47

I'm attempting to obtain full bandwidth in the L1 cache for the following function on Intel processors

float triad(float *x, float *y, float *z, const int n) {
    float k = 3.14159f;
    for(int i=0; i<n; i++) {
        z[i] = x[i] + k*y[i];
    }
}

This is the triad function from STREAM.

I get about 95% of the peak with SandyBridge/IvyBridge processors with this function (using assembly with NASM). However, using Haswell I only achieve 62% of the peak unless I unroll the loop. If I unroll 16 times I get 92%. I don't understand this.

I decided to write my function in assembly using NASM. The main loop in assembly looks like this.

.L2:
    vmovaps         ymm1, [rdi+rax]
    vfmadd231ps     ymm1, ymm2, [rsi+rax]
    vmovaps         [rdx+rax], ymm1
    add             rax, 32
    jne             .L2

It turns out in Agner Fog's Optimizing Assembly manual in examples 12.7-12.11 he does almost the same thing (but for y[i] = y[i] +k*x[i]) for the Pentium M, Core 2, Sandy Bridge, FMA4, and FMA3. I managed to reproduce his code more or less on my own (actually he has a small bug in the FMA3 example when he broadcasts). He gives instruction size counts, fused ops , execution ports in tables for each processor except for FMA4 and FMA3. I have tried to make this table myself for FMA3.

                                 ports
             size   μops-fused   0   1   2   3   4   5   6   7    
vmovaps      5      1                    ½   ½
vfmadd231ps  6      1            ½   ½   ½   ½
vmovaps      5      1                            1           1
add          4      ½                                    ½
jne          2      ½                                    ½
--------------------------------------------------------------
total       22      4            ½   ½   1   1   1   0   1   1

Size refers to the instruction length in bytes. The reason the add and jne instructions have half a μop is they get fused into one macro-op (not to be confused with μop fusion which still uses multiple ports) and only need port 6 and one μop. The vfmadd231ps instruction can use port 0 or port 1. I chose port 0. The load vmovaps can use port 2 or 3. I chose 2 and had vfmadd231ps use port 3.. In order to be consistent with Agner Fog's tables and since I think it makes more sense to say an instruction which can go to different ports equally goes to each one 1/2 of the time, I assigned 1/2 for the ports vmovaps and vmadd231ps can go to.

Based on this table and the fact that all Core2 processors can do four μops every clock cycle it appears this loop should be possible every clock cycle but I have not managed to obtain it. Can somebody please explain to me why I can't get close to the peak bandwidth for this function on Haswell without unrolling? Is this possible without unrolling and if so how can it be done? Let me be clear that I'm really trying to maximize the ILP for this function (I don't only want maximum bandwidth) so that's the reason I don't want to unroll.

Edit: Here is an update since Iwillnotexist Idonotexist showed using IACA that the stores never use port 7. I managed to break the 66% barrier without unrolling and do this in one clock cycle every iteration without unrolling(theoretically). Let's first address the store problem.

Stephen Canon mentioned in at comment that the Address Generation Unit (AGU) in port 7 can only handle simple operations such as [base + offset] and not [base + index]. In the Intel optimization reference manual the only thing I found was a comment on port7 which says "Simple_AGU" with no definition of what simple means. But then Iwillnotexist Idonotexist found in the comments of IACA that this problem was already mentioned six months ago in which an employee at Intel wrote on 03/11/2014:

Port7 AGU can only work on stores with simple memory address (no index register).

Stephen Canon suggests "using the store address as the offset for the load operands." I have tried this like this

vmovaps         ymm1, [rdi + r9 + 32*i]
vfmadd231ps     ymm1, ymm2, [rsi + r9 + 32*i]
vmovaps         [r9 + 32*i], ymm1
add             r9, 32*unroll
cmp             r9, rcx
jne             .L2

This indeed causes the store to use port7. However, it has another problem which is that the the vmadd231ps does not fuse with the load which you can see from IACA. It also needs additionally the cmp instruction which my original function did not. So the store uses one less micro-op but the cmp (or rather then add since the cmp macro fuses with the jne) needs one more. IACA reports a block throughput of 1.5. In practice this only get about 57% of the peak.

But I found a way to get the vmadd231ps instruction to fuse with the load as well. This can only be done using static arrays with addressing [absolute 32-bit address + index] like this. Evgeny Kluev original suggested this.

vmovaps         ymm1, [src1_end + rax]
vfmadd231ps     ymm1, ymm2, [src2_end + rax]
vmovaps         [dst_end + rax], ymm1
add             rax, 32
jl              .L2

Where src1_end, src2_end, and dst_end are the end addresses of static arrays.

This reproduces the table in my question with four fused micro-ops that I expected. If you put this into IACA it reports a block throughput of 1.0. In theory this should do as well as the SSE and AVX versions. In practice it gets about 72% of the peak. That breaks the 66% barrier but it's still a long ways from the 92% I get unrolling 16 times. So on Haswell the only option to get close to the peak is to unroll. This is not necessary on Core2 through Ivy Bridge but it is on Haswell.

End_edit:

Here is the C/C++ Linux code to test this. The NASM code is posted after the C/C++ code. The only thing you have to change is the frequency number. In the line double frequency = 1.3; replace 1.3 with whatever the operating (not nominal) frequency of your processors is (which in case for a i5-4250U with turbo disabled in the BIOS is 1.3 GHz).

Compile with

nasm -f elf64 triad_sse_asm.asm
nasm -f elf64 triad_avx_asm.asm
nasm -f elf64 triad_fma_asm.asm
g++ -m64 -lrt -O3 -mfma  tests.cpp triad_fma_asm.o -o tests_fma
g++ -m64 -lrt -O3 -mavx  tests.cpp triad_avx_asm.o -o tests_avx
g++ -m64 -lrt -O3 -msse2 tests.cpp triad_sse_asm.o -o tests_sse

The C/C++ code

#include <x86intrin.h>
#include <stdio.h>
#include <string.h>
#include <time.h>

#define TIMER_TYPE CLOCK_REALTIME

extern "C" float triad_sse_asm_repeat(float *x, float *y, float *z, const int n, int repeat);
extern "C" float triad_sse_asm_repeat_unroll16(float *x, float *y, float *z, const int n, int repeat);    
extern "C" float triad_avx_asm_repeat(float *x, float *y, float *z, const int n, int repeat);
extern "C" float triad_avx_asm_repeat_unroll16(float *x, float *y, float *z, const int n, int repeat); 
extern "C" float triad_fma_asm_repeat(float *x, float *y, float *z, const int n, int repeat);
extern "C" float triad_fma_asm_repeat_unroll16(float *x, float *y, float *z, const int n, int repeat);

#if (defined(__FMA__))
float triad_fma_repeat(float *x, float *y, float *z, const int n, int repeat) {
    float k = 3.14159f;
    int r;
    for(r=0; r<repeat; r++) {
        int i;
        __m256 k4 = _mm256_set1_ps(k);
        for(i=0; i<n; i+=8) {
            _mm256_store_ps(&z[i], _mm256_fmadd_ps(k4, _mm256_load_ps(&y[i]), _mm256_load_ps(&x[i])));
        }
    }
}
#elif (defined(__AVX__))
float triad_avx_repeat(float *x, float *y, float *z, const int n, int repeat) {
    float k = 3.14159f;
    int r;
    for(r=0; r<repeat; r++) {
        int i;
        __m256 k4 = _mm256_set1_ps(k);
        for(i=0; i<n; i+=8) {
            _mm256_store_ps(&z[i], _mm256_add_ps(_mm256_load_ps(&x[i]), _mm256_mul_ps(k4, _mm256_load_ps(&y[i]))));
        }
    }
}
#else
float triad_sse_repeat(float *x, float *y, float *z, const int n, int repeat) {
    float k = 3.14159f;
    int r;
    for(r=0; r<repeat; r++) {
        int i;
        __m128 k4 = _mm_set1_ps(k);
        for(i=0; i<n; i+=4) {
            _mm_store_ps(&z[i], _mm_add_ps(_mm_load_ps(&x[i]), _mm_mul_ps(k4, _mm_load_ps(&y[i]))));
        }
    }
}
#endif

double time_diff(timespec start, timespec end)
{
    timespec temp;
    if ((end.tv_nsec-start.tv_nsec)<0) {
        temp.tv_sec = end.tv_sec-start.tv_sec-1;
        temp.tv_nsec = 1000000000+end.tv_nsec-start.tv_nsec;
    } else {
        temp.tv_sec = end.tv_sec-start.tv_sec;
        temp.tv_nsec = end.tv_nsec-start.tv_nsec;
    }
    return (double)temp.tv_sec +  (double)temp.tv_nsec*1E-9;
}

int main () {
    int bytes_per_cycle = 0;
    double frequency = 1.3;  //Haswell
    //double frequency = 3.6;  //IB
    //double frequency = 2.66;  //Core2
    #if (defined(__FMA__))
    bytes_per_cycle = 96;
    #elif (defined(__AVX__))
    bytes_per_cycle = 48;
    #else
    bytes_per_cycle = 24;
    #endif
    double peak = frequency*bytes_per_cycle;

    const int n =2048;

    float* z2 = (float*)_mm_malloc(sizeof(float)*n, 64);
    char *mem = (char*)_mm_malloc(1<<18,4096);
    char *a = mem;
    char *b = a+n*sizeof(float);
    char *c = b+n*sizeof(float);

    float *x = (float*)a;
    float *y = (float*)b;
    float *z = (float*)c;

    for(int i=0; i<n; i++) {
        x[i] = 1.0f*i;
        y[i] = 1.0f*i;
        z[i] = 0;
    }
    int repeat = 1000000;
    timespec time1, time2;
    #if (defined(__FMA__))
    triad_fma_repeat(x,y,z2,n,repeat);
    #elif (defined(__AVX__))
    triad_avx_repeat(x,y,z2,n,repeat);
    #else
    triad_sse_repeat(x,y,z2,n,repeat);
    #endif

    while(1) {
        double dtime, rate;

        clock_gettime(TIMER_TYPE, &time1);
        #if (defined(__FMA__))
        triad_fma_asm_repeat(x,y,z,n,repeat);
        #elif (defined(__AVX__))
        triad_avx_asm_repeat(x,y,z,n,repeat);
        #else
        triad_sse_asm_repeat(x,y,z,n,repeat);
        #endif
        clock_gettime(TIMER_TYPE, &time2);
        dtime = time_diff(time1,time2);
        rate = 3.0*1E-9*sizeof(float)*n*repeat/dtime;
        printf("unroll1     rate %6.2f GB/s, efficency %6.2f%%, error %d\n", rate, 100*rate/peak, memcmp(z,z2, sizeof(float)*n));
        clock_gettime(TIMER_TYPE, &time1);
        #if (defined(__FMA__))
        triad_fma_repeat(x,y,z,n,repeat);
        #elif (defined(__AVX__))
        triad_avx_repeat(x,y,z,n,repeat);
        #else
        triad_sse_repeat(x,y,z,n,repeat);
        #endif
        clock_gettime(TIMER_TYPE, &time2);
        dtime = time_diff(time1,time2);
        rate = 3.0*1E-9*sizeof(float)*n*repeat/dtime;
        printf("intrinsic   rate %6.2f GB/s, efficency %6.2f%%, error %d\n", rate, 100*rate/peak, memcmp(z,z2, sizeof(float)*n));
        clock_gettime(TIMER_TYPE, &time1);
        #if (defined(__FMA__))
        triad_fma_asm_repeat_unroll16(x,y,z,n,repeat);
        #elif (defined(__AVX__))
        triad_avx_asm_repeat_unroll16(x,y,z,n,repeat);
        #else
        triad_sse_asm_repeat_unroll16(x,y,z,n,repeat);
        #endif
        clock_gettime(TIMER_TYPE, &time2);
        dtime = time_diff(time1,time2);
        rate = 3.0*1E-9*sizeof(float)*n*repeat/dtime;
        printf("unroll16    rate %6.2f GB/s, efficency %6.2f%%, error %d\n", rate, 100*rate/peak, memcmp(z,z2, sizeof(float)*n));
    }
}

The NASM code using the System V AMD64 ABI.

triad_fma_asm.asm:

global triad_fma_asm_repeat
;RDI x, RSI y, RDX z, RCX n, R8 repeat
;z[i] = y[i] + 3.14159*x[i]
pi: dd 3.14159
;align 16
section .text
    triad_fma_asm_repeat:
    shl             rcx, 2  
    add             rdi, rcx
    add             rsi, rcx
    add             rdx, rcx
    vbroadcastss    ymm2, [rel pi]
    ;neg                rcx 

align 16
.L1:
    mov             rax, rcx
    neg             rax
align 16
.L2:
    vmovaps         ymm1, [rdi+rax]
    vfmadd231ps     ymm1, ymm2, [rsi+rax]
    vmovaps         [rdx+rax], ymm1
    add             rax, 32
    jne             .L2
    sub             r8d, 1
    jnz             .L1
    vzeroupper
    ret

global triad_fma_asm_repeat_unroll16
section .text
    triad_fma_asm_repeat_unroll16:
    shl             rcx, 2
    add             rcx, rdi
    vbroadcastss    ymm2, [rel pi]  
.L1:
    xor             rax, rax
    mov             r9, rdi
    mov             r10, rsi
    mov             r11, rdx
.L2:
    %assign unroll 32
    %assign i 0 
    %rep    unroll
        vmovaps         ymm1, [r9 + 32*i]
        vfmadd231ps     ymm1, ymm2, [r10 + 32*i]
        vmovaps         [r11 + 32*i], ymm1
    %assign i i+1 
    %endrep
    add             r9, 32*unroll
    add             r10, 32*unroll
    add             r11, 32*unroll
    cmp             r9, rcx
    jne             .L2
    sub             r8d, 1
    jnz             .L1
    vzeroupper
    ret

triad_ava_asm.asm:

global triad_avx_asm_repeat
;RDI x, RSI y, RDX z, RCX n, R8 repeat
pi: dd 3.14159
align 16
section .text
    triad_avx_asm_repeat:
    shl             rcx, 2  
    add             rdi, rcx
    add             rsi, rcx
    add             rdx, rcx
    vbroadcastss    ymm2, [rel pi]
    ;neg                rcx 

align 16
.L1:
    mov             rax, rcx
    neg             rax
align 16
.L2:
    vmulps          ymm1, ymm2, [rdi+rax]
    vaddps          ymm1, ymm1, [rsi+rax]
    vmovaps         [rdx+rax], ymm1
    add             rax, 32
    jne             .L2
    sub             r8d, 1
    jnz             .L1
    vzeroupper
    ret

global triad_avx_asm_repeat2
;RDI x, RSI y, RDX z, RCX n, R8 repeat
;pi: dd 3.14159
align 16
section .text
    triad_avx_asm_repeat2:
    shl             rcx, 2  
    vbroadcastss    ymm2, [rel pi]

align 16
.L1:
    xor             rax, rax
align 16
.L2:
    vmulps          ymm1, ymm2, [rdi+rax]
    vaddps          ymm1, ymm1, [rsi+rax]
    vmovaps         [rdx+rax], ymm1
    add             eax, 32
    cmp             eax, ecx
    jne             .L2
    sub             r8d, 1
    jnz             .L1
    vzeroupper
    ret

global triad_avx_asm_repeat_unroll16
align 16
section .text
    triad_avx_asm_repeat_unroll16:
    shl             rcx, 2
    add             rcx, rdi
    vbroadcastss    ymm2, [rel pi]  
align 16
.L1:
    xor             rax, rax
    mov             r9, rdi
    mov             r10, rsi
    mov             r11, rdx
align 16
.L2:
    %assign unroll 16
    %assign i 0 
    %rep    unroll
        vmulps          ymm1, ymm2, [r9 + 32*i]
        vaddps          ymm1, ymm1, [r10 + 32*i]
        vmovaps         [r11 + 32*i], ymm1
    %assign i i+1 
    %endrep
    add             r9, 32*unroll
    add             r10, 32*unroll
    add             r11, 32*unroll
    cmp             r9, rcx
    jne             .L2
    sub             r8d, 1
    jnz             .L1
    vzeroupper
    ret

triad_sse_asm.asm:

global triad_sse_asm_repeat
;RDI x, RSI y, RDX z, RCX n, R8 repeat
pi: dd 3.14159
;align 16
section .text
    triad_sse_asm_repeat:
    shl             rcx, 2  
    add             rdi, rcx
    add             rsi, rcx
    add             rdx, rcx
    movss           xmm2, [rel pi]
    shufps          xmm2, xmm2, 0
    ;neg                rcx 
align 16
.L1:
    mov             rax, rcx
    neg             rax
align 16
.L2:
    movaps          xmm1, [rdi+rax]
    mulps           xmm1, xmm2
    addps           xmm1, [rsi+rax]
    movaps          [rdx+rax], xmm1
    add             rax, 16
    jne             .L2
    sub             r8d, 1
    jnz             .L1
    ret

global triad_sse_asm_repeat2
;RDI x, RSI y, RDX z, RCX n, R8 repeat
;pi: dd 3.14159
;align 16
section .text
    triad_sse_asm_repeat2:
    shl             rcx, 2  
    movss           xmm2, [rel pi]
    shufps          xmm2, xmm2, 0
align 16
.L1:
    xor             rax, rax
align 16
.L2:
    movaps          xmm1, [rdi+rax]
    mulps           xmm1, xmm2
    addps           xmm1, [rsi+rax]
    movaps          [rdx+rax], xmm1
    add             eax, 16
    cmp             eax, ecx
    jne             .L2
    sub             r8d, 1
    jnz             .L1
    ret



global triad_sse_asm_repeat_unroll16
section .text
    triad_sse_asm_repeat_unroll16:
    shl             rcx, 2
    add             rcx, rdi
    movss           xmm2, [rel pi]
    shufps          xmm2, xmm2, 0
.L1:
    xor             rax, rax
    mov             r9, rdi
    mov             r10, rsi
    mov             r11, rdx
.L2:
    %assign unroll 8
    %assign i 0 
    %rep    unroll
        movaps          xmm1, [r9 + 16*i]
        mulps           xmm1, xmm2,
        addps           xmm1, [r10 + 16*i]
        movaps          [r11 + 16*i], xmm1
    %assign i i+1 
    %endrep
    add             r9, 16*unroll
    add             r10, 16*unroll
    add             r11, 16*unroll
    cmp             r9, rcx
    jne             .L2
    sub             r8d, 1
    jnz             .L1
    ret
  • 1
    @rubenvb, it's done in the line double rate = 3.0*1E-9*sizeof(float)*n*repeat/dtime;. The percentage is 100*rate/peak. The peak is frequency*96 which in my case is 1.3*96=124.8 billion bytes/sec. The 96 is 32*2 byte reads + 32*1 byte write. – Z boson Sep 18 '14 at 8:46
  • 1
    I think you should ask Mysticial – phuclv Sep 18 '14 at 9:06
  • 2
    In order for the FMA version to run at 100%, it needs to saturate all 8 ports on every cycle. (0+1 - 2xFMA, 2+3 - 2xload, 7+4, 1xstore, 5 - add, 6 - jmp). Furthermore, you have a total of 6 uops in the unfused domain and 4 uops in the fused domain. Haswell can only retire 4 uops per cycle, but it's not clear whether it's 4 in the fused or unfused domains. Even if we assume the former, Agner Fog said that it's basically impossible to sustain all 8 ports every cycle. – Mysticial Sep 19 '14 at 19:42
  • 3
    You'd probably need someone from Intel to give you a definitive answer. All I'm saying is that I can only find 1 scheduling that could reach 100% (assuming the limit of 4 is for fused uops). But because there are so many ways to schedule it, the processor might not actually find the best one. For example, store needs 237 + 4. It has a choice between 2, 3, or 7. But it MUST pick 7 otherwise it will block a load. Likewise, a fused add/jmp can go into either 0 or 6. But it MUST pick 6 or it will block an FMA... – Mysticial Sep 19 '14 at 19:56
  • 2
    yeah, ;START_MARKER mov ebx, 111 db 0x64, 0x67, 0x90 ;END_MARKER mov ebx, 222 db 0x64, 0x67, 0x90 – Z boson Sep 23 '14 at 19:26
30
+500

IACA Analysis

Using IACA (the Intel Architecture Code Analyzer) reveals that macro-op fusion is indeed occurring, and that it is not the problem. It is Mysticial who is correct: The problem is that the store isn't using Port 7 at all.

IACA reports the following:

Intel(R) Architecture Code Analyzer Version - 2.1
Analyzed File - ../../../tests_fma
Binary Format - 64Bit
Architecture  - HSW
Analysis Type - Throughput

Throughput Analysis Report
--------------------------
Block Throughput: 1.55 Cycles       Throughput Bottleneck: FrontEnd, PORT2_AGU, PORT3_AGU

Port Binding In Cycles Per Iteration:
---------------------------------------------------------------------------------------
|  Port  |  0   -  DV  |  1   |  2   -  D   |  3   -  D   |  4   |  5   |  6   |  7   |
---------------------------------------------------------------------------------------
| Cycles | 0.5    0.0  | 0.5  | 1.5    1.0  | 1.5    1.0  | 1.0  | 0.0  | 1.0  | 0.0  |
---------------------------------------------------------------------------------------

N - port number or number of cycles resource conflict caused delay, DV - Divider pipe (on port 0)
D - Data fetch pipe (on ports 2 and 3), CP - on a critical path
F - Macro Fusion with the previous instruction occurred
* - instruction micro-ops not bound to a port
^ - Micro Fusion happened
# - ESP Tracking sync uop was issued
@ - SSE instruction followed an AVX256 instruction, dozens of cycles penalty is expected
! - instruction not supported, was not accounted in Analysis

| Num Of |                    Ports pressure in cycles                     |    |
|  Uops  |  0  - DV  |  1  |  2  -  D  |  3  -  D  |  4  |  5  |  6  |  7  |    |
---------------------------------------------------------------------------------
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [rdi+rax*1]
|   2    | 0.5       | 0.5 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [rsi+rax*1]
|   2    |           |     | 0.5       | 0.5       | 1.0 |     |     |     | CP | vmovaps ymmword ptr [rdx+rax*1], ymm1
|   1    |           |     |           |           |     |     | 1.0 |     |    | add rax, 0x20
|   0F   |           |     |           |           |     |     |     |     |    | jnz 0xffffffffffffffec
Total Num Of Uops: 6

In particular, the reported block throughput in cycles (1.5) jives very well with an efficiency of 66%.

A post on IACA's own website about this very phenomenon on Tue, 03/11/2014 - 12:39 was met by this reply by an Intel employee on Tue, 03/11/2014 - 23:20:

Port7 AGU can only work on stores with simple memory address (no index register). This is why the above analysis doesn't show port7 utilization.

This firmly settles why Port 7 wasn't being used.

Now, contrast the above with a 32x unrolled loop (it turns out unroll16 shoudl actually be called unroll32):

Intel(R) Architecture Code Analyzer Version - 2.1
Analyzed File - ../../../tests_fma
Binary Format - 64Bit
Architecture  - HSW
Analysis Type - Throughput

Throughput Analysis Report
--------------------------
Block Throughput: 32.00 Cycles       Throughput Bottleneck: PORT2_AGU, Port2_DATA, PORT3_AGU, Port3_DATA, Port4, Port7

Port Binding In Cycles Per Iteration:
---------------------------------------------------------------------------------------
|  Port  |  0   -  DV  |  1   |  2   -  D   |  3   -  D   |  4   |  5   |  6   |  7   |
---------------------------------------------------------------------------------------
| Cycles | 16.0   0.0  | 16.0 | 32.0   32.0 | 32.0   32.0 | 32.0 | 2.0  | 2.0  | 32.0 |
---------------------------------------------------------------------------------------

N - port number or number of cycles resource conflict caused delay, DV - Divider pipe (on port 0)
D - Data fetch pipe (on ports 2 and 3), CP - on a critical path
F - Macro Fusion with the previous instruction occurred
* - instruction micro-ops not bound to a port
^ - Micro Fusion happened
# - ESP Tracking sync uop was issued
@ - SSE instruction followed an AVX256 instruction, dozens of cycles penalty is expected
! - instruction not supported, was not accounted in Analysis

| Num Of |                    Ports pressure in cycles                     |    |
|  Uops  |  0  - DV  |  1  |  2  -  D  |  3  -  D  |  4  |  5  |  6  |  7  |    |
---------------------------------------------------------------------------------
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x20]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x20]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x20], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x40]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x40]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x40], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x60]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x60]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x60], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x80]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x80]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x80], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0xa0]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0xa0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0xa0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0xc0]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0xc0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0xc0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0xe0]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0xe0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0xe0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x100]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x100]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x100], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x120]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x120]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x120], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x140]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x140]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x140], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x160]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x160]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x160], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x180]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x180]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x180], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x1a0]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x1a0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x1a0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x1c0]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x1c0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x1c0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x1e0]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x1e0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x1e0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x200]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x200]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x200], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x220]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x220]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x220], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x240]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x240]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x240], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x260]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x260]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x260], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x280]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x280]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x280], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x2a0]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x2a0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x2a0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x2c0]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x2c0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x2c0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x2e0]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x2e0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x2e0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x300]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x300]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x300], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x320]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x320]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x320], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x340]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x340]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x340], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x360]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x360]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x360], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x380]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x380]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x380], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x3a0]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x3a0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x3a0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x3c0]
|   2^   | 1.0       |     |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x3c0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x3c0], ymm1
|   1    |           |     | 1.0   1.0 |           |     |     |     |     | CP | vmovaps ymm1, ymmword ptr [r9+0x3e0]
|   2^   |           | 1.0 |           | 1.0   1.0 |     |     |     |     | CP | vfmadd231ps ymm1, ymm2, ymmword ptr [r10+0x3e0]
|   2^   |           |     |           |           | 1.0 |     |     | 1.0 | CP | vmovaps ymmword ptr [r11+0x3e0], ymm1
|   1    |           |     |           |           |     | 1.0 |     |     |    | add r9, 0x400
|   1    |           |     |           |           |     |     | 1.0 |     |    | add r10, 0x400
|   1    |           |     |           |           |     | 1.0 |     |     |    | add r11, 0x400
|   1    |           |     |           |           |     |     | 1.0 |     |    | cmp r9, rcx
|   0F   |           |     |           |           |     |     |     |     |    | jnz 0xfffffffffffffcaf
Total Num Of Uops: 164

We see here micro-fusion and correct scheduling of the store to Port 7.

Manual Analysis (see edit above)

I can now answer the second of your questions: Is this possible without unrolling and if so how can it be done?. The answer is no.

I padded the arrays x, y and z to the left and right with plenty of buffer for the below experiment, and changed the inner loop to the following:

.L2:
vmovaps         ymm1, [rdi+rax] ; 1L
vmovaps         ymm0, [rsi+rax] ; 2L
vmovaps         [rdx+rax], ymm2 ; S1
add             rax, 32         ; ADD
jne             .L2             ; JMP

This intentionally does not use FMA (only loads and stores) and all load/store instructions have no dependencies, since there should therefore be no hazards whatever preventing their issue into any execution ports.

I then tested every single permutation of the first and second loads (1L and 2L), the store (S1) and the add (A) while leaving the conditional jump (J) at the end, and for each of these I tested every possible combination of offsets of x, y and z by 0 or -32 bytes (to correct for the fact that reordering the add rax, 32 before one of the r+r indexes would cause the load or store to target the wrong address). The loop was aligned to 32 bytes. The tests were run on a 2.4GHz i7-4700MQ with TurboBoost disabled by means of echo '0' > /sys/devices/system/cpu/cpufreq/boost under Linux, and using 2.4 for the frequency constant. Here are the efficiency results (maximum of 24):

Cases: 0           1           2           3           4           5           6           7
       L1  L2  S   L1  L2  S   L1  L2  S   L1  L2  S   L1  L2  S   L1  L2  S   L1  L2  S   L1  L2  S   
       -0  -0  -0  -0  -0  -32 -0  -32 -0  -0  -32 -32 -32 -0  -0  -32 -0  -32 -32 -32 -0  -32 -32 -32
       ________________________________________________________________________________________________
12SAJ: 65.34%      65.34%      49.63%      65.07%      49.70%      65.05%      49.22%      65.07%
12ASJ: 48.59%      64.48%      48.74%      49.69%      48.75%      49.69%      48.99%      48.60%
1A2SJ: 49.69%      64.77%      48.67%      64.06%      49.69%      49.69%      48.94%      49.69%
1AS2J: 48.61%      64.66%      48.73%      49.71%      48.77%      49.69%      49.05%      48.74%
1S2AJ: 49.66%      65.13%      49.49%      49.66%      48.96%      64.82%      49.02%      49.66%
1SA2J: 64.44%      64.69%      49.69%      64.34%      49.69%      64.41%      48.75%      64.14%
21SAJ: 65.33%*     65.34%      49.70%      65.06%      49.62%      65.07%      49.22%      65.04%
21ASJ: Hypothetically =12ASJ
2A1SJ: Hypothetically =1A2SJ
2AS1J: Hypothetically =1AS2J
2S1AJ: Hypothetically =1S2AJ
2SA1J: Hypothetically =1SA2J
S21AJ: 48.91%      65.19%      49.04%      49.72%      49.12%      49.63%      49.21%      48.95%
S2A1J: Hypothetically =S1A2J
SA21J: Hypothetically =SA12J
SA12J: 64.69%      64.93%      49.70%      64.66%      49.69%      64.27%      48.71%      64.56%
S12AJ: 48.90%      65.20%      49.12%      49.63%      49.03%      49.70%      49.21%*     48.94%
S1A2J: 49.69%      64.74%      48.65%      64.48%      49.43%      49.69%      48.66%      49.69%
A2S1J: Hypothetically =A1S2J
A21SJ: Hypothetically =A12SJ
A12SJ: 64.62%      64.45%      49.69%      64.57%      49.69%      64.45%      48.58%      63.99%
A1S2J: 49.72%      64.69%      49.72%      49.72%      48.67%      64.46%      48.95%      49.72%
AS21J: Hypothetically =AS21J
AS12J: 48.71%      64.53%      48.76%      49.69%      48.76%      49.74%      48.93%      48.69%

We can notice a few things from the table:

  • Several plateaux of results, but two main ones only: Just under 50% and around 65%.
  • L1 and L2 can permute freely between each other without affecting the result.
  • Offsetting the accesses by -32 bytes can change efficiency.
  • The patterns we are interested in (Load 1, Load 2, Store 1 and Jump with the Add anywhere around them and the -32 offsets properly applied) are all the same, and all in the higher plateau:
    • 12SAJ Case 0 (No offsets applied), with efficiency 65.34% (the highest)
    • 12ASJ Case 1 (S-32), with efficiency 64.48%
    • 1A2SJ Case 3 (2L-32, S-32), with efficiency 64.06%
    • A12SJ Case 7 (1L-32, 2L-32, S-32), with efficiency 63.99%
  • There always exists at least one "case" for every permutation that allows execution at the higher plateau of efficiency. In particular, Case 1 (where S-32) seems to guarantee this.
  • Cases 2, 4 and 6 guarantee execution at the lower plateau. They have in common that either or both of the loads are offset by -32 while the store isn't.
  • For cases 0, 3, 5 and 7, it depends on the permutation.

Whence we may draw at least a few conclusions:

  • Execution ports 2 and 3 really don't care which load address they generate and load from.
  • Macro-op fusion of the add and jmp appears unimpacted by any permutation of the instructions (in particular under Case 1 offsetting), leading me to believe that @Evgeny Kluev's conclusion is incorrect: The distance of the add from the jne does not appear to impact their fusion. I'm reasonably certain now that the Haswell ROB handles this correctly.
    • What Evgeny was seeing (Going from 12SAJ with efficiency 65% to the others with efficiency 49% within Case 0) was an effect due solely to the value of the addresses loaded and stored from, and not due to an inability of the core to macro-fuse the add and branch.
    • Further, macro-op fusion must be occurring at least some of the time, since the average loop time is 1.5 CC. If macro-op fusion did not occur this would be 2CC minimum.
  • Having tested all valid and invalid permutations of instructions within the not-unrolled loop, we've seen nothing higher than 65.34%. This answers empirically with a "no" the question of whether it is possible to use the full bandwidth without unrolling.

I will hypothesize several possible explanations:

  • We're seeing some wierd perversion due to the value of the addresses relative to each other.
    • If so then there would exist a set of offsets of x, y and z that would allow maximum throughput. Quick random tests on my part seem not to support this.
  • We're seeing the loop run in one-two-step mode; The loop iterations alternate running in one clock cycle, then two.

    • This could be macro-op fusion being affected by the decoders. From Agner Fog:

      Fuseable arithmetic/logic instructions cannot be decoded in the last of the four decoders on Sandy Bridge and Ivy Bridge processors. I have not tested whether this also applies to the Haswell.

    • Alternately, every other clock cycle an instruction is issued to the "wrong" port, blocking the next iteration for one extra clock cycle. Such a situation would be self-correcting in the next clock cycle but would remain oscillatory.
      • If somebody has access to the Intel performance counters, he should look at the events UOPS_EXECUTED_PORT.PORT_[0-7]. If oscillation is not occuring, all ports that are used will be pegged equally during the relevant stretch of time; Else if oscillation is occuring, there will be a 50% split. Especially important is to look at the ports Mystical pointed out (0, 1, 6 and 7).

And here's what I think is not happening:

  • I don't believe that the fused arithmetic+branch uop is blocking execution by going to port 0, since predicted-taken branches are sent exclusively to port 6 (see Agner Fog's Instruction Tables under Haswell -> Control transfer instructions). After a few iterations of the loop above, the branch predictor will learn that this branch is a loop and always predict as taken.

I believe this is a problem that will be solved with Intel's performance counters.

  • 3
    What was the difference between rdx and other base registers (rsi, rdi) in your tests? In case it was a multiple of 4096, isn't it possible to explain all the results close to 49% by false sharing? (See "L1 memory bandwidth: 50% drop in efficiency..." for details). Also it should be noted that macro-fused instructions must be adjacent in the instruction stream (see section 3.4.2.2 of Intel Optimization manual, also mentioned in Agner's manuals). – Evgeny Kluev Sep 22 '14 at 11:35
  • 2
    @Zboson: not decided yet. I hope we'll find something with help of performance counters. Or may be (with a bit of luck) your question attracts attention of somebody who knows definite answer. – Evgeny Kluev Sep 22 '14 at 12:37
  • 6
    "why isn't port 7 used" is easy to answer: port 7 can only handle "simple" AGU operations (base + immediate offset, IIRC). It can't do base + register offset. You can get around this by using the store address as the offset for the load operands. – Stephen Canon Sep 23 '14 at 12:56
  • 3
    Regarding the various uop limits: You can execute a uop on all 8 ports during a single cycle if appropriate uops are in the 192 entry ROB (reorder buffer) and all dependencies are satisfied. But there is a front end limit of 4 (unfused) uops per cycle that can enter the the ROB. This applies even if the uops are coming from the tiny loop buffer or the ~1000 entry decoded uop buffer. There is an additional back end limit of 4 (fused) uops that can be retired per cycle. As a result, sustained throughput cannot exceed 4 uops per cycle. Unrolling loops helps iff it gets under these limits. – Nathan Kurz Sep 30 '14 at 3:40
  • 3
    Missed the edit window on a mistake: the decoded instruction buffer stores fused uops, so everything coming from it should be counted in the fused domain. Good diagram with per cycle limits here: pc.watch.impress.co.jp/video/pcw/docs/601/161/p21.pdf – Nathan Kurz Sep 30 '14 at 6:25

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