Introduction

In today's highly connected and data-driven world, network performance is crucial for ensuring efficient communication and optimal user experience. XDP (eXpress Data Path) and eBPF (extended Berkeley Packet Filter) have emerged as powerful technologies that enable high-performance packet processing and network optimization. In this step-by-step guide, we will explore the process of building an XDP eBPF program using C and Golang. XDP allows for early packet interception at the network interface driver level, while eBPF provides a flexible and efficient execution environment for custom packet processing logic. Together, they offer an unprecedented level of control and performance in networking applications. Our project, named "dilih" (drop it like it's hot), demonstrates how to build a simple chaos engineering tool that arbitrarily drops packets on a given network interface, which can be a useful tool to allow application developers to understand how their products behave when the network isn't. Through this guide, you will gain a basic understanding of XDP, eBPF, and their practical applications in network manipulation.

note: you can find the entire codebase for this article here: https://github.com/peter-mcconnell/dilih

Project Overview

The project aims to build an XDP (eXpress Data Path) eBPF (extended Berkeley Packet Filter) program using C and Golang. Named "dilih" (drop it like it's hot, as it drops packets like ... they're hot?), the program serves as a simple chaos engineering tool that randomly drops around 50% of packets on a given network interface. This project demonstrates the power and flexibility of XDP and eBPF in controlling packet processing at high speed, making it an ideal starting point for understanding these technologies.

The XDP eBPF program, implemented in C, hooks into the Linux kernel's networking stack at an early stage to intercept packets and decide their fate. Using a simple randomization mechanism the program selectively drops packets allowing for controlled chaos in network traffic. Additionally, the program utilizes eBPF's perf event mechanism to gather statistics and measure the processing time for dropped and passed packets.

The accompanying Golang application interacts with the XDP eBPF program, providing a user-friendly interface to monitor the packet drop behavior and visualize performance statistics. It leverages eBPF maps to extract and aggregate the collected data from kernel space, allowing users to gain insights into the impact of dropped packets and the efficiency of packet processing.

Setting Up the Development Environment

To get started with building the XDP eBPF program with C and Golang, you need to set up your development environment. Follow these steps to ensure that you have all the necessary tools and dependencies in place:

1. Install Development Tools

   First, ensure that you have the required development tools installed on your system. This includes packages like clang, llvm, and bpftool. You can install these tools using the package manager available on your Linux distribution however I would recommend investing a little time to build these tools from source as it will give you greater control over the flags and features built into these tools.

   If you are curious about my exact LLVM / Clang setup, I use the following ansible tasks for my configuration:

   https://github.com/peter-mcconnell/.dotfiles/blob/master/tasks/llvm.yaml
   https://github.com/peter-mcconnell/.dotfiles/blob/master/tasks/debugtools.yaml
   https://github.com/peter-mcconnell/.dotfiles/blob/master/tasks/docker.yaml

2. Install Golang

   Next, you need to install Golang, which is the programming language used for the accompanying Golang application. Visit the official Golang website at https://golang.org and follow the installation instructions specific to your operating system. Once installed, make sure the go command is accessible from the command line by adding the appropriate binary directory to your system's PATH.

   If you are curious about my exact Golang setup, I use the following ansible task for my configuration:

   https://github.com/peter-mcconnell/.dotfiles/blob/master/tasks/golang.yaml

3. Install Project Dependencies

   go dependencies

   Navigate to the project's root directory and install the required Golang dependencies by running the following command:
   

   go mod download
   

   This command will fetch and install the necessary Golang packages defined in the project's go.mod file.

   libbpf

   We are going to use libbpf in our C code. In the dilih repo we added this as a git submodule but you can choose to manage it elsewhere if you like. When we build our C program later we'll include libbpf with -I../libbpf/src

4. (Optional) IDE configuration

   Whatever your editor of choice should be, invest some time in making sure it is set up for C and Golang. Particularly for autocomplete, linting, symbol detection etc. This will make your life much easier.

   If you are curious about my exact setup, I use the following repo to install neovim, configure my LSP and setup everything else I need for development:

   https://github.com/peter-mcconnell/.dotfiles/

Writing the XDP eBPF Program in C

The XDP (eXpress Data Path) program is implemented using the eBPF (extended Berkeley Packet Filter) framework in C, with some help from libbpf. It allows us to intercept packets at an early stage in the Linux kernel's networking stack and perform custom packet processing logic. In this section, we will walk through the steps to write the XDP eBPF program in C.

1. Understanding the Program Logic

   Before diving into the code, let's understand the logic of our XDP program. The goal is to randomly drop ~50% of packets on a given network interface. We will use a randomization mechanism to decide whether to drop or pass each packet ("is random number even?"). The program will also collect statistics and measure the processing time for dropped and passed packets using eBPF's perf event mechanism. Our BPF program runs in kernel space but we'll want to expose data to userspace, so we'll use BPF maps to expose data to our Go program.

2. Creating the Program Source File

   Start by creating a new file called dilih_kern.c in a ./bpf/ directory in your project. This file will contain our XDP eBPF program logic. Open the file in your favorite text editor.

3. Defining the required headers and structures

   To begin, include the necessary headers and define the required structures for our XDP program. We need bpf.h and bpf_helpers.h which provide useful structures and helper functions.
   

   #include <linux/bpf.h>
   #include <bpf_helpers.h>
   

4. Defining Data Structures and Maps

   Next, define the necessary data structures and maps that our XDP program will utilize. We will use a struct to represent the perf event data, and a BPF_MAP_TYPE_PERF_EVENT_ARRAY map to store the perf events. Define the following structures and maps:
   

   struct perf_trace_event {
       __u64 timestamp;
       __u32 processing_time_ns;
       __u8 type;
   };
   
   #define TYPE_ENTER 1
   #define TYPE_DROP 2
   #define TYPE_PASS 3
   
   struct {
       __uint(type, BPF_MAP_TYPE_PERF_EVENT_ARRAY);
       __uint(key_size, sizeof(int));
       __uint(value_size, sizeof(struct perf_trace_event));
       __uint(max_entries, 1024);
   } output_map SEC(".maps");
   
   

   The output_map map will be used to store the perf events generated by our XDP program. The TYPE_* definitions will make our code more readable later.

5. Implementing the XDP Program Function

   Now, it's time to implement the XDP program function itself. Begin by declaring the XDP function with the appropriate signature:
   

   SEC("xdp")
   int xdp_dilih(struct xdp_md *ctx)
   {
       // Add program logic here ... detailed in the next step
   }
   

   The xdp_dilih function will serve as our XDP eBPF program entry point. It will be called for every incoming packet.

6. Handling Perf Events and Collecting Data

   Inside the xdp_dilih function, we can handle perf events to collect data and measure processing time. We have already defined the output_map to store these events. Use the bpf_perf_event_output helper function to emit perf events to the map.
   

   struct perf_trace_event e = {};
   
   // Perf event for entering xdp program
   e.timestamp = bpf_ktime_get_ns();
   e.type = TYPE_ENTER;
   e.processing_time_ns = 0;
   bpf_perf_event_output(ctx, &output_map, BPF_F_CURRENT_CPU, &e, sizeof(e));
   
   // Packet dropping logic
   if (bpf_get_prandom_u32() % 2 == 0) {
       // Perf event for dropping packet
       e.type = TYPE_DROP;
       __u64 ts = bpf_ktime_get_ns();
       e.processing_time_ns = ts - e.timestamp;
       e.timestamp = ts;
       bpf_perf_event_output(ctx, &output_map, BPF_F_CURRENT_CPU, &e, sizeof(e));
       return XDP_DROP;
   }
   
   // Perf event for passing packet
   e.type = TYPE_PASS;
   __u64 ts = bpf_ktime_get_ns();
   e.processing_time_ns = ts - e.timestamp;
   e.timestamp = ts;
   bpf_perf_event_output(ctx, &output_map, BPF_F_CURRENT_CPU, &e, sizeof(e));
   
   return XDP_PASS;
   

   In this section of the code, we handle the perf events to collect data and measure the processing time of dropped and passed packets. We first emit a perf event when entering the XDP program (type 1). Then, we use a randomization mechanism to decide whether to drop or pass the packet. If the packet is dropped, we emit a perf event with type 2 and return XDP_DROP. If the packet is passed, we emit a perf event with type 3 and return XDP_PASS.

   The bpf_ktime_get_ns() function is used to measure the timestamp (nanoseconds since system boot, excluding suspend time) and processing time of the packet. The bpf_get_prandom_u32() function generates a random value that helps in deciding whether to drop or pass the packet - the "is this random number even?" part.

   Additionally, we use bpf_printk() to print debug messages that can be accessed through the kernel's trace buffer.

That concludes the implementation of the XDP eBPF program in C. This program will selectively drop packets based on a randomization mechanism and emit perf events for collecting data and measuring processing time.

Compiling and Loading the XDP eBPF Program

Once we have written the XDP eBPF program in C, the next step is to compile it and load it into the kernel. In this section, we will walk through the steps to compile and load the XDP eBPF program.

Compiling the XDP Program

To compile the XDP program, we will use the LLVM Clang compiler with the appropriate flags. Open a terminal and navigate to the bpf directory where the dilih_kern.c file is located. Then, run the following command:

clang -S \
    -g \
    -target bpf \
    -I../libbpf/src\
    -Wall \
    -Werror \
    -O2 -emit-llvm -c -o dilih_kern.ll dilih_kern.c

Let me explain the flags:

• -S Emit an intermediate representation (IR) assembly code file instead of generating object code. This step is used to generate LLVM IR code.
• -g Include BTF information
• -target bpf Specify the target architecture as "bpf" (Berkeley Packet Filter), indicating that the code being compiled is intended to run on eBPF.
• -I../libbpf/src Add the path ../libbpf/src to the include search paths. This allows the compiler to find the necessary header files (bpf helper files) from the libbpf library.`Wall Enable all compiler warning messages.
• -Werror Treat all warnings as errors, causing the compilation process to fail if any warnings are encountered.
• -O2 Apply optimization level 2 to the generated code. This level of optimization focuses on improving performance without sacrificing code size. This is actually a requirement for some BPF usecases, though I'm struggling to recall right now what they are. TODO
• -emit-llvm Instruct the compiler to emit LLVM IR code as the output.
• -c Compile the input source file without linking, producing an object file.
• -o dilih_kern.ll: Specify the output file name for the generated LLVM IR code as dilih_kern.ll.

Now we use the llc command is used to further process the LLVM IR code and generate the final object file:

llc -march=bpf -filetype=obj -O2 -o dilih_kern.o dilih_kern.ll

Let me explain the flags:

• -march=bpf Specify the target architecture as "bpf" for the code generation stage.
• -filetype=obj Specify the desired output file type as an object file.
• -O2 Apply optimization level 2 to the generated code during the code generation stage.
• -o Specify the output file name for the generated object code as dilih_kern.o.

This command compiles the dilih_kern.c file into a BPF object file named dilih_kern.o. The -target bpf flag specifies the target architecture as BPF, and the -O2 flag enables optimization.

Loading the XDP Program

To load the XDP program into the kernel, we will use the bpftool command-line utility. Ensure that you have the bpftool utility installed on your system. If it's not already installed, you can typically install it using your distribution's package manager.

In the terminal, run the following command to load the XDP program:

sudo bpftool prog load dilih\_kern.o /sys/fs/bpf/dilih

This command loads the dilih_kern.o object file and pins it into the /sys/fs/bpf/dilih location. Adjust the path as necessary based on your system configuration. The bpftool utility will handle the loading process and verify the program's validity.

Attaching the XDP Program

After loading the XDP program, we need to attach it to a network interface to start intercepting packets. To attach the XDP program, run the following command:

sudo bpftool net attach xdp pinned /sys/fs/bpf/dilih dev <interface>

you can get by running `ip link'

Replace with the name of the network interface you want to attach the XDP program to. For example, eth0. This command attaches the XDP program to the specified interface, enabling it to intercept incoming packets.

Makefile

For convenience, lets throw some of what we learned above into a Makefile at ./bpf/Makefile. I'll not go into depths about how Makefiles work in this article but will summarise the functionality after the code snippet:
``

TARGET = dilih
BPF_TARGET = ${TARGET:=_kern}
BPF_C = ${BPF_TARGET:=.c}
BPF_OBJ = ${BPF_C:.c=.o}

BPF_PINNED_PATH := /sys/fs/bpf/$(TARGET)
XDP_NAME := dilih
DEV := ens160

xdp: $(BPF_OBJ)
        -bpftool net detach xdpgeneric dev $(DEV)
        rm -f $(BPF_PINNED_PATH)
        bpftool prog load $(BPF_OBJ) $(BPF_PINNED_PATH)
        bpftool net attach xdpgeneric pinned $(BPF_PINNED_PATH) dev $(DEV)

$(BPF_OBJ): %.o: %.c
        clang -S \
                -g \
                -target bpf \
          -I../libbpf/src\
                -Wall \
                -Werror \
                -O2 -emit-llvm -c -o ${@:.o=.ll} $<
        llc -march=bpf -filetype=obj -O2 -o $@ ${@:.o=.ll}

clean:
        -bpftool net detach xdpgeneric dev $(DEV)
        sudo rm -f $(BPF_PINNED_PATH)
        rm -f $(BPF_OBJ)
        rm -f ${BPF_OBJ:.o=.ll}

With this file in place and make installed you can run something like DEV=eth0 make to compile and load the eBPF program and DEV=eth0 make clean to remove the files and unload the eBPF program.

Congratulations! You have successfully compiled and loaded the XDP eBPF program into the kernel and attached it to a network interface. The program is now ready to intercept and process packets based on your defined logic.

Please note that the compilation and loading process may vary slightly depending on your system configuration and specific requirements. Make sure to adjust the commands accordingly and refer to the documentation of the tools and utilities used.

Writing the Golang Application

In this section, we will write a Golang application that interacts with the XDP eBPF program and collects metrics. The Golang application will communicate with the loaded XDP program, read the perf events, and display statistics based on the collected data.

Writing the Golang Application Code

Let's create a new file named main.go and open it in a text editor. This file will contain the code for our Golang application. Copy and paste the following code into main.go:

package main

import (
        "encoding/binary"
        "fmt"
        "net"
        "os"
        "os/signal"
        "syscall"

        "github.com/cilium/ebpf"
        "github.com/cilium/ebpf/link"
        "github.com/cilium/ebpf/perf"
)

const (
        TYPE_ENTER = 1
        TYPE_DROP  = 2
        TYPE_PASS  = 3
)

type event struct {
        TimeSinceBoot  uint64
        ProcessingTime uint32
        Type           uint8
}

const ringBufferSize = 128 // size of ring buffer used to calculate average processing times
type ringBuffer struct {
        data   [ringBufferSize]uint32
        start  int
        pointer int
        filled bool
}

func (rb *ringBuffer) add(val uint32) {
        if rb.pointer < ringBufferSize {
                rb.pointer++
        } else {
                rb.filled = true
                rb.pointer= 1
        }
        rb.data[rb.pointer-1] = val
}

func (rb *ringBuffer) avg() float32 {
        if rb.pointer == 0 {
                return 0
        }
        sum := uint32(0)
        for _, val := range rb.data {
                sum += uint32(val)
        }
        if rb.filled {
                return float32(sum) / float32(ringBufferSize)
        }
        return float32(sum) / float32(rb.pointer)
}

func main() {
        spec, err := ebpf.LoadCollectionSpec("bpf/dilih_kern.o")
        if err != nil {
                panic(err)
        }

        coll, err := ebpf.NewCollection(spec)
        if err != nil {
                panic(fmt.Sprintf("Failed to create new collection: %v\n", err))
        }
        defer coll.Close()

        prog := coll.Programs["xdp_dilih"]
        if prog == nil {
                panic("No program named 'xdp_dilih' found in collection")
        }

        iface := os.Getenv("INTERFACE")
        if iface == "" {
                panic("No interface specified. Please set the INTERFACE environment variable to the name of the interface to be use")
        }
        iface_idx, err := net.InterfaceByName(iface)
        if err != nil {
                panic(fmt.Sprintf("Failed to get interface %s: %v\n", iface, err))
        }
        opts := link.XDPOptions{
                Program:   prog,
                Interface: iface_idx.Index,
                // Flags is one of XDPAttachFlags (optional).
        }
        lnk, err := link.AttachXDP(opts)
        if err != nil {
                panic(err)
        }
        defer lnk.Close()

        fmt.Println("Successfully loaded and attached BPF program.")

        // handle perf events
        outputMap, ok := coll.Maps["output_map"]
        if !ok {
                panic("No map named 'output_map' found in collection")
        }
        perfEvent, err := perf.NewReader(outputMap, 4096)
        if err != nil {
                panic(fmt.Sprintf("Failed to create perf event reader: %v\n", err))
        }
        defer perfEvent.Close()
        buckets := map[uint8]uint32{
                TYPE_ENTER: 0, // bpf program entered
                TYPE_DROP: 0, // bpf program dropped
                TYPE_PASS: 0, // bpf program passed
        }

        processingTimePassed := &ringBuffer{}
        processingTimeDropped := &ringBuffer{}

        go func() {
                // var event event
                for {
                        record, err := perfEvent.Read()
                        if err != nil {
                                fmt.Println(err)
                                continue
                        }

                        var e event
                        if len(record.RawSample) < 12 {
                                fmt.Println("Invalid sample size")
                                continue
                        }
                        // time since boot in the first 8 bytes
                        e.TimeSinceBoot = binary.LittleEndian.Uint64(record.RawSample[:8])
                        // processing time in the next 4 bytes
                        e.ProcessingTime = binary.LittleEndian.Uint32(record.RawSample[8:12])
                        // type in the last byte
                        e.Type = uint8(record.RawSample[12])
                        buckets[e.Type]++

                        if e.Type == TYPE_ENTER {
                                continue
                        }
                        if e.Type == TYPE_DROP {
                                processingTimeDropped.add(e.ProcessingTime)
                        } else if e.Type == TYPE_PASS {
                                processingTimePassed.add(e.ProcessingTime)
                        }

                        fmt.Print("\033[H\033[2J")
                        fmt.Printf("total: %d. passed: %d. dropped: %d. passed processing time avg (ns): %f. dropped processing time avg (ns): %f\n", buckets[TYPE_ENTER], buckets[TYPE_PASS], buckets[TYPE_DROP], processingTimePassed.avg(), processingTimeDropped.avg())
                }
        }()

        c := make(chan os.Signal, 1)
        signal.Notify(c, os.Interrupt, syscall.SIGTERM)
        <-c
}

You may need to run go mod init && go mod tidy if you haven't already done so.

The code sets up the necessary components for the Golang application. It loads the BPF program, attaches it to the specified network interface, and initializes the perf event reader. However, the code to read and process the perf events is yet to be implemented.

That concludes the content for the "Writing the Golang Application" section. Feel free to modify and customize the content according to your needs.

Building and Running the Project

Now that we have implemented the XDP eBPF program in C and the Golang application, let's build and run the project.

Building the XDP eBPF Program

You can skip this step if you have already compiled the dilih_kern.o from the steps above.

Before building the XDP eBPF program, ensure that you have the necessary build tools and dependencies installed on your system. You can refer to the project's README or documentation for the specific requirements.

To build the XDP eBPF program, navigate to the bpf directory and run the following command:

make

This command will compile the C code and generate the dilih_kern.o object file.

Building the Golang Application

To build the Golang application, make sure you are in the root directory of the project. Run the following command:

CGO_ENABLED=0 go build

This command will compile the Golang code and generate an executable binary file. Note: we do not need CGO for our application. We could leave it enabled if we wish, but I like to use CGO_ENABLED=0 when I can as it results in a statically compiled binary that I can easily load into containers.

Running the Go Project

sudo ./dilih

You should start to see a summary of the packets processed on the given interface:

Make sure to run the application with elevated privileges (sudo) to access the necessary resources.

The Golang application will start collecting data from the XDP program and display statistics based on the received perf events.

Cleaning Up
To clean up the project and remove the XDP program from the network interface, run the following command:

sudo make clean

This command will detach the XDP program from the network interface and remove any associated artifacts.

That's it! You have successfully built and run the project. Experiment with different network interfaces and observe the packet drop statistics displayed by the Golang application.

Feel free to explore additional features and modifications to enhance the project further.

Testing and Verifying the XDP eBPF Program

Testing and verifying the functionality of the XDP eBPF program is an essential step to ensure its correctness and effectiveness. In this section, we'll cover some testing techniques and verification methods for the XDP program.

Test Environment Setup

To create a suitable test environment, we'll utilize virtual network interfaces (veth devices) to simulate network traffic and observe the behavior of the XDP program.

Install the iproute2 package if it's not already installed on your system. This package provides the necessary tools to manage network interfaces.

Create a pair of veth devices using the following commands:

sudo ip link add veth0 type veth peer name veth1

This command will create two virtual network interfaces (veth0 and veth1) that are connected to each other.

Set the interfaces up and assign IP addresses to them:

sudo ip link set veth0 up
sudo ip link set veth1 up
sudo ip addr add 10.0.0.1/24 dev veth0
sudo ip addr add 10.0.0.2/24 dev veth1

This will bring up the interfaces and assign IP addresses (10.0.0.1 and 10.0.0.2) to them.

With the veth devices set up, we can proceed to test and verify the XDP eBPF program's functionality.

Packet Drop Verification

One of the primary functionalities of the XDP program is to drop a certain percentage of packets. We can verify this behavior by sending packets between the veth devices and observing the packet drop rate.

Open two terminal windows and navigate to the project directory in both of them.

In the first terminal, run the following command to listen for ICMP echo requests (ping):

sudo tcpdump -i veth1 icmp

In the second terminal, send ICMP echo requests (ping) from veth0 to veth1 using the following command:

sudo ip netns exec veth0 ping 10.0.0.2

Observe the output in the first terminal. You should see the ICMP echo requests being captured.

Analyze the packet capture to verify the packet drop rate. If the XDP program is working correctly, approximately 50% of the ICMP echo requests should be dropped, resulting in a reduced number of captured packets.

By performing packet drop verification tests, you can ensure that the XDP program is functioning as expected and dropping packets according to the specified percentage.

Performance Analysis

In addition to functional verification, it's crucial to analyze the performance impact of the XDP eBPF program. This analysis helps evaluate the efficiency and overhead introduced by the program.

1. Use the provided Golang application to collect performance metrics and statistics from the XDP program. Refer to the "Building and Running the Project" section for instructions on how to run the Golang application.

2. Monitor and observe the average processing time for both passed and dropped packets. The Golang application displays the average processing time in nanoseconds (ns) for each packet type.

   If the average processing time is consistently low, it indicates that the XDP program is performing efficiently and causing minimal processing overhead.

   If the average processing time is significantly high, it may indicate that the XDP program is introducing a considerable processing overhead, which may require optimization or further investigation.

3. Collect data and analyze the performance metrics over an extended period of network traffic to identify any patterns or trends. Look for anomalies or deviations in the processing time that could indicate potential bottlenecks or inefficiencies.

4. Experiment with different packet drop percentages and observe their impact on the average processing time. By varying the drop rate, you can assess the trade-off between packet loss and processing efficiency.

5. Performing performance analysis allows you to gain insights into the impact of the XDP eBPF program on network performance and make informed decisions about its optimization and tuning.

Integration and System Testing
To ensure the proper integration of the XDP eBPF program into the overall system, it's essential to perform integration and system testing. This involves testing the interaction between the XDP program, the network stack, and other components of the system.

Construct a test scenario that closely resembles the production environment in which the XDP program will operate. Consider factors such as network traffic patterns, system load, and the presence of other networking components.

Generate realistic network traffic using tools such as packet generators, traffic simulators, or actual production traffic if available.

Monitor the system's behavior, including packet processing, performance metrics, and system resource utilization. Ensure that the XDP program functions as expected and does not introduce any adverse effects on the system.

Test corner cases and edge conditions to validate the robustness and resilience of the XDP program. This includes scenarios such as high network traffic volumes, unusual packet structures, or unexpected network events.

By conducting integration and system testing, you can ensure that the XDP eBPF program seamlessly integrates into the broader system and operates reliably under various conditions.

Conclusion

In this article, we explored the process of building an XDP eBPF program with C and Golang. We started by understanding the basics of XDP and eBPF, followed by setting up the development environment and writing the XDP eBPF program in C. We then integrated the program with a Golang application to collect and analyze performance metrics.

Throughout the journey, we learned how to compile and load the XDP program, build the Golang application, and leverage the power of eBPF and XDP to manipulate network packets and introduce controlled chaos. We also discussed testing methodologies to ensure the correctness, efficiency, and integration of the XDP program within the system.

The ability to leverage eBPF and XDP opens up a world of possibilities for network programmability, performance optimization, and security enhancements. By harnessing the flexibility and programmability of eBPF, developers can create powerful and efficient networking applications.

We encourage you to explore further possibilities with XDP and eBPF, experiment with different scenarios, and dive deeper into the rich ecosystem of eBPF tools and libraries available. Embrace the power of XDP and eBPF to unlock new horizons in network programming and performance optimization.

Happy coding!

Additional Resources

To further expand your knowledge and explore the world of XDP, eBPF, and network programming, here are some valuable resources:

• The Cilium Project: Cilium is an open-source project that provides networking and security capabilities powered by eBPF. Their documentation and codebase offer in-depth insights into eBPF and its applications. Visit their website at cilium.io for more information.

• The iovisor Project: iovisor is an open-source project that focuses on building tools, libraries, and infrastructure for eBPF-based tracing, monitoring, and networking. Their website at iovisor.org hosts a wealth of resources, including tutorials, documentation, and sample code.

• The BCC (BPF Compiler Collection): BCC is a collection of powerful command-line tools and libraries that leverage eBPF for various tracing and performance analysis tasks. The official GitHub repository at github.com/iovisor/bcc provides extensive documentation and examples to help you dive deep into eBPF.

• eBPF.io: eBPF.io is a community-driven website dedicated to providing resources, tutorials, and news about eBPF. It features articles, case studies, and a curated list of tools and libraries related to eBPF. Explore the website at ebpf.io to stay up-to-date with the latest developments in the eBPF ecosystem.

• Linux Kernel Documentation: The Linux kernel documentation includes a comprehensive section on eBPF and XDP, covering various aspects, including API references, usage examples, and implementation details. Access the documentation at www.kernel.org/doc/html/latest/bpf to gain a deep understanding of the underlying mechanisms.

These resources serve as valuable references and provide opportunities for further learning and exploration. Delve into the world of XDP, eBPF, and network programming, and unlock the full potential of these technologies in your networking projects.

You can also find the entire codebase for this article here: https://github.com/peter-mcconnell/dilih