When I wrote this answer, I was only looking at the title question about < vs. <= in general, not the specific example of a constant `a < 901`

vs. `a <= 900`

. Many compilers always shrink the magnitude of constants by converting between `<`

and `<=`

, e.g. because x86 immediate operand have a shorter 1-byte encoding for -128..127.

For ARM and especially AArch64, being able to encode as an immediate depends on being able to rotate a narrow field into any position in a word. So `cmp w0, #0x00f000`

would be encodeable, while `cmp w0, #0x00effff`

might not be. So the make-it-smaller rule for comparison vs. a compile-time constant doesn't always apply for AArch64.

### < vs. <= in general, including for runtime-variable conditions

In assembly language on most machines, a comparison for `<=`

has the same cost as a comparison for `<`

. This applies whether you're branching on it, booleanizing it to create a 0/1 integer, or using it as a predicate for a branchless select operation (like x86 CMOV). The other answers have only addressed this part of the question.

**But this question is about the C++ operators, the ***input* to the optimizer. Normally they're both equally efficient; the advice from the book sounds totally bogus because compilers can always transform the comparison that they implement in asm. But there is at least one exception where using `<=`

can accidentally create something the compiler can't optimize.

**As a loop condition, there are cases where **`<=`

is *qualitatively* different from `<`

, when it stops the compiler from proving that a loop is not infinite. This can make a big difference, disabling auto-vectorization.

Unsigned overflow is well-defined as base-2 wrap around, unlike signed overflow (UB). Signed loop counters are generally safe from this with compilers that optimize based on signed-overflow UB not happening: `++i <= size`

will always eventually become false. (What Every C Programmer Should Know About Undefined Behavior)

```
void foo(unsigned size) {
unsigned upper_bound = size - 1; // or any calculation that could produce UINT_MAX
for(unsigned i=0 ; i <= upper_bound ; i++)
...
```

**Compilers can only optimize in ways that preserve the (defined and legally observable) behaviour of the C++ source for ***all* possible input values, except ones that lead to undefined behaviour.

(A simple `i <= size`

would create the problem too, but I thought calculating an upper bound was a more realistic example of accidentally introducing the possibility of an infinite loop for an input you don't care about but which the compiler must consider.)

**In this case, **`size=0`

leads to `upper_bound=UINT_MAX`

, and `i <= UINT_MAX`

is always true. So this loop is infinite for `size=0`

, and the compiler has to respect that even though you as the programmer probably never intend to pass size=0. If the compiler can inline this function into a caller where it can prove that size=0 is impossible, then great, it can optimize like it could for `i < size`

.

Asm like `if(!size) skip the loop;`

`do{...}while(--size);`

is one normally-efficient way to optimize a `for( i<size )`

loop, if the actual value of `i`

isn't needed inside the loop (Why are loops always compiled into "do...while" style (tail jump)?).

But that do{}while can't be infinite: if entered with `size==0`

, we get 2^n iterations. (Iterating over all unsigned integers in a for loop C makes it possible to express a loop over all unsigned integers including zero, but it's not easy without a carry flag the way it is in asm.)

**With wraparound of the loop counter being a possibility, modern compilers often just "give up", and don't optimize nearly as aggressively.**

# Example: sum of integers from 1 to n

**Using unsigned **`i <= n`

defeats clang's idiom-recognition that optimizes `sum(1 .. n)`

loops with a closed form based on Gauss's `n * (n+1) / 2`

formula.

```
unsigned sum_1_to_n_finite(unsigned n) {
unsigned total = 0;
for (unsigned i = 0 ; i < n+1 ; ++i)
total += i;
return total;
}
```

x86-64 asm from clang7.0 and gcc8.2 on the Godbolt compiler explorer

```
# clang7.0 -O3 closed-form
cmp edi, -1 # n passed in EDI: x86-64 System V calling convention
je .LBB1_1 # if (n == UINT_MAX) return 0; // C++ loop runs 0 times
# else fall through into the closed-form calc
mov ecx, edi # zero-extend n into RCX
lea eax, [rdi - 1] # n-1
imul rax, rcx # n * (n-1) # 64-bit
shr rax # n * (n-1) / 2
add eax, edi # n + (stuff / 2) = n * (n+1) / 2 # truncated to 32-bit
ret # computed without possible overflow of the product before right shifting
.LBB1_1:
xor eax, eax
ret
```

**But for the naive version, we just get a dumb loop from clang.**

```
unsigned sum_1_to_n_naive(unsigned n) {
unsigned total = 0;
for (unsigned i = 0 ; i<=n ; ++i)
total += i;
return total;
}
```

```
# clang7.0 -O3
sum_1_to_n(unsigned int):
xor ecx, ecx # i = 0
xor eax, eax # retval = 0
.LBB0_1: # do {
add eax, ecx # retval += i
add ecx, 1 # ++1
cmp ecx, edi
jbe .LBB0_1 # } while( i<n );
ret
```

**GCC doesn't use a closed-form either way, so the choice of loop condition doesn't really hurt it**; it auto-vectorizes with SIMD integer addition, running 4 `i`

values in parallel in the elements of an XMM register.

```
# "naive" inner loop
.L3:
add eax, 1 # do {
paddd xmm0, xmm1 # vect_total_4.6, vect_vec_iv_.5
paddd xmm1, xmm2 # vect_vec_iv_.5, tmp114
cmp edx, eax # bnd.1, ivtmp.14 # bound and induction-variable tmp, I think.
ja .L3 #, # }while( n > i )
"finite" inner loop
# before the loop:
# xmm0 = 0 = totals
# xmm1 = {0,1,2,3} = i
# xmm2 = set1_epi32(4)
.L13: # do {
add eax, 1 # i++
paddd xmm0, xmm1 # total[0..3] += i[0..3]
paddd xmm1, xmm2 # i[0..3] += 4
cmp eax, edx
jne .L13 # }while( i != upper_limit );
then horizontal sum xmm0
and peeled cleanup for the last n%3 iterations, or something.
```

It also has a plain scalar loop which I think it uses for very small `n`

, and/or for the infinite loop case.

BTW, both of these loops waste an instruction (and a uop on Sandybridge-family CPUs) on loop overhead. `sub eax,1`

/`jnz`

instead of `add eax,1`

/cmp/jcc would be more efficient. 1 uop instead of 2 (after macro-fusion of sub/jcc or cmp/jcc). The code after both loops writes EAX unconditionally, so it's not using the final value of the loop counter.

which bookyou're referring to. – Jonathon Reinhart Jul 24 '14 at 19:47`<`

is two times faster than typing`<=`

. – Deqing Apr 21 '16 at 0:19