Skip to content

VDBPSADBW

Henk-Jan Lebbink edited this page Jun 5, 2018 · 14 revisions

VDBPSADBW — Double Block Packed Sum-Absolute-Differences (SAD) on Unsigned Bytes

Opcode/ Instruction Op / En 64/32 bit Mode Support CPUID Feature Flag Description
EVEX.NDS.128.66.0F3A.W0 42 /r ib VDBPSADBW xmm1 {k1}{z}, xmm2, xmm3/m128, imm8 A V/V AVX512VL AVX512BW Compute packed SAD word results of unsigned bytes in dword block from xmm2 with unsigned bytes of dword blocks transformed from xmm3/m128 using the shuffle controls in imm8. Results are written to xmm1 under the writemask k1.
EVEX.NDS.256.66.0F3A.W0 42 /r ib VDBPSADBW ymm1 {k1}{z}, ymm2, ymm3/m256, imm8 A V/V AVX512VL AVX512BW Compute packed SAD word results of unsigned bytes in dword block from ymm2 with unsigned bytes of dword blocks transformed from ymm3/m256 using the shuffle controls in imm8. Results are written to ymm1 under the writemask k1.
EVEX.NDS.512.66.0F3A.W0 42 /r ib VDBPSADBW zmm1 {k1}{z}, zmm2, zmm3/m512, imm8 A V/V AVX512BW Compute packed SAD word results of unsigned bytes in dword block from zmm2 with unsigned bytes of dword blocks transformed from zmm3/m512 using the shuffle controls in imm8. Results are written to zmm1 under the writemask k1.

Instruction Operand Encoding

Op/En Tuple Type Operand 1 Operand 2 Operand 3 Operand 4
A Full Mem ModRM:reg (w) EVEX.vvvv ModRM:r/m (r) Imm8

Description

Compute packed SAD (sum of absolute differences) word results of unsigned bytes from two 32-bit dword elements. Packed SAD word results are calculated in multiples of qword superblocks, producing 4 SAD word results in each 64-bit superblock of the destination register.

Within each super block of packed word results, the SAD results from two 32-bit dword elements are calculated as follows:

  • The lower two word results are calculated each from the SAD operation between a sliding dword element within a qword superblock from an intermediate vector with a stationary dword element in the corresponding qword superblock of the first source operand. The intermediate vector, see “Tmp1” in Figure 5-8, is constructed from the second source operand the imm8 byte as shuffle control to select dword elements within a 128-bit lane of the second source operand. The two sliding dword elements in a qword superblock of Tmp1 are located at byte offset 0 and 1 within the superblock, respectively. The stationary dword element in the qword superblock from the first source operand is located at byte offset 0.

  • The next two word results are calculated each from the SAD operation between a sliding dword element within a qword superblock from the intermediate vector Tmp1 with a second stationary dword element in the corresponding qword superblock of the first source operand. The two sliding dword elements in a qword superblock of Tmp1 are located at byte offset 2and 3 within the superblock, respectively. The stationary dword element in the qword superblock from the first source operand is located at byte offset 4.

  • The intermediate vector is constructed in 128-bits lanes. Within each 128-bit lane, each dword element of the intermediate vector is selected by a two-bit field within the imm8 byte on the corresponding 128-bits of the second source operand. The imm8 byte serves as dword shuffle control within each 128-bit lanes of the inter- mediate vector and the second source operand, similarly to PSHUFD.

The first source operand is a ZMM/YMM/XMM register. The second source operand is a ZMM/YMM/XMM register, or a 512/256/128-bit memory location. The destination operand is conditionally updated based on writemask k1 at 16-bit word granularity.

128-bit Lane of Src2 DW3 DW2 DW1 DW0 127+128*n 95+128*n 63+128*n 31+128*n 128*n imm8 shuffle control 7 5 3 1 0 00B: DW0 01B: DW1 10B: DW2 11B: DW3 127+128*n 95+128*n 63+128*n 31+128*n 128*n 128-bit Lane of Tmp1 Tmp1 qword superblock 55 47 39 31 24 39 31 23 15 8 Tmp1 sliding dword Src1 stationary dword 1 63 55 47 39 32 _ abs _ abs _ abs _ abs Tmp1 sliding dword Src1 stationary dword 0 31 23 15 7 0 _ abs _ abs _ abs _ abs + 47 39 31 23 16 Tmp1 sliding dword Src1 stationary dword 1 63 55 47 39 32 _ abs _ abs _ abs _ abs + 31 23 15 31 23 15 7 7 0 0 Tmp1 sliding dword Src1 stationary dword 0 _ abs _ abs _ abs _ abs Destination qword superblock 63 + 47 31 15 + 0
DW3 DW2 DW1 DW0
01B: DW1 10B: DW2 11B: DW3 31+128*n 128*n 23 15 8 Tmp1 sliding dword Src1 stationary dword 0 15 7 0 _ abs _ abs 31 23 15 31 23 15 7 7 0 0 Tmp1 sliding dword Src1 stationary dword 0 _ abs _ abs _ abs _ abs 15 + 0
Tmp1 sliding dword Src1 stationary dword 0
Tmp1 sliding dword Src1 stationary dword 0 23 15 23 15 7 7 0 0 Tmp1 sliding dword Src1 stationary dword 0 _ abs _ abs _ abs + 0
55 47 39 Src1 stationary dword 1 32 31 _ abs 47 39 31 23 16 Tmp1 sliding dword Src1 stationary dword 1 63 55 47 39 32 _ abs _ abs _ abs _ abs + 47 31 23 15 7 Src1 stationary dword 0 0 23 15 23 15 7 7 0 0 Tmp1 sliding dword Src1 stationary dword 0 _ abs _ abs _ abs + 0
63 55 47 39 32 _ _ _ _ Src1 stationary dword 0 23 15 23 15 7 7 0 0 Tmp1 sliding dword Src1 stationary dword 0 _ abs _ abs _ abs + 0
23 15 23 15 7 7 0 0 Tmp1 sliding dword Src1 stationary dword 0 _ abs _ abs _ abs + 0
55 47 39 Tmp1 sliding dword Src1 stationary dword 1 32 31 15 Tmp1 sliding dword Src1 stationary dword 0
23 15 7 0 Src1 stationary dword 0
_ _ _ _ Src1 stationary dword 0

Figure 5-8. 64-bit Super Block of SAD Operation in VDBPSADBW

Operation

VDBPSADBW (EVEX encoded versions)

(KL, VL) = (8, 128), (16, 256), (32, 512)
Selection of quadruplets:
FOR I = 0 to VL step 128
    TMP1[I+31:I] ← select (SRC2[I+127: I], imm8[1:0])
    TMP1[I+63: I+32] ← select (SRC2[I+127: I], imm8[3:2])
    TMP1[I+95: I+64] ← select (SRC2[I+127: I], imm8[5:4])
    TMP1[I+127: I+96]← select (SRC2[I+127: I], imm8[7:6])
END FOR
SAD of quadruplets:
FOR I =0 to VL step 64
    TMP_DEST[I+15:I] ← ABS(SRC1[I+7: I] - TMP1[I+7: I]) +
        ABS(SRC1[I+15: I+8]- TMP1[I+15: I+8]) +
        ABS(SRC1[I+23: I+16]- TMP1[I+23: I+16]) +
        ABS(SRC1[I+31: I+24]- TMP1[I+31: I+24]) 
    TMP_DEST[I+31: I+16] ←ABS(SRC1[I+7: I] - TMP1[I+15: I+8]) +
        ABS(SRC1[I+15: I+8]- TMP1[I+23: I+16]) +
        ABS(SRC1[I+23: I+16]- TMP1[I+31: I+24]) +
        ABS(SRC1[I+31: I+24]- TMP1[I+39: I+32])
    TMP_DEST[I+47: I+32] ←ABS(SRC1[I+39: I+32] - TMP1[I+23: I+16]) +
        ABS(SRC1[I+47: I+40]- TMP1[I+31: I+24]) +
        ABS(SRC1[I+55: I+48]- TMP1[I+39: I+32]) +
        ABS(SRC1[I+63: I+56]- TMP1[I+47: I+40]) 
    TMP_DEST[I+63: I+48] ←ABS(SRC1[I+39: I+32] - TMP1[I+31: I+24]) +
        ABS(SRC1[I+47: I+40] - TMP1[I+39: I+32]) +
        ABS(SRC1[I+55: I+48] - TMP1[I+47: I+40]) +
        ABS(SRC1[I+63: I+56] - TMP1[I+55: I+48])
ENDFOR
FOR j0 TO KL-1
    ij * 16
    IF k1[j] OR *no writemask*
        THEN DEST[i+15:i] ← TMP_DEST[i+15:i]
        ELSE 
            IF *merging-masking*
                            ; merging-masking
                THEN *DEST[i+15:i] remains unchanged*
                ELSE 
                            ; zeroing-masking
                    DEST[i+15:i] ← 0
            FI
    FI;
ENDFOR
DEST[MAXVL-1:VL] ← 0

Intel C/C++ Compiler Intrinsic Equivalent

VDBPSADBW __m512i _mm512_dbsad_epu8(__m512i a, __m512i b);
VDBPSADBW __m512i _mm512_mask_dbsad_epu8(__m512i s, __mmask32 m, __m512i a, __m512i b);
VDBPSADBW __m512i _mm512_maskz_dbsad_epu8(__mmask32 m, __m512i a, __m512i b);
VDBPSADBW __m256i _mm256_dbsad_epu8(__m256i a, __m256i b);
VDBPSADBW __m256i _mm256_mask_dbsad_epu8(__m256i s, __mmask16 m, __m256i a, __m256i b);
VDBPSADBW __m256i _mm256_maskz_dbsad_epu8(__mmask16 m, __m256i a, __m256i b);
VDBPSADBW __m128i _mm_dbsad_epu8(__m128i a, __m128i b);
VDBPSADBW __m128i _mm_mask_dbsad_epu8(__m128i s, __mmask8 m, __m128i a, __m128i b);
VDBPSADBW __m128i _mm_maskz_dbsad_epu8(__mmask8 m, __m128i a, __m128i b);

SIMD Floating-Point Exceptions

None

Other Exceptions

See Exceptions Type E4NF.nb.


Source: Intel® Architecture Software Developer's Manual (May 2018)
Generated: 5-6-2018

Clone this wiki locally