PADDSB, PADDSWs (Intel x86/64 assembly instruction)

모두의 코드
PADDSB, PADDSWs (Intel x86/64 assembly instruction)

작성일 : 2020-09-01 이 글은 756 번 읽혔습니다.

PADDSB, PADDSW

Add Packed Signed Integers with Signed Saturation

참고 사항

아래 표를 해석하는 방법은 x86-64 명령어 레퍼런스 읽는 법 글을 참조하시기 바랍니다.

Opcode/ Instruction	Op/ En	64/32 bit Mode Support	CPUID Feature Flag	Description
`0F EC /r\footnote{1}` PADDSB mm mm/m64	RM	V/V	MMX	Add packed signed byte integers from mm/m64 and mm and saturate the results.
`66 0F EC /r` PADDSB xmm1 xmm2/m128	RM	V/V	SSE2	Add packed signed byte integers from xmm2/m128 and xmm1 saturate the results.
`0F ED /r\footnote{1}` PADDSW mm mm/m64	RM	V/V	MMX	Add packed signed word integers from mm/m64 and mm and saturate the results.
`66 0F ED /r` PADDSW xmm1 xmm2/m128	RM	V/V	SSE2	Add packed signed word integers from xmm2/m128 and xmm1 and saturate the results.
`VEX.NDS.128.66.0F.WIG EC /r` VPADDSB xmm1 xmm2 xmm3/m128	RVM	V/V	AVX	Add packed signed byte integers from xmm3/m128 and xmm2 saturate the results.
`VEX.NDS.128.66.0F.WIG ED /r` VPADDSW xmm1 xmm2 xmm3/m128	RVM	V/V	AVX	Add packed signed word integers from xmm3/m128 and xmm2 and saturate the results.
`VEX.NDS.256.66.0F.WIG EC /r` VPADDSB ymm1 ymm2 ymm3/m256	RVM	V/V	AVX2	Add packed signed byte integers from ymm2, and ymm3/m256 and store the saturated results in ymm1.
`VEX.NDS.256.66.0F.WIG ED /r` VPADDSW ymm1 ymm2 ymm3/m256	RVM	V/V	AVX2	Add packed signed word integers from ymm2, and ymm3/m256 and store the saturated results in ymm1.
`EVEX.NDS.128.66.0F.WIG EC /r` VPADDSB xmm1 {k1}{z} xmm2 xmm3/m128	FVM	V/V	AVX512VL AVX512BW	Add packed signed byte integers from xmm2, and xmm3/m128 and store the saturated results in xmm1 under writemask k1.
`EVEX.NDS.256.66.0F.WIG EC /r` VPADDSB ymm1 {k1}{z} ymm2 ymm3/m256	FVM	V/V	AVX512VL AVX512BW	Add packed signed byte integers from ymm2, and ymm3/m256 and store the saturated results in ymm1 under writemask k1.
`EVEX.NDS.512.66.0F.WIG EC /r` VPADDSB zmm1 {k1}{z} zmm2 zmm3/m512	FVM	V/V	AVX512BW	Add packed signed byte integers from zmm2, and zmm3/m512 and store the saturated results in zmm1 under writemask k1.
`EVEX.NDS.128.66.0F.WIG ED /r` VPADDSW xmm1 {k1}{z} xmm2 xmm3/m128	FVM	V/V	AVX512VL AVX512BW	Add packed signed word integers from xmm2, and xmm3/m128 and store the saturated results in xmm1 under writemask k1.
`EVEX.NDS.256.66.0F.WIG ED /r` VPADDSW ymm1 {k1}{z} ymm2 ymm3/m256	FVM	V/V	AVX512VL AVX512BW	Add packed signed word integers from ymm2, and ymm3/m256 and store the saturated results in ymm1 under writemask k1.
`EVEX.NDS.512.66.0F.WIG ED /r` VPADDSW zmm1 {k1}{z} zmm2 zmm3/m512	FVM	V/V	AVX512BW	Add packed signed word integers from zmm2, and zmm3/m512 and store the saturated results in zmm1 under writemask k1.

See note in Section 2.4, "AVX and SSE Instruction Exception Specification" in the Intel(R) 64 and IA-32 Architectures Software Developer's Manual, Volume 2A and Section 22.25.3, "Exception Conditions of Legacy SIMD Instructions Operating on MMX Registers" in the Intel(R) 64 and IA-32 Architectures Software Developer's Manual, Volume 3A

Instruction Operand Encoding

Op/En	Operand 1	Operand 2	Operand 3	Operand 4
RM	ModRM:reg (r, w)	ModRM:r/m (r)	NA	NA
RVM	ModRM:reg (w)	VEX.vvvv (r)	ModRM:r/m (r)	NA
FVM	ModRM:reg (w)	EVEX.vvvv (r)	ModRM:r/m (r)	NA

Description

Performs a SIMD add of the packed signed integers from the source operand (second operand) and the destination operand (first operand), and stores the packed integer results in the destination operand. See Figure 9-4 in the Intel(R) 64 and IA-32 Architectures Software Developer's Manual, Volume 1, for an illustration of a SIMD operation. Overflow is handled with signed saturation, as described in the following paragraphs.

(V)PADDSB performs a SIMD add of the packed signed integers with saturation from the first source operand and second source operand and stores the packed integer results in the destination operand. When an individual byte result is beyond the range of a signed byte integer (that is, greater than 7FH or less than 80H), the saturated value of 7FH or 80H, respectively, is written to the destination operand.

(V)PADDSW performs a SIMD add of the packed signed word integers with saturation from the first source operand and second source operand and stores the packed integer results in the destination operand. When an individual word result is beyond the range of a signed word integer (that is, greater than 7FFFH or less than 8000H), the satu-rated value of 7FFFH or 8000H, respectively, is written to the destination operand.

EVEX encoded versions: The first source operand is an ZMM/YMM/XMM register. The second source operand is an ZMM/YMM/XMM register or a memory location. The destination operand is an ZMM/YMM/XMM register.

VEX.256 encoded version: The first source operand is a YMM register. The second source operand is a YMM register or a 256-bit memory location. The destination operand is a YMM register.

VEX.128 encoded version: The first source operand is an XMM register. The second source operand is an XMM register or 128-bit memory location. The destination operand is an XMM register. The upper bits (MAXVL-1:128) of the corresponding register destination are zeroed.

128-bit Legacy SSE version: The first source operand is an XMM register. The second operand can be an XMM register or an 128-bit memory location. The destination is not distinct from the first source XMM register and the upper bits (MAXVL-1:128) of the corresponding register destination are unmodified.

Operation

PADDSB (with 64-bit operands)

    DEST[7:0] <- SaturateToSignedByte(DEST[7:0] + SRC (7:0]);
    (* Repeat add operation for 2nd through 7th bytes *)
    DEST[63:56] <- SaturateToSignedByte(DEST[63:56] + SRC[63:56] );

PADDSB (with 128-bit operands)

    DEST[7:0] <-SaturateToSignedByte (DEST[7:0] + SRC[7:0]);
    (* Repeat add operation for 2nd through 14th bytes *)
    DEST[127:120] <- SaturateToSignedByte (DEST[111:120] + SRC[127:120]);

VPADDSB (VEX.128 encoded version)

    DEST[7:0] <-  SaturateToSignedByte (SRC1[7:0] + SRC2[7:0]);
    (* Repeat subtract operation for 2nd through 14th bytes *)
    DEST[127:120] <-  SaturateToSignedByte (SRC1[111:120] + SRC2[127:120]);
    DEST[VLMAX-1:128] <-  0

VPADDSB (VEX.256 encoded version)

    DEST[7:0] <-  SaturateToSignedByte (SRC1[7:0] + SRC2[7:0]);
    (* Repeat add operation for 2nd through 31st bytes *)
    DEST[255:248]<-  SaturateToSignedByte (SRC1[255:248] + SRC2[255:248]);

VPADDSB (EVEX encoded versions)

(KL, VL) = (16, 128), (32, 256), (64, 512)
FOR j <-  0 TO KL-1
    i <-  j * 8
    IF k1[j] OR *no writemask*
          THEN DEST[i+7:i] <-  SaturateToSignedByte (SRC1[i+7:i] + SRC2[i+7:i])
          ELSE 
                IF *merging-masking* ; merging-masking
                      THEN *DEST[i+7:i] remains unchanged*
                      ELSE *zeroing-masking* ; zeroing-masking
                            DEST[i+7:i] = 0
                FI
    FI;
ENDFOR;
DEST[MAX_VL-1:VL] <-  0

PADDSW (with 64-bit operands)

    DEST[15:0] <- SaturateToSignedWord(DEST[15:0] + SRC[15:0] );
    (* Repeat add operation for 2nd and 7th words *)
    DEST[63:48] <- SaturateToSignedWord(DEST[63:48] + SRC[63:48] );

PADDSW (with 128-bit operands)

    DEST[15:0]  <- SaturateToSignedWord (DEST[15:0] + SRC[15:0]);
    (* Repeat add operation for 2nd through 7th words *)
    DEST[127:112] <- SaturateToSignedWord (DEST[127:112] + SRC[127:112]);

VPADDSW (VEX.128 encoded version)

    DEST[15:0] <-  SaturateToSignedWord (SRC1[15:0] + SRC2[15:0]);
    (* Repeat subtract operation for 2nd through 7th words *)
    DEST[127:112] <-  SaturateToSignedWord (SRC1[127:112] + SRC2[127:112]);
    DEST[VLMAX-1:128] <-  0

VPADDSW (VEX.256 encoded version)

    DEST[15:0] <-  SaturateToSignedWord (SRC1[15:0] + SRC2[15:0]);
    (* Repeat add operation for 2nd through 15th words *)
    DEST[255:240] <-  SaturateToSignedWord (SRC1[255:240] + SRC2[255:240])

VPADDSW (EVEX encoded versions)

(KL, VL) = (8, 128), (16, 256), (32, 512)
FOR j <-  0 TO KL-1
    i <-  j * 16
    IF k1[j] OR *no writemask*
          THEN DEST[i+15:i] <-  SaturateToSignedWord (SRC1[i+15:i] + SRC2[i+15:i])
          ELSE 
                IF *merging-masking* ; merging-masking
                      THEN *DEST[i+15:i] remains unchanged*
                      ELSE *zeroing-masking* ; zeroing-masking
                            DEST[i+15:i] = 0
                FI
    FI;
ENDFOR;
DEST[MAX_VL-1:VL] <-  0

Intel C/C++ Compiler Intrinsic Equivalents

PADDSB : __m64 _mm_adds_pi8(__m64 m1, __m64 m2)(V) PADDSB
    : __m128i _mm_adds_epi8(__m128i a, __m128i b) VPADDSB
    : __m256i _mm256_adds_epi8(__m256i a, __m256i b) PADDSW
    : __m64 _mm_adds_pi16(__m64 m1, __m64 m2)(V) PADDSW
    : __m128i _mm_adds_epi16(__m128i a, __m128i b) VPADDSW
    : __m256i _mm256_adds_epi16(__m256i a, __m256i b) VPADDSB__m512i
      _mm512_adds_epi8(__m512i a, __m512i b) VPADDSW__m512i
      _mm512_adds_epi16(__m512i a, __m512i b) VPADDSB__m512i
      _mm512_mask_adds_epi8(__m512i s, __mmask64 m, __m512i a,
                            __m512i b) VPADDSW__m512i
      _mm512_mask_adds_epi16(__m512i s, __mmask32 m, __m512i a,
                             __m512i b) VPADDSB__m512i
      _mm512_maskz_adds_epi8(__mmask64 m, __m512i a, __m512i b) VPADDSW__m512i
      _mm512_maskz_adds_epi16(__mmask32 m, __m512i a, __m512i b) VPADDSB__m256i
      _mm256_mask_adds_epi8(__m256i s, __mmask32 m, __m256i a,
                            __m256i b) VPADDSW__m256i
      _mm256_mask_adds_epi16(__m256i s, __mmask16 m, __m256i a,
                             __m256i b) VPADDSB__m256i
      _mm256_maskz_adds_epi8(__mmask32 m, __m256i a, __m256i b) VPADDSW__m256i
      _mm256_maskz_adds_epi16(__mmask16 m, __m256i a, __m256i b) VPADDSB__m128i
      _mm_mask_adds_epi8(__m128i s, __mmask16 m, __m128i a,
                         __m128i b) VPADDSW__m128i
      _mm_mask_adds_epi16(__m128i s, __mmask8 m, __m128i a,
                          __m128i b) VPADDSB__m128i
      _mm_maskz_adds_epi8(__mmask16 m, __m128i a, __m128i b) VPADDSW__m128i
      _mm_maskz_adds_epi16(__mmask8 m, __m128i a, __m128i b)

Flags Affected

None.

SIMD Floating-Point Exceptions