This is actually a rather large and complicated topic, and it is also architecture-specific, so I'll only aim in this answer to provide a summary of the common approaches on the Intel (and compatible) x86 microarchitecture.
The good news is, it is language-independent, so the debugger is going to work the same way whether it's debugging VB.NET, C#, or C++ code. The reason why this is true is that all code is ultimately going to compile (whether statically [i.e., ahead-of-time like C++ or with a JIT compiler like .NET]) or dynamically [e.g., via a run-time interpreter]) to object code that can be natively executed by the processor. It is this native code that the debugger ultimately works on.
Furthermore, this isn't limited to Visual Studio. Its debugger certainly works in the way that I'll describe, but so does any other Windows debugger, like the Debugging Tools for Windows debuggers (WinDbg, KD, CDB, NTSD, etc.), GNU's GDB, IDA's debugger, the open-source x64dbg, and so on.
Let's start with a simple definition—what is a breakpoint? It's just a mechanism that allows execution to be paused so that you can conduct further analysis, whether that's examining the call stack, printing the values of variables, modifying the contents of memory or registers, or even modifying the code itself.
On the x86 architecture, there are several fundamental ways that breakpoints can be implemented. They can be divided into the two general categories of software breakpoints and hardware breakpoints.
Although a software breakpoint uses features of the processor itself, it is primarily implemented within software, hence the name. Specifically, interrupt #3 (the assembly language instruction
INT 3) provides a breakpoint interrupt. This can be placed anywhere in the executable code, and when the CPU hits this instruction during execution, it will trap. The debugger can then catch this trap and do whatever it wants to do. If the program is not running under a debugger, then the operating system will handle the trap; the OS's default handler will simply terminate the program.
There are two possible encodings for the
INT 3 instruction. Perhaps the most logical encoding is
0xCD 0x03, where
0x03 specifies the "argument", or the number of the interrupt that is to be triggered. However, because breakpoints are so important, the designers at Intel also added a special-case representation for
INT 3—the single-byte opcode
The nice thing about this being a one-byte instruction is that it can be inserted pretty much anywhere in a program without much difficulty. Conceptually, this is simple, but the way it actually works is somewhat tricky. Basically, there are two options:
If it's a fixed breakpoint, then the debugger can insert this
INT instruction into the code when it is compiled. Then, every time you hit that point, it will execute that instruction and break.
In C/C++, a fixed breakpoint might be inserted via a call to the
DebugBreak API function, with the
__debugbreak intrinsic, or using inline assembly to insert an
INT 3 instruction. In .NET code, you would use
System.Diagnostics.Debugger.Break to emit a fixed breakpoint.
At runtime, a fixed breakpoint can be easily removed by replacing the one-byte
INT instruction (
0xCC) with a one-byte
NOP instruction (
NOP is the mnemonic for no-op: it just causes the processor to waste a cycle without doing anything.
But if it's a dynamic breakpoint, then things get more complicated. The debugger must modify the binary in-memory and insert the
INT instruction. But where is it going to insert it? Even in a debugging build, a compiler cannot reasonably insert a
NOP between every single instruction, and it doesn't know in advance where you might want to insert a breakpoint, so there won't be space to insert even a one-byte
INT instruction at an arbitrary location in the code.
So what it does instead is insert the
INT instruction (
0xCC) at the requested location, writing over whatever instruction is currently there. If this is a one-byte instruction (such as an
INC), then it is simply replaced by an
INT. If this is a multi-byte instruction (most of them are), then only the first byte of that instruction is replaced by
0xCC. The original instruction then becomes invalid because it's been partially overwritten. But that's okay, because once the processor hits the
INT instruction, it will trap and stop executing at precisely that point. The partial, corrupted, original instruction will not be hit. Once the debugger catches the trap triggered by the
INT instruction and "breaks" in, it undoes the in-memory modification, replacing the inserted
0xCC byte with the correct byte representation for the original instruction. That way, when you resume execution from that point, the code is correct and you don't hit the same breakpoint over and over. Note that all of this modification happens to the current image of the binary executable stored in memory; it is patched directly in memory, without ever modifying the file on disk. (This is done using the
WriteProcessMemory API functions, specifically designed for debuggers.)
Here it is in machine code, showing both the raw bytes as well as the assembly-language mnemonics:
31 C0 xor eax, eax ; clear EAX register to 0
BA 02 00 00 00 mov edx, 2 ; set EDX register to 2
01 D0 add eax, edx ; add EDX to EAX
C3 ret ; return, with result in EAX
If we were to set a breakpoint on the line of source code that added the values (the
ADD instruction in the disassembly), the first byte of the
ADD instruction (
0x01) would be replaced with
0xCC, leaving the remaining bytes as meaningless garbage:
31 C0 xor eax, eax ; clear EAX register to 0
BA 02 00 00 00 mov edx, 2 ; set EDX register to 2
CC int 3 ; BREAKPOINT!
D0 ??? ; meaningless garbage, never executed
C3 ret ; also meaningless garbage from CPU's perspective
Hopefully you were able to follow all of that, because that is actually the simplest case. Software breakpoints are what you use most of the time. Many of the most commonly used features of a debugger are implemented using software breakpoints, including stepping over a call, executing all code up to a particular point, and running to the end of a function. Behind the scenes, all of these use a temporary software breakpoint that is automatically removed the first time that it is hit.
However, there is a more complicated and more powerful way to set a breakpoint with the direct assistance of the processor. These are known as hardware breakpoints. The x86 instruction set provides 6 special debug registers. (They are referred to as
DB7, suggesting a total of 8, but
DR5 are the same as
DR7, so there are actually only 6.) The first 4 debug registers (
DR3) store either a memory address or an I/O location, whose values can be set using a special form of the
DR6 (equivalent to
DR4) is a status register that contains flags, and
DR7 (equivalent to
DR5) is a control register. When the control register is set accordingly, an attempt by the processor to access one of these four locations will cause a hardware breakpoint (specifically, an
INT 1 interrupt will be raised), which can then be caught by a debugger. Again, the details are complicated and can be found various places online or in Intel's technical manuals, but not necessary to gain a high-level understanding.
The nice thing about these special debug registers is that they provide a way to implement data breakpoints without needing to modify the code! However, there are two serious limitations. First, there are only four possible locations, so without a lot of cleverness, you are limited to four breakpoints. Second, the debug registers are privileged resources, and instructions that access and manipulate them can be executed only at ring 0 (essentially, kernel mode). Attempts to read or write these registers at any other privilege level (such as in ring 3, which is effectively user mode) will cause a general protection fault. Therefore, the Visual Studio debugger has to jump through some hoops to use these. I believe that it first suspends the thread and then calls the
SetThreadContext API function (which causes a switch to kernel mode internally) to manipulate the contents of the registers. Finally, it resumes the thread. These debug registers are very powerful for setting read/write breakpoints for memory locations that contain data, as well as for setting execute breakpoints for memory locations that contain code.
However, if you need more than 4, or hit against some other limitation, then these hardware-provided debug registers won't work. The Visual Studio debugger has to have some other, more general way of implementing data breakpoints. This is, in fact, why having a large number of breakpoints can really slow down the execution of your program when running under the debugger.
There are various tricks here, and I know a lot less about exactly which ones are used by the different closed-source debuggers. You could almost certainly find out by reverse-engineering or even closer observation, and perhaps there is someone that knows more about this than me. But I'll briefly summarize a couple of the tricks I know about:
One trick for memory-access breakpoints is to use guard pages. This involves changing the protection level of the virtual-memory page that contains the data of interest to
PAGE_GUARD, meaning that subsequent attempts to access that page (either read or write) will raise a guard page violation exception. The debugger can then catch this exception, verify that it occurred upon access to the memory address of interest, and process it as a breakpoint. Then, when you resume execution, the debugger arranges for the page access to succeed, resets the
PAGE_GUARD flag again, and continues. This is how OllyDBG implements its support for memory-access breakpoints. I don't know if Visual Studio's debugger uses this trick or not.
Another trick is to use single-stepping support. Basically, the debugger sets the Trap Flag (
TF) in the x86
EFLAGS register. This causes the CPU to trap before executing each instruction (which it does by raising an
INT 1 exception, just as we saw above when the debug registers are used). The debugger then catches this trap, and decides whether it should continue executing or not.
Finally, there are conditional breakpoints. This is where you can set a breakpoint on a line of code, but ask the debugger to only break there if a certain specified condition evaluates to true. These are extremely powerful, but, in my experience, only rarely used by developers. As far as I know, these are implemented under the hood as normal, unconditional breakpoints. When the breakpoint is hit, the debugger automatically evaluates the condition. If it is true, it "breaks in" for the user. If it is false, it continues execution just as if the breakpoint had never been hit. There is no hardware support for conditional breakpoints (beyond the data breakpoints support discussed above), and I am not aware of any lower-level support for conditional breakpoints (e.g., something provided by the operating system). This is, of course, why having complicated conditions attached to your breakpoints can significantly slow down the execution speed of your program!
If you're interested in more details (as if this answer isn't already long enough!), you might check out Tarik Soulami's Inside Windows Debugging. It looks like it contains relevant information, although I haven't read it yet so I can't unabashedly recommend it. (It's on my Amazon wish list!)