forked from Minki/linux
20dbf5ccbb
This work implements jiting of BPF_J{LT,LE,SLT,SLE} instructions with BPF_X/BPF_K variants for the ppc64 eBPF JIT. Signed-off-by: Daniel Borkmann <daniel@iogearbox.net> Acked-by: Naveen N. Rao <naveen.n.rao@linux.vnet.ibm.com> Tested-by: Naveen N. Rao <naveen.n.rao@linux.vnet.ibm.com> Signed-off-by: David S. Miller <davem@davemloft.net>
271 lines
11 KiB
C
271 lines
11 KiB
C
/*
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* bpf_jit.h: BPF JIT compiler for PPC
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*
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* Copyright 2011 Matt Evans <matt@ozlabs.org>, IBM Corporation
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* 2016 Naveen N. Rao <naveen.n.rao@linux.vnet.ibm.com>
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; version 2
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* of the License.
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*/
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#ifndef _BPF_JIT_H
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#define _BPF_JIT_H
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#ifndef __ASSEMBLY__
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#include <asm/types.h>
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#ifdef PPC64_ELF_ABI_v1
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#define FUNCTION_DESCR_SIZE 24
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#else
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#define FUNCTION_DESCR_SIZE 0
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#endif
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/*
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* 16-bit immediate helper macros: HA() is for use with sign-extending instrs
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* (e.g. LD, ADDI). If the bottom 16 bits is "-ve", add another bit into the
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* top half to negate the effect (i.e. 0xffff + 1 = 0x(1)0000).
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*/
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#define IMM_H(i) ((uintptr_t)(i)>>16)
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#define IMM_HA(i) (((uintptr_t)(i)>>16) + \
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(((uintptr_t)(i) & 0x8000) >> 15))
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#define IMM_L(i) ((uintptr_t)(i) & 0xffff)
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#define PLANT_INSTR(d, idx, instr) \
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do { if (d) { (d)[idx] = instr; } idx++; } while (0)
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#define EMIT(instr) PLANT_INSTR(image, ctx->idx, instr)
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#define PPC_NOP() EMIT(PPC_INST_NOP)
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#define PPC_BLR() EMIT(PPC_INST_BLR)
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#define PPC_BLRL() EMIT(PPC_INST_BLRL)
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#define PPC_MTLR(r) EMIT(PPC_INST_MTLR | ___PPC_RT(r))
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#define PPC_BCTR() EMIT(PPC_INST_BCTR)
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#define PPC_MTCTR(r) EMIT(PPC_INST_MTCTR | ___PPC_RT(r))
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#define PPC_ADDI(d, a, i) EMIT(PPC_INST_ADDI | ___PPC_RT(d) | \
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___PPC_RA(a) | IMM_L(i))
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#define PPC_MR(d, a) PPC_OR(d, a, a)
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#define PPC_LI(r, i) PPC_ADDI(r, 0, i)
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#define PPC_ADDIS(d, a, i) EMIT(PPC_INST_ADDIS | \
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___PPC_RT(d) | ___PPC_RA(a) | IMM_L(i))
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#define PPC_LIS(r, i) PPC_ADDIS(r, 0, i)
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#define PPC_STD(r, base, i) EMIT(PPC_INST_STD | ___PPC_RS(r) | \
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___PPC_RA(base) | ((i) & 0xfffc))
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#define PPC_STDU(r, base, i) EMIT(PPC_INST_STDU | ___PPC_RS(r) | \
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___PPC_RA(base) | ((i) & 0xfffc))
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#define PPC_STW(r, base, i) EMIT(PPC_INST_STW | ___PPC_RS(r) | \
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___PPC_RA(base) | IMM_L(i))
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#define PPC_STWU(r, base, i) EMIT(PPC_INST_STWU | ___PPC_RS(r) | \
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___PPC_RA(base) | IMM_L(i))
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#define PPC_STH(r, base, i) EMIT(PPC_INST_STH | ___PPC_RS(r) | \
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___PPC_RA(base) | IMM_L(i))
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#define PPC_STB(r, base, i) EMIT(PPC_INST_STB | ___PPC_RS(r) | \
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___PPC_RA(base) | IMM_L(i))
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#define PPC_LBZ(r, base, i) EMIT(PPC_INST_LBZ | ___PPC_RT(r) | \
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___PPC_RA(base) | IMM_L(i))
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#define PPC_LD(r, base, i) EMIT(PPC_INST_LD | ___PPC_RT(r) | \
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___PPC_RA(base) | IMM_L(i))
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#define PPC_LWZ(r, base, i) EMIT(PPC_INST_LWZ | ___PPC_RT(r) | \
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___PPC_RA(base) | IMM_L(i))
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#define PPC_LHZ(r, base, i) EMIT(PPC_INST_LHZ | ___PPC_RT(r) | \
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___PPC_RA(base) | IMM_L(i))
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#define PPC_LHBRX(r, base, b) EMIT(PPC_INST_LHBRX | ___PPC_RT(r) | \
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___PPC_RA(base) | ___PPC_RB(b))
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#define PPC_LDBRX(r, base, b) EMIT(PPC_INST_LDBRX | ___PPC_RT(r) | \
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___PPC_RA(base) | ___PPC_RB(b))
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#define PPC_BPF_LDARX(t, a, b, eh) EMIT(PPC_INST_LDARX | ___PPC_RT(t) | \
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___PPC_RA(a) | ___PPC_RB(b) | \
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__PPC_EH(eh))
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#define PPC_BPF_LWARX(t, a, b, eh) EMIT(PPC_INST_LWARX | ___PPC_RT(t) | \
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___PPC_RA(a) | ___PPC_RB(b) | \
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__PPC_EH(eh))
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#define PPC_BPF_STWCX(s, a, b) EMIT(PPC_INST_STWCX | ___PPC_RS(s) | \
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___PPC_RA(a) | ___PPC_RB(b))
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#define PPC_BPF_STDCX(s, a, b) EMIT(PPC_INST_STDCX | ___PPC_RS(s) | \
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___PPC_RA(a) | ___PPC_RB(b))
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#ifdef CONFIG_PPC64
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#define PPC_BPF_LL(r, base, i) do { PPC_LD(r, base, i); } while(0)
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#define PPC_BPF_STL(r, base, i) do { PPC_STD(r, base, i); } while(0)
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#define PPC_BPF_STLU(r, base, i) do { PPC_STDU(r, base, i); } while(0)
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#else
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#define PPC_BPF_LL(r, base, i) do { PPC_LWZ(r, base, i); } while(0)
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#define PPC_BPF_STL(r, base, i) do { PPC_STW(r, base, i); } while(0)
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#define PPC_BPF_STLU(r, base, i) do { PPC_STWU(r, base, i); } while(0)
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#endif
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#define PPC_CMPWI(a, i) EMIT(PPC_INST_CMPWI | ___PPC_RA(a) | IMM_L(i))
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#define PPC_CMPDI(a, i) EMIT(PPC_INST_CMPDI | ___PPC_RA(a) | IMM_L(i))
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#define PPC_CMPW(a, b) EMIT(PPC_INST_CMPW | ___PPC_RA(a) | \
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___PPC_RB(b))
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#define PPC_CMPD(a, b) EMIT(PPC_INST_CMPD | ___PPC_RA(a) | \
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___PPC_RB(b))
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#define PPC_CMPLWI(a, i) EMIT(PPC_INST_CMPLWI | ___PPC_RA(a) | IMM_L(i))
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#define PPC_CMPLDI(a, i) EMIT(PPC_INST_CMPLDI | ___PPC_RA(a) | IMM_L(i))
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#define PPC_CMPLW(a, b) EMIT(PPC_INST_CMPLW | ___PPC_RA(a) | \
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___PPC_RB(b))
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#define PPC_CMPLD(a, b) EMIT(PPC_INST_CMPLD | ___PPC_RA(a) | \
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___PPC_RB(b))
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#define PPC_SUB(d, a, b) EMIT(PPC_INST_SUB | ___PPC_RT(d) | \
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___PPC_RB(a) | ___PPC_RA(b))
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#define PPC_ADD(d, a, b) EMIT(PPC_INST_ADD | ___PPC_RT(d) | \
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___PPC_RA(a) | ___PPC_RB(b))
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#define PPC_MULD(d, a, b) EMIT(PPC_INST_MULLD | ___PPC_RT(d) | \
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___PPC_RA(a) | ___PPC_RB(b))
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#define PPC_MULW(d, a, b) EMIT(PPC_INST_MULLW | ___PPC_RT(d) | \
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___PPC_RA(a) | ___PPC_RB(b))
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#define PPC_MULHWU(d, a, b) EMIT(PPC_INST_MULHWU | ___PPC_RT(d) | \
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___PPC_RA(a) | ___PPC_RB(b))
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#define PPC_MULI(d, a, i) EMIT(PPC_INST_MULLI | ___PPC_RT(d) | \
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___PPC_RA(a) | IMM_L(i))
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#define PPC_DIVWU(d, a, b) EMIT(PPC_INST_DIVWU | ___PPC_RT(d) | \
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___PPC_RA(a) | ___PPC_RB(b))
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#define PPC_DIVD(d, a, b) EMIT(PPC_INST_DIVD | ___PPC_RT(d) | \
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___PPC_RA(a) | ___PPC_RB(b))
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#define PPC_AND(d, a, b) EMIT(PPC_INST_AND | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(b))
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#define PPC_ANDI(d, a, i) EMIT(PPC_INST_ANDI | ___PPC_RA(d) | \
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___PPC_RS(a) | IMM_L(i))
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#define PPC_AND_DOT(d, a, b) EMIT(PPC_INST_ANDDOT | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(b))
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#define PPC_OR(d, a, b) EMIT(PPC_INST_OR | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(b))
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#define PPC_MR(d, a) PPC_OR(d, a, a)
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#define PPC_ORI(d, a, i) EMIT(PPC_INST_ORI | ___PPC_RA(d) | \
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___PPC_RS(a) | IMM_L(i))
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#define PPC_ORIS(d, a, i) EMIT(PPC_INST_ORIS | ___PPC_RA(d) | \
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___PPC_RS(a) | IMM_L(i))
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#define PPC_XOR(d, a, b) EMIT(PPC_INST_XOR | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(b))
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#define PPC_XORI(d, a, i) EMIT(PPC_INST_XORI | ___PPC_RA(d) | \
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___PPC_RS(a) | IMM_L(i))
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#define PPC_XORIS(d, a, i) EMIT(PPC_INST_XORIS | ___PPC_RA(d) | \
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___PPC_RS(a) | IMM_L(i))
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#define PPC_EXTSW(d, a) EMIT(PPC_INST_EXTSW | ___PPC_RA(d) | \
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___PPC_RS(a))
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#define PPC_SLW(d, a, s) EMIT(PPC_INST_SLW | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(s))
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#define PPC_SLD(d, a, s) EMIT(PPC_INST_SLD | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(s))
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#define PPC_SRW(d, a, s) EMIT(PPC_INST_SRW | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(s))
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#define PPC_SRD(d, a, s) EMIT(PPC_INST_SRD | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(s))
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#define PPC_SRAD(d, a, s) EMIT(PPC_INST_SRAD | ___PPC_RA(d) | \
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___PPC_RS(a) | ___PPC_RB(s))
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#define PPC_SRADI(d, a, i) EMIT(PPC_INST_SRADI | ___PPC_RA(d) | \
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___PPC_RS(a) | __PPC_SH64(i))
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#define PPC_RLWINM(d, a, i, mb, me) EMIT(PPC_INST_RLWINM | ___PPC_RA(d) | \
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___PPC_RS(a) | __PPC_SH(i) | \
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__PPC_MB(mb) | __PPC_ME(me))
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#define PPC_RLWIMI(d, a, i, mb, me) EMIT(PPC_INST_RLWIMI | ___PPC_RA(d) | \
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___PPC_RS(a) | __PPC_SH(i) | \
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__PPC_MB(mb) | __PPC_ME(me))
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#define PPC_RLDICL(d, a, i, mb) EMIT(PPC_INST_RLDICL | ___PPC_RA(d) | \
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___PPC_RS(a) | __PPC_SH64(i) | \
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__PPC_MB64(mb))
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#define PPC_RLDICR(d, a, i, me) EMIT(PPC_INST_RLDICR | ___PPC_RA(d) | \
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___PPC_RS(a) | __PPC_SH64(i) | \
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__PPC_ME64(me))
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/* slwi = rlwinm Rx, Ry, n, 0, 31-n */
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#define PPC_SLWI(d, a, i) PPC_RLWINM(d, a, i, 0, 31-(i))
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/* srwi = rlwinm Rx, Ry, 32-n, n, 31 */
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#define PPC_SRWI(d, a, i) PPC_RLWINM(d, a, 32-(i), i, 31)
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/* sldi = rldicr Rx, Ry, n, 63-n */
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#define PPC_SLDI(d, a, i) PPC_RLDICR(d, a, i, 63-(i))
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/* sldi = rldicl Rx, Ry, 64-n, n */
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#define PPC_SRDI(d, a, i) PPC_RLDICL(d, a, 64-(i), i)
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#define PPC_NEG(d, a) EMIT(PPC_INST_NEG | ___PPC_RT(d) | ___PPC_RA(a))
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/* Long jump; (unconditional 'branch') */
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#define PPC_JMP(dest) EMIT(PPC_INST_BRANCH | \
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(((dest) - (ctx->idx * 4)) & 0x03fffffc))
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/* "cond" here covers BO:BI fields. */
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#define PPC_BCC_SHORT(cond, dest) EMIT(PPC_INST_BRANCH_COND | \
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(((cond) & 0x3ff) << 16) | \
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(((dest) - (ctx->idx * 4)) & \
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0xfffc))
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/* Sign-extended 32-bit immediate load */
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#define PPC_LI32(d, i) do { \
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if ((int)(uintptr_t)(i) >= -32768 && \
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(int)(uintptr_t)(i) < 32768) \
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PPC_LI(d, i); \
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else { \
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PPC_LIS(d, IMM_H(i)); \
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if (IMM_L(i)) \
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PPC_ORI(d, d, IMM_L(i)); \
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} } while(0)
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#define PPC_LI64(d, i) do { \
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if ((long)(i) >= -2147483648 && \
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(long)(i) < 2147483648) \
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PPC_LI32(d, i); \
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else { \
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if (!((uintptr_t)(i) & 0xffff800000000000ULL)) \
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PPC_LI(d, ((uintptr_t)(i) >> 32) & 0xffff); \
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else { \
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PPC_LIS(d, ((uintptr_t)(i) >> 48)); \
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if ((uintptr_t)(i) & 0x0000ffff00000000ULL) \
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PPC_ORI(d, d, \
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((uintptr_t)(i) >> 32) & 0xffff); \
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} \
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PPC_SLDI(d, d, 32); \
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if ((uintptr_t)(i) & 0x00000000ffff0000ULL) \
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PPC_ORIS(d, d, \
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((uintptr_t)(i) >> 16) & 0xffff); \
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if ((uintptr_t)(i) & 0x000000000000ffffULL) \
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PPC_ORI(d, d, (uintptr_t)(i) & 0xffff); \
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} } while (0)
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#ifdef CONFIG_PPC64
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#define PPC_FUNC_ADDR(d,i) do { PPC_LI64(d, i); } while(0)
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#else
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#define PPC_FUNC_ADDR(d,i) do { PPC_LI32(d, i); } while(0)
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#endif
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static inline bool is_nearbranch(int offset)
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{
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return (offset < 32768) && (offset >= -32768);
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}
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/*
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* The fly in the ointment of code size changing from pass to pass is
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* avoided by padding the short branch case with a NOP. If code size differs
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* with different branch reaches we will have the issue of code moving from
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* one pass to the next and will need a few passes to converge on a stable
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* state.
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*/
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#define PPC_BCC(cond, dest) do { \
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if (is_nearbranch((dest) - (ctx->idx * 4))) { \
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PPC_BCC_SHORT(cond, dest); \
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PPC_NOP(); \
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} else { \
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/* Flip the 'T or F' bit to invert comparison */ \
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PPC_BCC_SHORT(cond ^ COND_CMP_TRUE, (ctx->idx+2)*4); \
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PPC_JMP(dest); \
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} } while(0)
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/* To create a branch condition, select a bit of cr0... */
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#define CR0_LT 0
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#define CR0_GT 1
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#define CR0_EQ 2
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/* ...and modify BO[3] */
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#define COND_CMP_TRUE 0x100
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#define COND_CMP_FALSE 0x000
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/* Together, they make all required comparisons: */
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#define COND_GT (CR0_GT | COND_CMP_TRUE)
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#define COND_GE (CR0_LT | COND_CMP_FALSE)
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#define COND_EQ (CR0_EQ | COND_CMP_TRUE)
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#define COND_NE (CR0_EQ | COND_CMP_FALSE)
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#define COND_LT (CR0_LT | COND_CMP_TRUE)
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#define COND_LE (CR0_GT | COND_CMP_FALSE)
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#endif
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#endif
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