The Often Misunderstood GEP Instruction

Introduction

This document seeks to dispel the mystery and confusion surrounding LLVM’s GetElementPtr (GEP) instruction. Questions about the wily GEP instruction are probably the most frequently occurring questions once a developer gets down to coding with LLVM. Here we lay out the sources of confusion and show that the GEP instruction is really quite simple.

Address Computation

When people are first confronted with the GEP instruction, they tend to relate it to known concepts from other programming paradigms, most notably C array indexing and field selection. GEP closely resembles C array indexing and field selection, however it is a little different and this leads to the following questions.

What is the first index of the GEP instruction?

Quick answer: The index stepping through the first operand.

The confusion with the first index usually arises from thinking about the GetElementPtr instruction as if it was a C index operator. They aren’t the same. For example, when we write, in “C”:

AType *Foo;
...
X = &Foo->F;

it is natural to think that there is only one index, the selection of the field F. However, in this example, Foo is a pointer. That pointer must be indexed explicitly in LLVM. C, on the other hand, indices through it transparently. To arrive at the same address location as the C code, you would provide the GEP instruction with two index operands. The first operand indexes through the pointer; the second operand indexes the field F of the structure, just as if you wrote:

X = &Foo[0].F;

Sometimes this question gets rephrased as:

Why is it okay to index through the first pointer, but subsequent pointers won’t be dereferenced?

The answer is simply because memory does not have to be accessed to perform the computation. The first operand to the GEP instruction must be a value of a pointer type. The value of the pointer is provided directly to the GEP instruction as an operand without any need for accessing memory. It must, therefore be indexed and requires an index operand. Consider this example:

struct munger_struct {
  int f1;
  int f2;
};
void munge(struct munger_struct *P) {
  P[0].f1 = P[1].f1 + P[2].f2;
}
...
munger_struct Array[3];
...
munge(Array);

In this “C” example, the front end compiler (Clang) will generate three GEP instructions for the three indices through “P” in the assignment statement. The function argument P will be the first operand of each of these GEP instructions. The second operand indexes through that pointer. The third operand will be the field offset into the struct munger_struct type, for either the f1 or f2 field. So, in LLVM assembly the munge function looks like:

void %munge(%struct.munger_struct* %P) {
entry:
  %tmp = getelementptr %struct.munger_struct* %P, i32 1, i32 0
  %tmp = load i32* %tmp
  %tmp6 = getelementptr %struct.munger_struct* %P, i32 2, i32 1
  %tmp7 = load i32* %tmp6
  %tmp8 = add i32 %tmp7, %tmp
  %tmp9 = getelementptr %struct.munger_struct* %P, i32 0, i32 0
  store i32 %tmp8, i32* %tmp9
  ret void
}

In each case the first operand is the pointer through which the GEP instruction starts. The same is true whether the first operand is an argument, allocated memory, or a global variable.

To make this clear, let’s consider a more obtuse example:

%MyVar = uninitialized global i32
...
%idx1 = getelementptr i32* %MyVar, i64 0
%idx2 = getelementptr i32* %MyVar, i64 1
%idx3 = getelementptr i32* %MyVar, i64 2

These GEP instructions are simply making address computations from the base address of MyVar. They compute, as follows (using C syntax):

idx1 = (char*) &MyVar + 0
idx2 = (char*) &MyVar + 4
idx3 = (char*) &MyVar + 8

Since the type i32 is known to be four bytes long, the indices 0, 1 and 2 translate into memory offsets of 0, 4, and 8, respectively. No memory is accessed to make these computations because the address of %MyVar is passed directly to the GEP instructions.

The obtuse part of this example is in the cases of %idx2 and %idx3. They result in the computation of addresses that point to memory past the end of the %MyVar global, which is only one i32 long, not three i32s long. While this is legal in LLVM, it is inadvisable because any load or store with the pointer that results from these GEP instructions would produce undefined results.

Why is the extra 0 index required?

Quick answer: there are no superfluous indices.

This question arises most often when the GEP instruction is applied to a global variable which is always a pointer type. For example, consider this:

%MyStruct = uninitialized global { float*, i32 }
...
%idx = getelementptr { float*, i32 }* %MyStruct, i64 0, i32 1

The GEP above yields an i32* by indexing the i32 typed field of the structure %MyStruct. When people first look at it, they wonder why the i64 0 index is needed. However, a closer inspection of how globals and GEPs work reveals the need. Becoming aware of the following facts will dispel the confusion:

  1. The type of %MyStruct is not { float*, i32 } but rather { float*, i32 }*. That is, %MyStruct is a pointer to a structure containing a pointer to a float and an i32.
  2. Point #1 is evidenced by noticing the type of the first operand of the GEP instruction (%MyStruct) which is { float*, i32 }*.
  3. The first index, i64 0 is required to step over the global variable %MyStruct. Since the first argument to the GEP instruction must always be a value of pointer type, the first index steps through that pointer. A value of 0 means 0 elements offset from that pointer.
  4. The second index, i32 1 selects the second field of the structure (the i32).

What is dereferenced by GEP?

Quick answer: nothing.

The GetElementPtr instruction dereferences nothing. That is, it doesn’t access memory in any way. That’s what the Load and Store instructions are for. GEP is only involved in the computation of addresses. For example, consider this:

%MyVar = uninitialized global { [40 x i32 ]* }
...
%idx = getelementptr { [40 x i32]* }* %MyVar, i64 0, i32 0, i64 0, i64 17

In this example, we have a global variable, %MyVar that is a pointer to a structure containing a pointer to an array of 40 ints. The GEP instruction seems to be accessing the 18th integer of the structure’s array of ints. However, this is actually an illegal GEP instruction. It won’t compile. The reason is that the pointer in the structure must be dereferenced in order to index into the array of 40 ints. Since the GEP instruction never accesses memory, it is illegal.

In order to access the 18th integer in the array, you would need to do the following:

%idx = getelementptr { [40 x i32]* }* %, i64 0, i32 0
%arr = load [40 x i32]** %idx
%idx = getelementptr [40 x i32]* %arr, i64 0, i64 17

In this case, we have to load the pointer in the structure with a load instruction before we can index into the array. If the example was changed to:

%MyVar = uninitialized global { [40 x i32 ] }
...
%idx = getelementptr { [40 x i32] }*, i64 0, i32 0, i64 17

then everything works fine. In this case, the structure does not contain a pointer and the GEP instruction can index through the global variable, into the first field of the structure and access the 18th i32 in the array there.

Why don’t GEP x,0,0,1 and GEP x,1 alias?

Quick Answer: They compute different address locations.

If you look at the first indices in these GEP instructions you find that they are different (0 and 1), therefore the address computation diverges with that index. Consider this example:

%MyVar = global { [10 x i32 ] }
%idx1 = getelementptr { [10 x i32 ] }* %MyVar, i64 0, i32 0, i64 1
%idx2 = getelementptr { [10 x i32 ] }* %MyVar, i64 1

In this example, idx1 computes the address of the second integer in the array that is in the structure in %MyVar, that is MyVar+4. The type of idx1 is i32*. However, idx2 computes the address of the next structure after %MyVar. The type of idx2 is { [10 x i32] }* and its value is equivalent to MyVar + 40 because it indexes past the ten 4-byte integers in MyVar. Obviously, in such a situation, the pointers don’t alias.

Why do GEP x,1,0,0 and GEP x,1 alias?

Quick Answer: They compute the same address location.

These two GEP instructions will compute the same address because indexing through the 0th element does not change the address. However, it does change the type. Consider this example:

%MyVar = global { [10 x i32 ] }
%idx1 = getelementptr { [10 x i32 ] }* %MyVar, i64 1, i32 0, i64 0
%idx2 = getelementptr { [10 x i32 ] }* %MyVar, i64 1

In this example, the value of %idx1 is %MyVar+40 and its type is i32*. The value of %idx2 is also MyVar+40 but its type is { [10 x i32] }*.

Can GEP index into vector elements?

This hasn’t always been forcefully disallowed, though it’s not recommended. It leads to awkward special cases in the optimizers, and fundamental inconsistency in the IR. In the future, it will probably be outright disallowed.

What effect do address spaces have on GEPs?

None, except that the address space qualifier on the first operand pointer type always matches the address space qualifier on the result type.

How is GEP different from ptrtoint, arithmetic, and inttoptr?

It’s very similar; there are only subtle differences.

With ptrtoint, you have to pick an integer type. One approach is to pick i64; this is safe on everything LLVM supports (LLVM internally assumes pointers are never wider than 64 bits in many places), and the optimizer will actually narrow the i64 arithmetic down to the actual pointer size on targets which don’t support 64-bit arithmetic in most cases. However, there are some cases where it doesn’t do this. With GEP you can avoid this problem.

Also, GEP carries additional pointer aliasing rules. It’s invalid to take a GEP from one object, address into a different separately allocated object, and dereference it. IR producers (front-ends) must follow this rule, and consumers (optimizers, specifically alias analysis) benefit from being able to rely on it. See the Rules section for more information.

And, GEP is more concise in common cases.

However, for the underlying integer computation implied, there is no difference.

I’m writing a backend for a target which needs custom lowering for GEP. How do I do this?

You don’t. The integer computation implied by a GEP is target-independent. Typically what you’ll need to do is make your backend pattern-match expressions trees involving ADD, MUL, etc., which are what GEP is lowered into. This has the advantage of letting your code work correctly in more cases.

GEP does use target-dependent parameters for the size and layout of data types, which targets can customize.

If you require support for addressing units which are not 8 bits, you’ll need to fix a lot of code in the backend, with GEP lowering being only a small piece of the overall picture.

How does VLA addressing work with GEPs?

GEPs don’t natively support VLAs. LLVM’s type system is entirely static, and GEP address computations are guided by an LLVM type.

VLA indices can be implemented as linearized indices. For example, an expression like X[a][b][c], must be effectively lowered into a form like X[a*m+b*n+c], so that it appears to the GEP as a single-dimensional array reference.

This means if you want to write an analysis which understands array indices and you want to support VLAs, your code will have to be prepared to reverse-engineer the linearization. One way to solve this problem is to use the ScalarEvolution library, which always presents VLA and non-VLA indexing in the same manner.

Rules

What happens if an array index is out of bounds?

There are two senses in which an array index can be out of bounds.

First, there’s the array type which comes from the (static) type of the first operand to the GEP. Indices greater than the number of elements in the corresponding static array type are valid. There is no problem with out of bounds indices in this sense. Indexing into an array only depends on the size of the array element, not the number of elements.

A common example of how this is used is arrays where the size is not known. It’s common to use array types with zero length to represent these. The fact that the static type says there are zero elements is irrelevant; it’s perfectly valid to compute arbitrary element indices, as the computation only depends on the size of the array element, not the number of elements. Note that zero-sized arrays are not a special case here.

This sense is unconnected with inbounds keyword. The inbounds keyword is designed to describe low-level pointer arithmetic overflow conditions, rather than high-level array indexing rules.

Analysis passes which wish to understand array indexing should not assume that the static array type bounds are respected.

The second sense of being out of bounds is computing an address that’s beyond the actual underlying allocated object.

With the inbounds keyword, the result value of the GEP is undefined if the address is outside the actual underlying allocated object and not the address one-past-the-end.

Without the inbounds keyword, there are no restrictions on computing out-of-bounds addresses. Obviously, performing a load or a store requires an address of allocated and sufficiently aligned memory. But the GEP itself is only concerned with computing addresses.

Can array indices be negative?

Yes. This is basically a special case of array indices being out of bounds.

Can I compare two values computed with GEPs?

Yes. If both addresses are within the same allocated object, or one-past-the-end, you’ll get the comparison result you expect. If either is outside of it, integer arithmetic wrapping may occur, so the comparison may not be meaningful.

Can I do GEP with a different pointer type than the type of the underlying object?

Yes. There are no restrictions on bitcasting a pointer value to an arbitrary pointer type. The types in a GEP serve only to define the parameters for the underlying integer computation. They need not correspond with the actual type of the underlying object.

Furthermore, loads and stores don’t have to use the same types as the type of the underlying object. Types in this context serve only to specify memory size and alignment. Beyond that there are merely a hint to the optimizer indicating how the value will likely be used.

Can I cast an object’s address to integer and add it to null?

You can compute an address that way, but if you use GEP to do the add, you can’t use that pointer to actually access the object, unless the object is managed outside of LLVM.

The underlying integer computation is sufficiently defined; null has a defined value — zero — and you can add whatever value you want to it.

However, it’s invalid to access (load from or store to) an LLVM-aware object with such a pointer. This includes GlobalVariables, Allocas, and objects pointed to by noalias pointers.

If you really need this functionality, you can do the arithmetic with explicit integer instructions, and use inttoptr to convert the result to an address. Most of GEP’s special aliasing rules do not apply to pointers computed from ptrtoint, arithmetic, and inttoptr sequences.

Can I compute the distance between two objects, and add that value to one address to compute the other address?

As with arithmetic on null, you can use GEP to compute an address that way, but you can’t use that pointer to actually access the object if you do, unless the object is managed outside of LLVM.

Also as above, ptrtoint and inttoptr provide an alternative way to do this which do not have this restriction.

Can I do type-based alias analysis on LLVM IR?

You can’t do type-based alias analysis using LLVM’s built-in type system, because LLVM has no restrictions on mixing types in addressing, loads or stores.

LLVM’s type-based alias analysis pass uses metadata to describe a different type system (such as the C type system), and performs type-based aliasing on top of that. Further details are in the language reference.

What happens if a GEP computation overflows?

If the GEP lacks the inbounds keyword, the value is the result from evaluating the implied two’s complement integer computation. However, since there’s no guarantee of where an object will be allocated in the address space, such values have limited meaning.

If the GEP has the inbounds keyword, the result value is undefined (a “trap value”) if the GEP overflows (i.e. wraps around the end of the address space).

As such, there are some ramifications of this for inbounds GEPs: scales implied by array/vector/pointer indices are always known to be “nsw” since they are signed values that are scaled by the element size. These values are also allowed to be negative (e.g. “gep i32 *%P, i32 -1”) but the pointer itself is logically treated as an unsigned value. This means that GEPs have an asymmetric relation between the pointer base (which is treated as unsigned) and the offset applied to it (which is treated as signed). The result of the additions within the offset calculation cannot have signed overflow, but when applied to the base pointer, there can be signed overflow.

How can I tell if my front-end is following the rules?

There is currently no checker for the getelementptr rules. Currently, the only way to do this is to manually check each place in your front-end where GetElementPtr operators are created.

It’s not possible to write a checker which could find all rule violations statically. It would be possible to write a checker which works by instrumenting the code with dynamic checks though. Alternatively, it would be possible to write a static checker which catches a subset of possible problems. However, no such checker exists today.

Rationale

Why is GEP designed this way?

The design of GEP has the following goals, in rough unofficial order of priority:

  • Support C, C-like languages, and languages which can be conceptually lowered into C (this covers a lot).
  • Support optimizations such as those that are common in C compilers. In particular, GEP is a cornerstone of LLVM’s pointer aliasing model.
  • Provide a consistent method for computing addresses so that address computations don’t need to be a part of load and store instructions in the IR.
  • Support non-C-like languages, to the extent that it doesn’t interfere with other goals.
  • Minimize target-specific information in the IR.

Why do struct member indices always use i32?

The specific type i32 is probably just a historical artifact, however it’s wide enough for all practical purposes, so there’s been no need to change it. It doesn’t necessarily imply i32 address arithmetic; it’s just an identifier which identifies a field in a struct. Requiring that all struct indices be the same reduces the range of possibilities for cases where two GEPs are effectively the same but have distinct operand types.

What’s an uglygep?

Some LLVM optimizers operate on GEPs by internally lowering them into more primitive integer expressions, which allows them to be combined with other integer expressions and/or split into multiple separate integer expressions. If they’ve made non-trivial changes, translating back into LLVM IR can involve reverse-engineering the structure of the addressing in order to fit it into the static type of the original first operand. It isn’t always possibly to fully reconstruct this structure; sometimes the underlying addressing doesn’t correspond with the static type at all. In such cases the optimizer instead will emit a GEP with the base pointer casted to a simple address-unit pointer, using the name “uglygep”. This isn’t pretty, but it’s just as valid, and it’s sufficient to preserve the pointer aliasing guarantees that GEP provides.

Summary

In summary, here’s some things to always remember about the GetElementPtr instruction:

  1. The GEP instruction never accesses memory, it only provides pointer computations.
  2. The first operand to the GEP instruction is always a pointer and it must be indexed.
  3. There are no superfluous indices for the GEP instruction.
  4. Trailing zero indices are superfluous for pointer aliasing, but not for the types of the pointers.
  5. Leading zero indices are not superfluous for pointer aliasing nor the types of the pointers.