forked from Minki/linux
fd650a6394
It will take some time for binutils (gas) to support some newly added instructions, such as SSE4.1 instructions or the AES-NI instructions found in upcoming Intel CPU. To make the source code can be compiled by old binutils, .byte code is used instead of the assembly instruction. But the readability and flexibility of raw .byte code is not good. This patch solves the issue of raw .byte code via generating it via assembly instruction like gas macro. The syntax is as close as possible to real assembly instruction. Some helper macros such as MODRM is not a full feature implementation. It can be extended when necessary. Signed-off-by: Huang Ying <ying.huang@intel.com> Acked-by: H. Peter Anvin <hpa@zytor.com> Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
151 lines
2.6 KiB
C
151 lines
2.6 KiB
C
/*
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* Generate .byte code for some instructions not supported by old
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* binutils.
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*/
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#ifndef X86_ASM_INST_H
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#define X86_ASM_INST_H
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#ifdef __ASSEMBLY__
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.macro XMM_NUM opd xmm
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.ifc \xmm,%xmm0
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\opd = 0
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.endif
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.ifc \xmm,%xmm1
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\opd = 1
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.endif
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.ifc \xmm,%xmm2
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\opd = 2
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.endif
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.ifc \xmm,%xmm3
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\opd = 3
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.endif
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.ifc \xmm,%xmm4
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\opd = 4
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.endif
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.ifc \xmm,%xmm5
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\opd = 5
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.endif
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.ifc \xmm,%xmm6
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\opd = 6
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.endif
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.ifc \xmm,%xmm7
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\opd = 7
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.endif
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.ifc \xmm,%xmm8
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\opd = 8
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.endif
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.ifc \xmm,%xmm9
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\opd = 9
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.endif
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.ifc \xmm,%xmm10
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\opd = 10
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.endif
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.ifc \xmm,%xmm11
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\opd = 11
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.endif
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.ifc \xmm,%xmm12
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\opd = 12
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.endif
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.ifc \xmm,%xmm13
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\opd = 13
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.endif
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.ifc \xmm,%xmm14
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\opd = 14
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.endif
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.ifc \xmm,%xmm15
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\opd = 15
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.endif
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.endm
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.macro PFX_OPD_SIZE
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.byte 0x66
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.endm
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.macro PFX_REX opd1 opd2
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.if (\opd1 | \opd2) & 8
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.byte 0x40 | ((\opd1 & 8) >> 3) | ((\opd2 & 8) >> 1)
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.endif
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.endm
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.macro MODRM mod opd1 opd2
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.byte \mod | (\opd1 & 7) | ((\opd2 & 7) << 3)
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.endm
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.macro PSHUFB_XMM xmm1 xmm2
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XMM_NUM pshufb_opd1 \xmm1
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XMM_NUM pshufb_opd2 \xmm2
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PFX_OPD_SIZE
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PFX_REX pshufb_opd1 pshufb_opd2
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.byte 0x0f, 0x38, 0x00
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MODRM 0xc0 pshufb_opd1 pshufb_opd2
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.endm
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.macro PCLMULQDQ imm8 xmm1 xmm2
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XMM_NUM clmul_opd1 \xmm1
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XMM_NUM clmul_opd2 \xmm2
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PFX_OPD_SIZE
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PFX_REX clmul_opd1 clmul_opd2
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.byte 0x0f, 0x3a, 0x44
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MODRM 0xc0 clmul_opd1 clmul_opd2
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.byte \imm8
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.endm
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.macro AESKEYGENASSIST rcon xmm1 xmm2
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XMM_NUM aeskeygen_opd1 \xmm1
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XMM_NUM aeskeygen_opd2 \xmm2
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PFX_OPD_SIZE
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PFX_REX aeskeygen_opd1 aeskeygen_opd2
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.byte 0x0f, 0x3a, 0xdf
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MODRM 0xc0 aeskeygen_opd1 aeskeygen_opd2
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.byte \rcon
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.endm
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.macro AESIMC xmm1 xmm2
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XMM_NUM aesimc_opd1 \xmm1
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XMM_NUM aesimc_opd2 \xmm2
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PFX_OPD_SIZE
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PFX_REX aesimc_opd1 aesimc_opd2
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.byte 0x0f, 0x38, 0xdb
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MODRM 0xc0 aesimc_opd1 aesimc_opd2
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.endm
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.macro AESENC xmm1 xmm2
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XMM_NUM aesenc_opd1 \xmm1
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XMM_NUM aesenc_opd2 \xmm2
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PFX_OPD_SIZE
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PFX_REX aesenc_opd1 aesenc_opd2
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.byte 0x0f, 0x38, 0xdc
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MODRM 0xc0 aesenc_opd1 aesenc_opd2
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.endm
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.macro AESENCLAST xmm1 xmm2
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XMM_NUM aesenclast_opd1 \xmm1
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XMM_NUM aesenclast_opd2 \xmm2
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PFX_OPD_SIZE
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PFX_REX aesenclast_opd1 aesenclast_opd2
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.byte 0x0f, 0x38, 0xdd
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MODRM 0xc0 aesenclast_opd1 aesenclast_opd2
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.endm
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.macro AESDEC xmm1 xmm2
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XMM_NUM aesdec_opd1 \xmm1
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XMM_NUM aesdec_opd2 \xmm2
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PFX_OPD_SIZE
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PFX_REX aesdec_opd1 aesdec_opd2
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.byte 0x0f, 0x38, 0xde
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MODRM 0xc0 aesdec_opd1 aesdec_opd2
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.endm
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.macro AESDECLAST xmm1 xmm2
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XMM_NUM aesdeclast_opd1 \xmm1
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XMM_NUM aesdeclast_opd2 \xmm2
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PFX_OPD_SIZE
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PFX_REX aesdeclast_opd1 aesdeclast_opd2
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.byte 0x0f, 0x38, 0xdf
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MODRM 0xc0 aesdeclast_opd1 aesdeclast_opd2
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.endm
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#endif
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#endif
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