Native C arrays do not get bounds checking. That would require additional instructions and data structures. C is designed for efficiency and leanness, so it doesn't specify features that trade performance for safety.
You can use a tool like valgrind, which runs your program in a kind of emulator and attempts to detect such things as buffer overflows by tracking which bytes are initialized and which aren't. But it's not infallible, for example if the overflowing access happens to perform an otherwise-legal access to another variable.
Under the hood, array indexing is just pointer arithmetic. When you say
arr[ 150 ], you are just adding 150 times the
sizeof one element and adding that to the address of
arr to obtain the address of a particular object. That address is just a number, and it might be nonsense, invalid, or itself an arithmetic overflow. Some of these conditions result in the hardware generating a crash, when it can't find memory to access or detects virus-like activity, but none result in software-generated exceptions because there is no room for a software hook. If you want a safe array, you'll need to build functions around the principle of addition.
By the way, the array in your example isn't even technically of fixed size.
int len = 10; /* variable of type int */
char arr[len]; /* variable-length array */
Using a non-
const object to set the array size is a new feature since C99. You could just as well have
len be a function parameter, user input, etc. This would be better for compile-time analysis:
const int len = 10; /* constant of type int */
char arr[len]; /* constant-length array */
For the sake of completeness: The C standard doesn't specify bounds checking but neither is it prohibited. It falls under the category of undefined behavior, or errors that need not generate error messages, and can have any effect. It is possible to implement safe arrays, various approximations of the feature exist. C does nod in this direction by making it illegal, for example, to take the difference between two arrays in order to find the correct out-of-bounds index to access an arbitrary object A from array B. But the language is very free-form, and if A and B are part of the same memory block from
malloc it is legal. In other words, the more C-specific memory tricks you use, the harder automatic verification becomes even with C-oriented tools.