SKTGraphicView.m:1405
	frame #1: 0x00007fff8602d152, where = AppKit`-[NSApplication sendAction:to:from:] + 95
	frame #2: 0x00007fff860516be, where = AppKit`-[NSMenuItem _corePerformAction] + 365
	frame #3: 0x00007fff86051428, where = AppKit`-[NSCarbonMenuImpl performActionWithHighlightingForItemAtIndex:] + 121
	frame #4: 0x00007fff860370c1, where = AppKit`-[NSMenu performKeyEquivalent:] + 272
	frame #5: 0x00007fff86035e69, where = AppKit`-[NSApplication _handleKeyEquivalent:] + 559
	frame #6: 0x00007fff85f06aa1, where = AppKit`-[NSApplication sendEvent:] + 3630
	frame #7: 0x00007fff85e9d922, where = AppKit`-[NSApplication run] + 474
	frame #8: 0x00007fff85e965f8, where = AppKit`NSApplicationMain + 364
	frame #9: 0x0000000100015ae3, where = Sketch`main + 33 at /Projects/Sketch/SKTMain.m:11
	frame #10: 0x0000000100000f20, where = Sketch`start + 52

	You can also provide a list of threads to backtrace, or the keyword
	"all" to see all threads:

	(lldb) thread backtrace all

	Next task is inspecting data:

	The most convenient way to inspect a frame's arguments and local variables is:

	(lldb) frame variable
	self = (SKTGraphicView *) 0x0000000100208b40
	_cmd = (struct objc_selector *) 0x000000010001bae1
	sender = (id) 0x00000001001264e0
	selection = (NSArray *) 0x00000001001264e0
	i = (NSUInteger) 0x00000001001264e0
	c = (NSUInteger) 0x00000001001253b0

	You can also choose particular variables to view:

	(lldb) frame variable self
	(SKTGraphicView *) self = 0x0000000100208b40

	The frame variable command is not a full expression parser but it
	does support some common operations like dereferencing:

	(lldb) fr v *self
	(SKTGraphicView *) self = 0x0000000100208b40
	(NSView) NSView = {
	(NSResponder) NSResponder = {
	...

	and structure element references:

	(lldb) frame variable self.isa
	(struct objc_class *) self.isa = 0x0000000100023730

	The frame variable command will also perform "object printing" operations on
	variables (currently we only support NSPrintForDebugger) with:

	(lldb) fr v -o self
	(SKTGraphicView *) self = 0x0000000100208b40
	<SKTGraphicView: 0x100208b40>

	You can select another frame to view with:

	(lldb) frame select 9
	frame #9: 0x0000000100015ae3, where = Sketch`main + 33 at /Projects/Sketch/SKTMain.m:11
	8
	9
	10 int main(int argc, const char *argv[]) {
	11 -> return NSApplicationMain(argc, argv);
	12 }
	13
	14

	Another neat trick that the variable list does is array references, so:

	(lldb) fr v argv[0]
	(char const *) argv[0] = 0x00007fff5fbffaf8 "/Projects/Sketch/build/Debug/Sketch.app/Contents/MacOS/Sketch"

	If you need to view more complex data or change program data, you can
	use the general "expression" command. It takes an expression and
	evaluates it in the scope of the currently selected frame. For instance:

	(lldb) expr self
	$0 = (SKTGraphicView *) 0x0000000100135430
	(lldb) expr self = 0x00
	$1 = (SKTGraphicView *) 0x0000000000000000
	(lldb) frame var self
	(SKTGraphicView *) self = 0x0000000000000000

	You can also call functions:

	(lldb) expr (int) printf ("I have a pointer 0x%llx.\n", self)
	$2 = (int) 22
	I have a pointer 0x0.

	One thing to note from this example is that lldb commands can be defined to
	take "raw" input. "expression" is one of these. So in the expression command,
	you don't have to quote your whole expression, nor backslash protect quotes,
	etc...

	Finally, the results of the expressions are stored in persistent variables
	(of the form $[0-9]+) that you can use in further expressions, like:

	(lldb) expr self = $0
	$4 = (SKTGraphicView *) 0x0000000100135430

	f) Customization:

	You can use the embedded Python interprter to add the following 'pwd' and 'cd' commands
	for your lldb session:

	(lldb) script import os
	(lldb) command alias pwd script print os.getcwd()
	(lldb) command regex cd "s/^(.*)$/script os.chdir(os.path.expanduser('%1'))/"

	...

	(lldb) cd /tmp
	script os.chdir(os.path.expanduser('/tmp'))
	(lldb) pwd
	/private/tmp
	(lldb)

	Or for a more capable 'cd' command, create ~/utils.py like this:

	import os

	def chdir(debugger, args, result, dict):
	"""Change the working directory, or cd to ${HOME}."""
	dir = args.strip()
	if dir:
	os.chdir(args)
	else:
	os.chdir(os.path.expanduser('~'))
	print "Current working directory: %s" % os.getcwd()

	and, have the following in your ~/.lldbinit file:

	script import os, sys
	script sys.path.append(os.path.expanduser('~'))
	script import utils
	command alias pwd script print os.getcwd()
	command script add -f utils.chdir cd

	and, then in your lldb session, you can have:

	(lldb) help cd

	Change the working directory, or cd to ${HOME}.
	Syntax: cd
	(lldb) cd
	Current working directory: /Volumes/data/Users/johnny
	(lldb) cd /tmp
	Current working directory: /private/tmp
	(lldb) pwd
	/private/tmp
	(lldb)

	For more examples of customization, look under the ToT/examples/customization
	directory.