I did not know that gcc and the java jit were capable of recognizing that a sequence of SHIFT and OR operators can be reduced to a ROTATE instruction, very interesting.
The g++ compiler unrolls your loops and uses
SHIFT immediate and
ROTATE immediate instructions (since you shift and rotate by constant values).
Here's the six instruction sequence that is repeated in the TimeShift loop unroll case:
movq %rax, %rbx
salq $13, %rbx
leaq (%rbp,%rbx), %rbx
movq %rdi, %rbp
sarq $27, %rbp
xorq %rbx, %rdx
Here's the six instruction sequence that is repeated in the TimeRotate loop unroll case:
movq %rdx, %rbx
rorq $45, %rbx
leaq (%rbp,%rbx), %rbx
movq %r8, %rbp
rorq $49, %rbp
xorq %rbx, %r9
They differ mainly in the use of salq/sarq for
SHIFT and rorq for
ROTATE so you are correct in wondering why the timing differs.
The answer lies deep in the micro-architecture of Sandy Bridge (your Core i5 processor) and is found in INTEL® 64 and IA-32 Processor Architectures Optimization Reference Manual
The latest is
Order Number: 248966-026 April 2012
SHIFT instruction has 1 cycle latency whether you use the
by 1 opcode or
by immediate. It can dispatch from either
Port 0 or
Port 1 and for this reason has a 0.5 cycle throughput - the processor can dispatch and retire two
SHIFT immediate instructions per cycle. The
ROTATE instruction needs three micro-ops if the results of the condition flags are needed (they aren't in the code generated by gcc) and two micro-ops if not (so two micro-ops in your case). The
ROTATE instruction, however, can only be dispatched from
Port 1 and therefore has a 1 cycle throughput - the processor can dispatch and retire only one
ROTATE immediate per cycle.
I've copied the relevant image and section below.
22.214.171.124 Bitwise Rotation
Bitwise rotation can choose between rotate with count specified in the CL register, an
immediate constant and by 1 bit. Generally, The rotate by immediate and rotate by
register instructions are slower than rotate by 1 bit. The rotate by 1 instruction has
the same latency as a shift.
Assembly/Compiler Coding Rule 35. (ML impact, L generality) Avoid ROTATE
by register or ROTATE by immediate instructions. If possible, replace with a
ROTATE by 1 instruction.
In Intel microarchitecture code name Sandy Bridge, ROL/ROR by immediate has 1-
cycle throughput, SHLD/SHRD using the same register as source and destination by
an immediate constant has 1-cycle latency with 0.5 cycle throughput. The “ROL/ROR
reg, imm8” instruction has two micro-ops with the latency of 1-cycle for the rotate
register result and 2-cycles for the flags, if used.
In Intel microarchitecture code name Ivy Bridge, The “ROL/ROR reg, imm8” instruction with immediate greater than 1, is one micro-op with one-cycle latency when the
overflow flag result is used. When the immediate is one, dependency on the overflow
flag result of ROL/ROR by a subsequent instruction will see the ROL/ROR instruction
with two-cycle latency.
126.96.36.199 Execution Units and Issue Ports
At each cycle, the core may dispatch µops to one or more of four issue ports. At the
microarchitecture level, store operations are further divided into two parts: store
data and store address operations. The four ports through which μops are dispatched
to execution units and to load and store operations are shown in Figure 2-6. Some
ports can dispatch two µops per clock. Those execution units are marked Double
Port 0. In the first half of the cycle, port 0 can dispatch either one floating-point
move µop (a floating-point stack move, floating-point exchange or floating-point
store data) or one arithmetic logical unit (ALU) µop (arithmetic, logic, branch or store
data). In the second half of the cycle, it can dispatch one similar ALU µop.
Port 1. In the first half of the cycle, port 1 can dispatch either one floating-point
execution (all floating-point operations except moves, all SIMD operations) µop or
one normal-speed integer (multiply, shift and rotate) µop or one ALU (arithmetic)
µop. In the second half of the cycle, it can dispatch one similar ALU µop.
Port 2. This port supports the dispatch of one load operation per cycle.
Port 3. This port supports the dispatch of one store address operation per cycle.
The total issue bandwidth can range from zero to six µops per cycle. Each pipeline
contains several execution units. The µops are dispatched to the pipeline that corresponds to the correct type of operation. For example, an integer arithmetic logic unit
and the floating-point execution units (adder, multiplier, and divider) can share a