Advanced Apple Debugging & Reverse Engineering – Available Now!

The full version of Advanced Apple Debugging & Reverse Engineering is available now on our store. See what’s new, and grab your launch week discount! By Chris Belanger.

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The full version of the book has a full five sections, 27 chapters and two appendices, including complete source code for all the projects and scripts in the book.

To continue the launch celebrations, we’re extending the launch discount for the book on our store — for this week only.

Read on to see what the book is all about, how to take advantage of the discount and where you can get your copy!

What’s New in Advanced Apple Debugging & Reverse Engineering?

The v1.0 release of Advanced Apple Debugging and Reverse Engineering adds an entirely new section on DTrace, which is a great tool you can use to hook into a function or a group of functions using what’s known as a probe.

From there, you can perform custom actions to query information out of a specific process, or even system wide on your computer (and monitor multiple users)!

If you’ve ever used the Instruments application, it might surprise you to learn that a lot of the power underneath it is due to DTrace.

Here’s what we’ve added in the latest update to this book:

Learn the basics of DTrace commands – they’re less scary than they first appear!

Learn how DTrace can interact in the deep reaches of your OS – with some rather interesting results!

  • Hello, DTrace: You’ll explore a very small section of what DTrace is capable of doing by tracing Objective-C code in already compiled applications. Using DTrace to observe iOS frameworks (like UIKit) can give you an incredible insight into how the authors designed their code.
  • Learn the basics of DTrace commands – they’re less scary than they first appear!

  • Intermediate DTrace: This chapter will act as a grab-bag of more DTrace fundamentals, destructive actions, as well as how to use DTrace with Swift. In this chapter, you’ll learn additional ways DTrace can profile code, as well as how to augment existing code without laying a finger on the actual executable itself.
  • Learn how DTrace can interact in the deep reaches of your OS – with some rather interesting results!

  • DTrace vs objc_msgSend: In the final chapter, you’ll use DTrace to hook objc_msgSend’s entry probe and pull out the class name along with the Objective-C selector for that class. By the end of this chapter, you’ll have LLDB generating a DTrace script which only generates tracing info for code implemented within the main executable that calls objc_msgSend.

Learn the basics of DTrace commands – they’re less scary than they first appear!

Learn how DTrace can interact in the deep reaches of your OS – with some rather interesting results!

What’s In the Rest of the Book?

Here’s the complete listing of what’s contained in the book:

Section I: Beginning LLDB Commands

  1. Getting Started: In this chapter, you’re going to get acquainted with LLDB and investigate the process of introspecting and debugging a program. You’ll start off by introspecting a program you didn’t even write — Xcode!
  2. Help & Apropos: Just like any respectable developer tool, LLDB ships with a healthy amount of documentation. Knowing how to navigate through this documentation — including some of the more obscure command flags — is essential to mastering LLDB.
  3. Attaching with LLDB: Now that you’ve learned about the two most essential commands, help and apropos, it’s time to investigate how LLDB attaches itself to processes. You’ll learn all the different ways you can attach LLDB to processes using various options, as well as what happens behind the scenes when attaching to processes.
  4. Stopping in Code: Whether you’re using Swift, Objective-C, C++, C, or an entirely different language in your technology stack, you’ll need to learn how to create breakpoints. It’s easy to click on the side panel in Xcode to create a breakpoint using the GUI, but the LLDB console can give you much more control over breakpoints.
  5. Expression: Now that you’ve learned how to set breakpoints so the debugger will stop in your code, it’s time to get useful information out of whatever software you’re debugging. In this chapter you’ll learn about the expression command, which allows you to execute arbitrary code in the debugger.
  6. Thread, Frame & Stepping Around: You’ve learned how to create breakpoints, how to print and modify values, as well as how to execute code while paused in the debugger. But so far you’ve been left high and dry on how to move around in the debugger and inspect data beyond the immediate. In this chapter, you’ll learn how to move the debugger in and out of functions while LLDB is currently paused.
  7. Image: It’s time to explore one of the best tools for finding code of interest through the powers of LLDB. In this chapter, you’ll take a deep dive into the image command.
  8. Persisting & Customizing Commands: In this chapter, you’ll learn how to persist these choices through the .lldbinit file. By persisting your choices and making convenience commands for yourself, your debugging sessions will run much more smoothly and efficiently. This is also an important concept because from here on out, you’ll use the .lldbinit file on a regular basis.
  9. Regex Commands: In the previous chapter, you learned about the command alias command as well as how to persist commands through the lldbinit file. Unfortunately, command alias has some limitations. The LLDB command command regex acts much like command alias, except you can provide a regular expression for input which will be parsed and applied to the action part of the command.

Section II: Understanding Assembly

  1. Assembly Register Calling Convention: Now you’ve gained a basic understanding of how to maneuver around the debugger, it’s time to take a step down the executable Jenga tower and explore the 1s and 0s that make up your source code. This section will focus on the low-level aspects of debugging.
  2. Assembly & Memory: In this chapter, you’ll explore how a program executes. You’ll look at a special register used to tell the processor where it should read the next instruction from, as well as how different sizes and groupings of memory can produce very different results.
  3. Assembly and the Stack: What does being “passed on the stack” mean exactly? It’s time to take a deeper dive into what happens when a function is called from an assembly standpoint by exploring some “stack related” registers as well as the contents in the stack.

Learn how to reverse engineer code like a boss!

Learn how to reverse engineer code like a boss!

Section III: Low Level

  1. Hello, Ptrace: As alluded to in the introduction to this book, debugging is not entirely about just fixing stuff. Debugging is the process of gaining a better understanding of what’s happening behind the scenes. In this chapter, you’ll explore the foundation of debugging, namely, a system call responsible for a process attaching itself to another process: ptrace.
  2. Dynamic Frameworks: With dynamic frameworks comes a very interesting aspect of learning, debugging, and reverse engineering. Since you have the ability to load the framework at runtime, you can use LLDB to explore and execute code at runtime, which is great for spelunking in both public and private frameworks.
  3. Hooking & Executing Code with dlopen & dlsym: It’s time to learn about the complementary skills of developing with these frameworks. In this chapter, you’re going to learn about methods and strategies to “hook” into Swift and C code as well as execute methods you wouldn’t normally have access to.
  4. Exploring and Method Swizzling Objective-C Frameworks: You’ll cap off this round of dynamic framework exploration by digging into Objective-C frameworks using the Objective-C runtime to hook and execute methods of interest.

Section IV: Custom LLDB Commands

  1. Hello Script Bridging: Next up in the tradeoff between convenience and complexity is LLDB’s script bridging. With script bridging, you can do nearly anything you like. Script bridging is a Python interface LLDB uses to help extend the debugger to accomplish your wildest debugging dreams.
  2. Debugging Script Bridging: You need a methodical way to figure out what went wrong in your LLDB script so you don’t pull your hair out. In this chapter, you’ll explore how to inspect your LLDB Python scripts using the Python pdb module, which is used for debugging Python scripts.
  3. Script Bridging Classes and Hierarchy: You’ve learned the essentials of working with LLDB’s Python module, as well as how to correct any errors using Python’s PDB debugging module. Now you’ll explore the main players within the lldb Python module for a good overview of the main parts. In this chapter, you’ll add some arguments to this script and deal with some annoying edge cases, such handling commands differently between Objective-C and Swift.
  4. Script Bridging with Options & Arguments: When you’re creating a custom debugging command, you’ll often want to slightly tweak functionality based upon options or arguments supplied to your command. A custom LLDB command that can do a job only one way is a boring one-trick pony. In this chapter, you’ll explore how to pass optional parameters (aka options) as well as arguments (parameters which are expected) to your custom command to alter functionality or logic in your custom LLDB scripts.
  5. Script Bridging with SBValue & Memory: So far, when evaluating JIT code (i.e. Objective-C, Swift, C, etc. code that’s executed through your Python script), you’ve used a small set of APIs to evaluate the code. It’s time to talk about a new class in the lldb Python module, SBValue, and how it can simplify the parsing of JIT code output.
  6. SB Examples, Improved Lookup: For the rest of the chapters in this section, you’ll focus on Python scripts. As alluded to in the previous chapter, the image lookup -rn command is on its way out. When you finish this chapter, you’ll have a new script named “lookup” which queries in a much cleaner way.
  7. SB Examples, Resymbolicating a Stripped ObjC Binary: When LLDB comes up against a stripped executable (an executable devoid of DWARF debugging information), LLDB won’t have the symbol information to give you the stack trace. Instead, LLDB will generate a synthetic name for a method it recognizes as a method, but doesn’t know what to call it. In this chapter, you’ll build an LLDB script that will resymbolicate stripped Objective-C functions in a stack trace.
  8. SB Examples, Malloc Logging: For the final chapter in this section, you’ll go through the same steps I myself took to understand how the MallocStackLogging environment variable is used to get the stack trace when an object is created. From there, you’ll create a custom LLDB command which gives you the stack trace of when an object was allocated or deallocated in memory — even after the stack trace is long gone from the debugger.

Section V: DTrace

  1. Hello, DTrace: You’ll explore a very small section of what DTrace is capable of doing by tracing Objective-C code in already compiled applications. Using DTrace to observe iOS frameworks (like UIKit) can give you an incredible insight into how the authors designed their code.
  2. Intermediate DTrace: This chapter will act as a grab-bag of more DTrace fundamentals, destructive actions (yay!), as well as how to use DTrace with Swift. In this chapter, you’ll learn additional ways DTrace can profile code, as well as how to augment existing code without laying a finger on the actual executable itself.
  3. DTrace vs objc_msgSend: In this chapter, you’ll use DTrace to hook objc_msgSend’s entry probe and pull out the class name along with the Objective-C selector for that class. By the end of this chapter, you’ll have LLDB generating a DTrace script which only generates tracing info for code implemented within the main executable that calls objc_msgSend.
Chris Belanger

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