From the inline-assembly, you can use rdtsc instruction to get 32-bit(least significant part) counter into eax and 32-bit(highest significant part) to edx. If your code is too small, you can check total-approimate cpu-cycles with just eax register. If count is more than max. of 32-bit value, edx increments per max-32-bit value cycle.
std::cin>>max; //loop limit
rdtsc //gets current cpu-clock-counter into eax&edx
temp+=clock();//needed to defy optimization to actually measure something
//even the smartest compiler cannot know what
//the clock would be
rdtsc //gets current cpu-clock-counter into aex&edx
//if your loop takes more than ~2billions of cpu-clocks, use cpu_clk1b and 2b
Output: 74000 cpu-cycles for 1000 iterations and 800000 cpu-cycles for 10000 iterations on my machine. Because clock() is time-consuming.
Cpu-cycle resolution on my machine: ~1000 cycles. Yes, you need more than several thousands of addition/subtraction(fast instructions) to measure it relatively correct.
Assuming cpu working frequency being constant, 1000 cpu-cycles is nearly equal to 1 micro-seconds for a 1GHz cpu. You should warm your cpu up before doing this.