A type confusion issue was addressed with improved checks. This issue is fixed in macOS Big Sur 11.7.5, macOS Ventura 13.3, iOS 16.4 and iPadOS 16.4, iOS 15.7.4 and iPadOS 15.7.4, macOS Monterey 12.6.4. An app may be able to execute arbitrary code with kernel privileges.
The product allocates or initializes a resource such as a pointer, object, or variable using one type, but it later accesses that resource using a type that is incompatible with the original type.
| Name | Vendor | Start Version | End Version |
|---|---|---|---|
| Ipados | Apple | 15.0 (including) | 15.7.4 (excluding) |
| Ipados | Apple | 16.0 (including) | 16.4 (excluding) |
| Iphone_os | Apple | 15.0 (including) | 15.7.4 (excluding) |
| Iphone_os | Apple | 16.0 (including) | 16.4 (excluding) |
| Macos | Apple | 11.0 (including) | 11.7.5 (excluding) |
| Macos | Apple | 12.0.0 (including) | 12.6.4 (excluding) |
| Macos | Apple | 13.0 (including) | 13.3 (excluding) |
When the product accesses the resource using an incompatible type, this could trigger logical errors because the resource does not have expected properties. In languages without memory safety, such as C and C++, type confusion can lead to out-of-bounds memory access. While this weakness is frequently associated with unions when parsing data with many different embedded object types in C, it can be present in any application that can interpret the same variable or memory location in multiple ways. This weakness is not unique to C and C++. For example, errors in PHP applications can be triggered by providing array parameters when scalars are expected, or vice versa. Languages such as Perl, which perform automatic conversion of a variable of one type when it is accessed as if it were another type, can also contain these issues.