timwhitez starred bof-vs

This repository contains the Beacon Object File Visual Studio (BOF-VS) template project. You can read more about rationale and design decisions from this blog post.

Quick Start Guide

To get started, use the instructions provided below.

Prerequisites:

An x64 Windows 10/11 development machine (without a security solution)
Visual Studio Community/Pro/Enterprise 2022 (Desktop Development with C++ installed)

Download the latest release, and copy the bof-vs.zip archive under the %USERPROFILE%\Documents\Visual Studio 2022\Templates\ProjectTemplates folder. The template is accessible through Visual Studio's new project dialog, where you can locate it by searching with the keyword BOF. Be certain to have All languages chosen as the language filter.

If Visual Studio does not recognize the template, then reset the project template cache by deleting the following file: %localappdata%\Microsoft\VisualStudio\<VS vesrion>\ProjectTemplatesCache_{<GUID>}\cache.bin

Debug Build

The Debug target builds your BOF to an executable, which allows you to benefit from the convenience of debugging your BOF code directly within Visual Studio's built-in debugger. This will enable you to work at the source code level without running the BOF through a Beacon.

Release Build

The Release target compiles a release object file of your BOF, which is designed to be used directly with Cobalt Strike.

Dynamic Function Resolution

The project template includes two macro definitions to facilitate Dynamic Function Resolution (DFR) declarations. These macros provide a robust mechanism for efficiently resolving Win32 API functions in BOFs and simplify the development process significantly.

DFR Macro

The DFR macro can automatically extract the function type and generate the required function declaration.

DFR(KERNEL32, OpenProcess)

The above DFR macro statement expands to the following declaration.

DECLSPEC_IMPORT decltype(OpenProcess) KERNEL32$OpenProcess;

A common practice is to map the KERNEL32$OpenProcess function to OpenProcess using the following macro definition. This mapping enables you to call the OpenProcess function directly, eliminating the need for the KERNEL32$ prefix.

#define OpenProcess KERNEL32$OpenProcess

Example Usage

DFR(KERNEL32, OpenProcess)
#define OpenProcess KERNEL32$OpenProcess

void func1() { 
    OpenProcess(...); 
}

void func2() { 
    OpenProcess(...); 
}

DFR_LOCAL Macro

The DFR_LOCAL(module, function) macro allows you to define a local function pointer variable that directly references the module$function function. One of the main advantages of using this macro compared to the DFR macro is the elimination of the need for the additional OpenProcess -> KERNEL32$OpenProcess mapping. This streamlines the code and makes it more concise. However, it's important to note that the function pointer created with the DFR_LOCAL macro has a limited scope and can only be accessed within the function where it is defined. Consequently, if you plan to use the required WINAPI functions in multiple functions throughout your BOF, you will need to define the function pointer using the DFR_LOCAL macro in each of those functions.

Example Usage

void func1() { 
    DFR_LOCAL(KERNEL32, OpenProcess); 
    OpenProcess(...); 
} 

void func2() { 
    DFR_LOCAL(KERNEL32, OpenProcess); 
    OpenProcess(...); 
}

Mocked APIs

The template includes a mocked version of the Beacon API for Debug builds, enabling BOF debugging without a running Beacon instance. When you select either the Debug or UnitTest configuration, the mocked API is automatically included into the project.

Argument Packer

The BofData class implements an argument packer to replicate the argument packing behavior of the bof_pack aggressor function. This enables us to call BOF's entry point with custom arguments without Beacon.

bof::mock::BofData data; 
// the pack function takes one or more arguments 
data.pack<int, short, int, const char*>(6502, 80, 68010, "Hello World"); 

// alternatively, the << operator can be used to construct the arguments buffer 
data << 0xdeadface << L"Hello World"; 

// raw buffers can be added too 
const char buf[] = { 0x41, 0x42, 0x43, 0x44 }; 
data.addData(buf, sizeof(buf)); 

go(data.get(), data.size());

Beacon API

The template also provides a mocked implementation of the Data Parser, Output, and Format APIs. The mocked functions within the Output API print the output to the standard output, ensuring the results are visible. Moreover, all returned output is stored for future examination and analysis.

Furthermore, the Internal API functions (such as BeaconUseToken, BeaconInjectProcess, etc.) are declared. However, it is important to note that these functions lack the real implementation and only display an error message on the standard error if called.

Unit Tests

The project template offers an additional build target called UnitTest, specifically designed to build BOFs with the GoogleTest framework. Furthermore, the mock library provides a convenient runMocked function that handles the argument packing, execution of the BOF's entry point, and capturing all generated outputs.

Install the GoogleTest framework:

Right-click the project name in Solution Explorer.
Select Manage NuGet Packages.
Ensure that the Microsoft.googletest.v140.windesktop.msvcstl.static.rt-static package is installed.

Example Usage

extern "C" { 
    #include "beacon.h" 

    void go(char* args, int len) { 
        datap parser; 
        BeaconDataParse(&parser, args, len); 
        int number = BeaconDataInt(&parser); 
        BeaconPrintf(CALLBACK_OUTPUT, "Hello: %i", number); 
    } 
} 

TEST(ExampleBofTest, TestCase1) { 
    std::vector<bof::output::OutputEntry> actual = 
        bof::runMocked<int>(go, 6502); 

    std::vector<bof::output::OutputEntry> expected = { 
        {CALLBACK_OUTPUT, "Hello: 6502"} 
    }; 

    ASSERT_EQ(expected, actual); 
}

Multiple BOFs

The template supports multiple BOFs within separate files, enabling each .cpp file to be compiled into an individual BOF. This approach eliminates the need for multiple projects and allows grouping similar BOFs under one Visual Studio project. When it comes to debugging, since each BOF is compiled into its own debug executable, it is important to adjust the debug command accordingly. This can be done through the project properties: Configuration Properties -> Debugging -> Command.