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diff --git a/lib/hipe/x86/hipe_x86_encode.erl b/lib/hipe/x86/hipe_x86_encode.erl
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+%%%
+%%% %CopyrightBegin%
+%%%
+%%% Copyright Ericsson AB 2001-2009. All Rights Reserved.
+%%%
+%%% The contents of this file are subject to the Erlang Public License,
+%%% Version 1.1, (the "License"); you may not use this file except in
+%%% compliance with the License. You should have received a copy of the
+%%% Erlang Public License along with this software. If not, it can be
+%%% retrieved online at http://www.erlang.org/.
+%%%
+%%% Software distributed under the License is distributed on an "AS IS"
+%%% basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
+%%% the License for the specific language governing rights and limitations
+%%% under the License.
+%%%
+%%% %CopyrightEnd%
+%%%
+%%% Copyright (C) 2000-2005 Mikael Pettersson
+%%%
+%%% This is the syntax of x86 r/m operands:
+%%%
+%%% opnd ::= reg mod == 11
+%%% | MEM[ea] mod != 11
+%%%
+%%% ea ::= disp32(reg) mod == 10, r/m != ESP
+%%% | disp32 sib12 mod == 10, r/m == 100
+%%% | disp8(reg) mod == 01, r/m != ESP
+%%% | disp8 sib12 mod == 01, r/m == 100
+%%% | (reg) mod == 00, r/m != ESP and EBP
+%%% | sib0 mod == 00, r/m == 100
+%%% | disp32 mod == 00, r/m == 101 [on x86-32]
+%%% | disp32(%rip) mod == 00, r/m == 101 [on x86-64]
+%%%
+%%% // sib0: mod == 00
+%%% sib0 ::= disp32(,index,scale) base == EBP, index != ESP
+%%% | disp32 base == EBP, index == 100
+%%% | (base,index,scale) base != EBP, index != ESP
+%%% | (base) base != EBP, index == 100
+%%%
+%%% // sib12: mod == 01 or 10
+%%% sib12 ::= (base,index,scale) index != ESP
+%%% | (base) index == 100
+%%%
+%%% scale ::= 00 | 01 | 10 | 11 index << scale
+%%%
+%%% Notes:
+%%%
+%%% 1. ESP cannot be used as index register.
+%%% 2. Use of ESP as base register requires a SIB byte.
+%%% 3. disp(reg), when reg != ESP, can be represented without
+%%% [r/m == reg] or with [r/m == 100, base == reg] a SIB byte.
+%%% 4. disp32 can be represented without [mod == 00, r/m == 101]
+%%% or with [mod == 00, r/m == 100, base == 101, index == 100]
+%%% a SIB byte.
+%%% 5. x86-32 and x86-64 interpret mod==00b r/m==101b EAs differently:
+%%% on x86-32 the disp32 is an absolute address, but on x86-64 the
+%%% disp32 is relative to the %rip of the next instruction.
+%%% Absolute disp32s need a SIB on x86-64.
+
+-module(hipe_x86_encode).
+
+-export([% condition codes
+ cc/1,
+ % 8-bit registers
+ %% al/0, cl/0, dl/0, bl/0, ah/0, ch/0, dh/0, bh/0,
+ % 32-bit registers
+ %% eax/0, ecx/0, edx/0, ebx/0, esp/0, ebp/0, esi/0, edi/0,
+ % operands
+ sindex/2, sib/1, sib/2,
+ ea_disp32_base/2, ea_disp32_sib/2,
+ ea_disp8_base/2, ea_disp8_sib/2,
+ ea_base/1,
+ %% ea_disp32_sindex/1, % XXX: do not use on x86-32, only on x86-64
+ ea_disp32_sindex/2,
+ ea_sib/1, ea_disp32/1,
+ rm_reg/1, rm_mem/1,
+ % instructions
+ insn_encode/3, insn_sizeof/2]).
+
+%%-define(DO_HIPE_X86_ENCODE_TEST,true).
+-ifdef(DO_HIPE_X86_ENCODE_TEST).
+-export([dotest/0, dotest/1]). % for testing, don't use
+-endif.
+
+-define(ASSERT(F,G), if G -> [] ; true -> exit({?MODULE,F}) end).
+%-define(ASSERT(F,G), []).
+
+%%% condition codes
+
+-define(CC_O, 2#0000). % overflow
+-define(CC_NO, 2#0001). % no overflow
+-define(CC_B, 2#0010). % below, <u
+-define(CC_AE, 2#0011). % above or equal, >=u
+-define(CC_E, 2#0100). % equal
+-define(CC_NE, 2#0101). % not equal
+-define(CC_BE, 2#0110). % below or equal, <=u
+-define(CC_A, 2#0111). % above, >u
+-define(CC_S, 2#1000). % sign, +
+-define(CC_NS, 2#1001). % not sign, -
+-define(CC_PE, 2#1010). % parity even
+-define(CC_PO, 2#1011). % parity odd
+-define(CC_L, 2#1100). % less than, <s
+-define(CC_GE, 2#1101). % greater or equal, >=s
+-define(CC_LE, 2#1110). % less or equal, <=s
+-define(CC_G, 2#1111). % greater than, >s
+
+cc(o) -> ?CC_O;
+cc(no) -> ?CC_NO;
+cc(b) -> ?CC_B;
+cc(ae) -> ?CC_AE;
+cc(e) -> ?CC_E;
+cc(ne) -> ?CC_NE;
+cc(be) -> ?CC_BE;
+cc(a) -> ?CC_A;
+cc(s) -> ?CC_S;
+cc(ns) -> ?CC_NS;
+cc(pe) -> ?CC_PE;
+cc(po) -> ?CC_PO;
+cc(l) -> ?CC_L;
+cc(ge) -> ?CC_GE;
+cc(le) -> ?CC_LE;
+cc(g) -> ?CC_G.
+
+%%% 8-bit registers
+
+-define(AL, 2#000).
+-define(CL, 2#001).
+-define(DL, 2#010).
+-define(BL, 2#011).
+-define(AH, 2#100).
+-define(CH, 2#101).
+-define(DH, 2#110).
+-define(BH, 2#111).
+
+%% al() -> ?AL.
+%% cl() -> ?CL.
+%% dl() -> ?DL.
+%% bl() -> ?BL.
+%% ah() -> ?AH.
+%% ch() -> ?CH.
+%% dh() -> ?DH.
+%% bh() -> ?BH.
+
+%%% 32-bit registers
+
+-define(EAX, 2#000).
+-define(ECX, 2#001).
+-define(EDX, 2#010).
+-define(EBX, 2#011).
+-define(ESP, 2#100).
+-define(EBP, 2#101).
+-define(ESI, 2#110).
+-define(EDI, 2#111).
+
+%% eax() -> ?EAX.
+%% ecx() -> ?ECX.
+%% edx() -> ?EDX.
+%% ebx() -> ?EBX.
+%% esp() -> ?ESP.
+%% ebp() -> ?EBP.
+%% esi() -> ?ESI.
+%% edi() -> ?EDI.
+
+%%% r/m operands
+
+sindex(Scale, Index) when is_integer(Scale), is_integer(Index) ->
+ ?ASSERT(sindex, Scale >= 0),
+ ?ASSERT(sindex, Scale =< 3),
+ ?ASSERT(sindex, Index =/= ?ESP),
+ {sindex, Scale, Index}.
+
+-record(sib, {sindex_opt, base :: integer()}).
+sib(Base) when is_integer(Base) -> #sib{sindex_opt=none, base=Base}.
+sib(Base, Sindex) when is_integer(Base) -> #sib{sindex_opt=Sindex, base=Base}.
+
+ea_disp32_base(Disp32, Base) when is_integer(Base) ->
+ ?ASSERT(ea_disp32_base, Base =/= ?ESP),
+ {ea_disp32_base, Disp32, Base}.
+ea_disp32_sib(Disp32, SIB) -> {ea_disp32_sib, Disp32, SIB}.
+ea_disp8_base(Disp8, Base) when is_integer(Base) ->
+ ?ASSERT(ea_disp8_base, Base =/= ?ESP),
+ {ea_disp8_base, Disp8, Base}.
+ea_disp8_sib(Disp8, SIB) -> {ea_disp8_sib, Disp8, SIB}.
+ea_base(Base) when is_integer(Base) ->
+ ?ASSERT(ea_base, Base =/= ?ESP),
+ ?ASSERT(ea_base, Base =/= ?EBP),
+ {ea_base, Base}.
+%% ea_disp32_sindex(Disp32) -> {ea_disp32_sindex, Disp32, none}.
+ea_disp32_sindex(Disp32, Sindex) -> {ea_disp32_sindex, Disp32, Sindex}.
+ea_sib(SIB) ->
+ ?ASSERT(ea_sib, SIB#sib.base =/= ?EBP),
+ {ea_sib, SIB}.
+ea_disp32(Disp32) -> {ea_disp32, Disp32}.
+
+rm_reg(Reg) -> {rm_reg, Reg}.
+rm_mem(EA) -> {rm_mem, EA}.
+
+mk_modrm(Mod, RO, RM) ->
+ (Mod bsl 6) bor (RO bsl 3) bor RM.
+
+mk_sib(Scale, Index, Base) ->
+ (Scale bsl 6) bor (Index bsl 3) bor Base.
+
+le16(Word, Tail) ->
+ [Word band 16#FF, (Word bsr 8) band 16#FF | Tail].
+
+le32(Word, Tail) when is_integer(Word) ->
+ [Word band 16#FF, (Word bsr 8) band 16#FF,
+ (Word bsr 16) band 16#FF, (Word bsr 24) band 16#FF | Tail];
+le32({Tag,Val}, Tail) -> % a relocatable datum
+ [{le32,Tag,Val} | Tail].
+
+enc_sindex_opt({sindex,Scale,Index}) -> {Scale, Index};
+enc_sindex_opt(none) -> {2#00, 2#100}.
+
+enc_sib(#sib{sindex_opt=SindexOpt, base=Base}) ->
+ {Scale, Index} = enc_sindex_opt(SindexOpt),
+ mk_sib(Scale, Index, Base).
+
+enc_ea(EA, RO, Tail) ->
+ case EA of
+ {ea_disp32_base, Disp32, Base} ->
+ [mk_modrm(2#10, RO, Base) | le32(Disp32, Tail)];
+ {ea_disp32_sib, Disp32, SIB} ->
+ [mk_modrm(2#10, RO, 2#100), enc_sib(SIB) | le32(Disp32, Tail)];
+ {ea_disp8_base, Disp8, Base} ->
+ [mk_modrm(2#01, RO, Base), Disp8 | Tail];
+ {ea_disp8_sib, Disp8, SIB} ->
+ [mk_modrm(2#01, RO, 2#100), enc_sib(SIB), Disp8 | Tail];
+ {ea_base, Base} ->
+ [mk_modrm(2#00, RO, Base) | Tail];
+ {ea_disp32_sindex, Disp32, SindexOpt} ->
+ {Scale, Index} = enc_sindex_opt(SindexOpt),
+ SIB = mk_sib(Scale, Index, 2#101),
+ MODRM = mk_modrm(2#00, RO, 2#100),
+ [MODRM, SIB | le32(Disp32, Tail)];
+ {ea_sib, SIB} ->
+ [mk_modrm(2#00, RO, 2#100), enc_sib(SIB) | Tail];
+ {ea_disp32, Disp32} ->
+ [mk_modrm(2#00, RO, 2#101) | le32(Disp32, Tail)]
+ end.
+
+encode_rm(RM, RO, Tail) ->
+ case RM of
+ {rm_reg, Reg} -> [mk_modrm(2#11, RO, Reg) | Tail];
+ {rm_mem, EA} -> enc_ea(EA, RO, Tail)
+ end.
+
+sizeof_ea(EA) ->
+ case element(1, EA) of
+ ea_disp32_base -> 5;
+ ea_disp32_sib -> 6;
+ ea_disp8_base -> 2;
+ ea_disp8_sib -> 3;
+ ea_base -> 1;
+ ea_disp32_sindex -> 6;
+ ea_sib -> 2;
+ ea_disp32 -> 5
+ end.
+
+sizeof_rm(RM) ->
+ case RM of
+ {rm_reg, _} -> 1;
+ {rm_mem, EA} -> sizeof_ea(EA)
+ end.
+
+%%% Floating point stack positions
+
+-define(ST0, 2#000).
+-define(ST1, 2#001).
+-define(ST2, 2#010).
+-define(ST3, 2#011).
+-define(ST4, 2#100).
+-define(ST5, 2#101).
+-define(ST6, 2#110).
+-define(ST7, 2#111).
+
+st(0) -> ?ST0;
+st(1) -> ?ST1;
+st(2) -> ?ST2;
+st(3) -> ?ST3;
+st(4) -> ?ST4;
+st(5) -> ?ST5;
+st(6) -> ?ST6;
+st(7) -> ?ST7.
+
+
+%%% Instructions
+%%%
+%%% Insn ::= {Op,Opnds}
+%%% Opnds ::= {Opnd1,...,Opndn} (n >= 0)
+%%% Opnd ::= eax | ax | al | 1 | cl
+%%% | {imm32,Imm32} | {imm16,Imm16} | {imm8,Imm8}
+%%% | {rm32,RM32} | {rm16,RM16} | {rm8,RM8}
+%%% | {rel32,Rel32} | {rel8,Rel8}
+%%% | {moffs32,Moffs32} | {moffs16,Moffs16} | {moffs8,Moffs8}
+%%% | {cc,CC}
+%%% | {reg32,Reg32} | {reg16,Reg16} | {reg8,Reg8}
+%%% | {ea,EA}
+
+-define(PFX_OPND, 16#66).
+
+arith_binop_encode(SubOpcode, Opnds) ->
+ %% add, or, adc, sbb, and, sub, xor, cmp
+ case Opnds of
+ {eax, {imm32,Imm32}} ->
+ [16#05 bor (SubOpcode bsl 3) | le32(Imm32, [])];
+ {{rm32,RM32}, {imm32,Imm32}} ->
+ [16#81 | encode_rm(RM32, SubOpcode, le32(Imm32, []))];
+ {{rm32,RM32}, {imm8,Imm8}} ->
+ [16#83 | encode_rm(RM32, SubOpcode, [Imm8])];
+ {{rm32,RM32}, {reg32,Reg32}} ->
+ [16#01 bor (SubOpcode bsl 3) | encode_rm(RM32, Reg32, [])];
+ {{reg32,Reg32}, {rm32,RM32}} ->
+ [16#03 bor (SubOpcode bsl 3) | encode_rm(RM32, Reg32, [])]
+ end.
+
+arith_binop_sizeof(Opnds) ->
+ %% add, or, adc, sbb, and, sub, xor, cmp
+ case Opnds of
+ {eax, {imm32,_}} ->
+ 1 + 4;
+ {{rm32,RM32}, {imm32,_}} ->
+ 1 + sizeof_rm(RM32) + 4;
+ {{rm32,RM32}, {imm8,_}} ->
+ 1 + sizeof_rm(RM32) + 1;
+ {{rm32,RM32}, {reg32,_}} ->
+ 1 + sizeof_rm(RM32);
+ {{reg32,_}, {rm32,RM32}} ->
+ 1 + sizeof_rm(RM32)
+ end.
+
+bs_op_encode(Opcode, {{reg32,Reg32}, {rm32,RM32}}) -> % bsf, bsr
+ [16#0F, Opcode | encode_rm(RM32, Reg32, [])].
+
+bs_op_sizeof({{reg32,_}, {rm32,RM32}}) -> % bsf, bsr
+ 2 + sizeof_rm(RM32).
+
+bswap_encode({{reg32,Reg32}}) ->
+ [16#0F, 16#C8 bor Reg32].
+
+bswap_sizeof({{reg32,_}}) ->
+ 2.
+
+bt_op_encode(SubOpcode, Opnds) -> % bt, btc, btr, bts
+ case Opnds of
+ {{rm32,RM32}, {reg32,Reg32}} ->
+ [16#0F, 16#A3 bor (SubOpcode bsl 3) | encode_rm(RM32, Reg32, [])];
+ {{rm32,RM32}, {imm8,Imm8}} ->
+ [16#0F, 16#BA | encode_rm(RM32, SubOpcode, [Imm8])]
+ end.
+
+bt_op_sizeof(Opnds) -> % bt, btc, btr, bts
+ case Opnds of
+ {{rm32,RM32}, {reg32,_}} ->
+ 2 + sizeof_rm(RM32);
+ {{rm32,RM32}, {imm8,_}} ->
+ 2 + sizeof_rm(RM32) + 1
+ end.
+
+call_encode(Opnds) ->
+ case Opnds of
+ {{rel32,Rel32}} ->
+ [16#E8 | le32(Rel32, [])];
+ {{rm32,RM32}} ->
+ [16#FF | encode_rm(RM32, 2#010, [])]
+ end.
+
+call_sizeof(Opnds) ->
+ case Opnds of
+ {{rel32,_}} ->
+ 1 + 4;
+ {{rm32,RM32}} ->
+ 1 + sizeof_rm(RM32)
+ end.
+
+cbw_encode({}) ->
+ [?PFX_OPND, 16#98].
+
+cbw_sizeof({}) ->
+ 2.
+
+nullary_op_encode(Opcode, {}) ->
+ %% cdq, clc, cld, cmc, cwde, into, leave, nop, prefix_fs, stc, std
+ [Opcode].
+
+nullary_op_sizeof({}) ->
+ %% cdq, clc, cld, cmc, cwde, into, leave, nop, prefix_fs, stc, std
+ 1.
+
+cmovcc_encode({{cc,CC}, {reg32,Reg32}, {rm32,RM32}}) ->
+ [16#0F, 16#40 bor CC | encode_rm(RM32, Reg32, [])].
+
+cmovcc_sizeof({{cc,_}, {reg32,_}, {rm32,RM32}}) ->
+ 2 + sizeof_rm(RM32).
+
+incdec_encode(SubOpcode, Opnds) -> % SubOpcode is either 0 or 1
+ case Opnds of
+ {{rm32,RM32}} ->
+ [16#FF | encode_rm(RM32, SubOpcode, [])];
+ {{reg32,Reg32}} ->
+ [16#40 bor (SubOpcode bsl 3) bor Reg32]
+ end.
+
+incdec_sizeof(Opnds) ->
+ case Opnds of
+ {{rm32,RM32}} ->
+ 1 + sizeof_rm(RM32);
+ {{reg32,_}} ->
+ 1
+ end.
+
+arith_unop_encode(Opcode, {{rm32,RM32}}) -> % div, idiv, mul, neg, not
+ [16#F7 | encode_rm(RM32, Opcode, [])].
+
+arith_unop_sizeof({{rm32,RM32}}) -> % div, idiv, mul, neg, not
+ 1 + sizeof_rm(RM32).
+
+enter_encode({{imm16,Imm16}, {imm8,Imm8}}) ->
+ [16#C8 | le16(Imm16, [Imm8])].
+
+enter_sizeof({{imm16,_}, {imm8,_}}) ->
+ 1 + 2 + 1.
+
+imul_encode(Opnds) ->
+ case Opnds of
+ {{rm32,RM32}} -> % <edx,eax> *= rm32
+ [16#F7 | encode_rm(RM32, 2#101, [])];
+ {{reg32,Reg32}, {rm32,RM32}} -> % reg *= rm32
+ [16#0F, 16#AF | encode_rm(RM32, Reg32, [])];
+ {{reg32,Reg32}, {rm32,RM32}, {imm8,Imm8}} -> % reg := rm32 * sext(imm8)
+ [16#6B | encode_rm(RM32, Reg32, [Imm8])];
+ {{reg32,Reg32}, {rm32,RM32}, {imm32,Imm32}} -> % reg := rm32 * imm32
+ [16#69 | encode_rm(RM32, Reg32, le32(Imm32, []))]
+ end.
+
+imul_sizeof(Opnds) ->
+ case Opnds of
+ {{rm32,RM32}} ->
+ 1 + sizeof_rm(RM32);
+ {{reg32,_}, {rm32,RM32}} ->
+ 2 + sizeof_rm(RM32);
+ {{reg32,_}, {rm32,RM32}, {imm8,_}} ->
+ 1 + sizeof_rm(RM32) + 1;
+ {{reg32,_}, {rm32,RM32}, {imm32,_}} ->
+ 1 + sizeof_rm(RM32) + 4
+ end.
+
+jcc_encode(Opnds) ->
+ case Opnds of
+ {{cc,CC}, {rel8,Rel8}} ->
+ [16#70 bor CC, Rel8];
+ {{cc,CC}, {rel32,Rel32}} ->
+ [16#0F, 16#80 bor CC | le32(Rel32, [])]
+ end.
+
+jcc_sizeof(Opnds) ->
+ case Opnds of
+ {{cc,_}, {rel8,_}} ->
+ 2;
+ {{cc,_}, {rel32,_}} ->
+ 2 + 4
+ end.
+
+jmp8_op_encode(Opcode, {{rel8,Rel8}}) -> % jecxz, loop, loope, loopne
+ [Opcode, Rel8].
+
+jmp8_op_sizeof({{rel8,_}}) -> % jecxz, loop, loope, loopne
+ 2.
+
+jmp_encode(Opnds) ->
+ case Opnds of
+ {{rel8,Rel8}} ->
+ [16#EB, Rel8];
+ {{rel32,Rel32}} ->
+ [16#E9 | le32(Rel32, [])];
+ {{rm32,RM32}} ->
+ [16#FF | encode_rm(RM32, 2#100, [])]
+ end.
+
+jmp_sizeof(Opnds) ->
+ case Opnds of
+ {{rel8,_}} ->
+ 2;
+ {{rel32,_}} ->
+ 1 + 4;
+ {{rm32,RM32}} ->
+ 1 + sizeof_rm(RM32)
+ end.
+
+lea_encode({{reg32,Reg32}, {ea,EA}}) ->
+ [16#8D | enc_ea(EA, Reg32, [])].
+
+lea_sizeof({{reg32,_}, {ea,EA}}) ->
+ 1 + sizeof_ea(EA).
+
+mov_encode(Opnds) ->
+ case Opnds of
+ {{rm8,RM8}, {reg8,Reg8}} ->
+ [16#88 | encode_rm(RM8, Reg8, [])];
+ {{rm16,RM16}, {reg16,Reg16}} ->
+ [?PFX_OPND, 16#89 | encode_rm(RM16, Reg16, [])];
+ {{rm32,RM32}, {reg32,Reg32}} ->
+ [16#89 | encode_rm(RM32, Reg32, [])];
+ {{reg8,Reg8}, {rm8,RM8}} ->
+ [16#8A | encode_rm(RM8, Reg8, [])];
+ {{reg16,Reg16}, {rm16,RM16}} ->
+ [?PFX_OPND, 16#8B | encode_rm(RM16, Reg16, [])];
+ {{reg32,Reg32}, {rm32,RM32}} ->
+ [16#8B | encode_rm(RM32, Reg32, [])];
+ {al, {moffs8,Moffs8}} ->
+ [16#A0 | le32(Moffs8, [])];
+ {ax, {moffs16,Moffs16}} ->
+ [?PFX_OPND, 16#A1 | le32(Moffs16, [])];
+ {eax, {moffs32,Moffs32}} ->
+ [16#A1 | le32(Moffs32, [])];
+ {{moffs8,Moffs8}, al} ->
+ [16#A2 | le32(Moffs8, [])];
+ {{moffs16,Moffs16}, ax} ->
+ [?PFX_OPND, 16#A3 | le32(Moffs16, [])];
+ {{moffs32,Moffs32}, eax} ->
+ [16#A3 | le32(Moffs32, [])];
+ {{reg8,Reg8}, {imm8,Imm8}} ->
+ [16#B0 bor Reg8, Imm8];
+ {{reg16,Reg16}, {imm16,Imm16}} ->
+ [?PFX_OPND, 16#B8 bor Reg16 | le16(Imm16, [])];
+ {{reg32,Reg32}, {imm32,Imm32}} ->
+ [16#B8 bor Reg32 | le32(Imm32, [])];
+ {{rm8,RM8}, {imm8,Imm8}} ->
+ [16#C6 | encode_rm(RM8, 2#000, [Imm8])];
+ {{rm16,RM16}, {imm16,Imm16}} ->
+ [?PFX_OPND, 16#C7 | encode_rm(RM16, 2#000, le16(Imm16, []))];
+ {{rm32,RM32}, {imm32,Imm32}} ->
+ [16#C7 | encode_rm(RM32, 2#000, le32(Imm32, []))]
+ end.
+
+mov_sizeof(Opnds) ->
+ case Opnds of
+ {{rm8,RM8}, {reg8,_}} ->
+ 1 + sizeof_rm(RM8);
+ {{rm16,RM16}, {reg16,_}} ->
+ 2 + sizeof_rm(RM16);
+ {{rm32,RM32}, {reg32,_}} ->
+ 1 + sizeof_rm(RM32);
+ {{reg8,_}, {rm8,RM8}} ->
+ 1 + sizeof_rm(RM8);
+ {{reg16,_}, {rm16,RM16}} ->
+ 2 + sizeof_rm(RM16);
+ {{reg32,_}, {rm32,RM32}} ->
+ 1 + sizeof_rm(RM32);
+ {al, {moffs8,_}} ->
+ 1 + 4;
+ {ax, {moffs16,_}} ->
+ 2 + 4;
+ {eax, {moffs32,_}} ->
+ 1 + 4;
+ {{moffs8,_}, al} ->
+ 1 + 4;
+ {{moffs16,_}, ax} ->
+ 2 + 4;
+ {{moffs32,_}, eax} ->
+ 1 + 4;
+ {{reg8,_}, {imm8,_}} ->
+ 2;
+ {{reg16,_}, {imm16,_}} ->
+ 2 + 2;
+ {{reg32,_}, {imm32,_}} ->
+ 1 + 4;
+ {{rm8,RM8}, {imm8,_}} ->
+ 1 + sizeof_rm(RM8) + 1;
+ {{rm16,RM16}, {imm16,_}} ->
+ 2 + sizeof_rm(RM16) + 2;
+ {{rm32,RM32}, {imm32,_}} ->
+ 1 + sizeof_rm(RM32) + 4
+ end.
+
+movx_op_encode(Opcode, Opnds) -> % movsx, movzx
+ case Opnds of
+ {{reg16,Reg16}, {rm8,RM8}} ->
+ [?PFX_OPND, 16#0F, Opcode | encode_rm(RM8, Reg16, [])];
+ {{reg32,Reg32}, {rm8,RM8}} ->
+ [16#0F, Opcode | encode_rm(RM8, Reg32, [])];
+ {{reg32,Reg32}, {rm16,RM16}} ->
+ [16#0F, Opcode bor 1 | encode_rm(RM16, Reg32, [])]
+ end.
+
+movx_op_sizeof(Opnds) ->
+ case Opnds of
+ {{reg16,_}, {rm8,RM8}} ->
+ 3 + sizeof_rm(RM8);
+ {{reg32,_}, {rm8,RM8}} ->
+ 2 + sizeof_rm(RM8);
+ {{reg32,_}, {rm16,RM16}} ->
+ 2 + sizeof_rm(RM16)
+ end.
+
+pop_encode(Opnds) ->
+ case Opnds of
+ {{rm32,RM32}} ->
+ [16#8F | encode_rm(RM32, 2#000, [])];
+ {{reg32,Reg32}} ->
+ [16#58 bor Reg32]
+ end.
+
+pop_sizeof(Opnds) ->
+ case Opnds of
+ {{rm32,RM32}} ->
+ 1 + sizeof_rm(RM32);
+ {{reg32,_}} ->
+ 1
+ end.
+
+push_encode(Opnds) ->
+ case Opnds of
+ {{rm32,RM32}} ->
+ [16#FF | encode_rm(RM32, 2#110, [])];
+ {{reg32,Reg32}} ->
+ [16#50 bor Reg32];
+ {{imm8,Imm8}} -> % sign-extended
+ [16#6A, Imm8];
+ {{imm32,Imm32}} ->
+ [16#68 | le32(Imm32, [])]
+ end.
+
+push_sizeof(Opnds) ->
+ case Opnds of
+ {{rm32,RM32}} ->
+ 1 + sizeof_rm(RM32);
+ {{reg32,_}} ->
+ 1;
+ {{imm8,_}} ->
+ 2;
+ {{imm32,_}} ->
+ 1 + 4
+ end.
+
+shift_op_encode(SubOpcode, Opnds) -> % rcl, rcr, rol, ror, sar, shl, shr
+ case Opnds of
+ {{rm32,RM32}, 1} ->
+ [16#D1 | encode_rm(RM32, SubOpcode, [])];
+ {{rm32,RM32}, cl} ->
+ [16#D3 | encode_rm(RM32, SubOpcode, [])];
+ {{rm32,RM32}, {imm8,Imm8}} ->
+ [16#C1 | encode_rm(RM32, SubOpcode, [Imm8])];
+ {{rm16,RM16}, {imm8,Imm8}} ->
+ [?PFX_OPND, 16#C1 | encode_rm(RM16, SubOpcode, [Imm8])]
+ end.
+
+shift_op_sizeof(Opnds) -> % rcl, rcr, rol, ror, sar, shl, shr
+ case Opnds of
+ {{rm32,RM32}, 1} ->
+ 1 + sizeof_rm(RM32);
+ {{rm32,RM32}, cl} ->
+ 1 + sizeof_rm(RM32);
+ {{rm32,RM32}, {imm8,_Imm8}} ->
+ 1 + sizeof_rm(RM32) + 1;
+ {{rm16,RM16}, {imm8,_Imm8}} ->
+ 1 + 1 + sizeof_rm(RM16) + 1
+ end.
+
+ret_encode(Opnds) ->
+ case Opnds of
+ {} ->
+ [16#C3];
+ {{imm16,Imm16}} ->
+ [16#C2 | le16(Imm16, [])]
+ end.
+
+ret_sizeof(Opnds) ->
+ case Opnds of
+ {} ->
+ 1;
+ {{imm16,_}} ->
+ 1 + 2
+ end.
+
+setcc_encode({{cc,CC}, {rm8,RM8}}) ->
+ [16#0F, 16#90 bor CC | encode_rm(RM8, 2#000, [])].
+
+setcc_sizeof({{cc,_}, {rm8,RM8}}) ->
+ 2 + sizeof_rm(RM8).
+
+shd_op_encode(Opcode, Opnds) ->
+ case Opnds of
+ {{rm32,RM32}, {reg32,Reg32}, {imm8,Imm8}} ->
+ [16#0F, Opcode | encode_rm(RM32, Reg32, [Imm8])];
+ {{rm32,RM32}, {reg32,Reg32}, cl} ->
+ [16#0F, Opcode bor 1 | encode_rm(RM32, Reg32, [])]
+ end.
+
+shd_op_sizeof(Opnds) ->
+ case Opnds of
+ {{rm32,RM32}, {reg32,_}, {imm8,_}} ->
+ 2 + sizeof_rm(RM32) + 1;
+ {{rm32,RM32}, {reg32,_}, cl} ->
+ 2 + sizeof_rm(RM32)
+ end.
+
+test_encode(Opnds) ->
+ case Opnds of
+ {eax, {imm32,Imm32}} ->
+ [16#A9 | le32(Imm32, [])];
+ {{rm32,RM32}, {imm32,Imm32}} ->
+ [16#F7 | encode_rm(RM32, 2#000, le32(Imm32, []))];
+ {{rm32,RM32}, {reg32,Reg32}} ->
+ [16#85 | encode_rm(RM32, Reg32, [])]
+ end.
+
+test_sizeof(Opnds) ->
+ case Opnds of
+ {eax, {imm32,_}} ->
+ 1 + 4;
+ {{rm32,RM32}, {imm32,_}} ->
+ 1 + sizeof_rm(RM32) + 4;
+ {{rm32,RM32}, {reg32,_}} ->
+ 1 + sizeof_rm(RM32)
+ end.
+
+fild_encode(Opnds) ->
+ %% The operand cannot be a register!
+ {{rm32, RM32}} = Opnds,
+ [16#DB | encode_rm(RM32, 2#000, [])].
+
+fild_sizeof(Opnds) ->
+ {{rm32, RM32}} = Opnds,
+ 1 + sizeof_rm(RM32).
+
+fld_encode(Opnds) ->
+ case Opnds of
+ {{rm64fp, RM64fp}} ->
+ [16#DD | encode_rm(RM64fp, 2#000, [])];
+ {{fpst, St}} ->
+ [16#D9, 16#C0 bor st(St)]
+ end.
+
+fld_sizeof(Opnds) ->
+ case Opnds of
+ {{rm64fp, RM64fp}} ->
+ 1 + sizeof_rm(RM64fp);
+ {{fpst, _}} ->
+ 2
+ end.
+
+fp_comm_arith_encode(OpCode, Opnds) ->
+ %% fadd, fmul
+ case Opnds of
+ {{rm64fp, RM64fp}} ->
+ [16#DC | encode_rm(RM64fp, OpCode, [])];
+ {{fpst,0}, {fpst,St}} ->
+ [16#D8, (16#C0 bor (OpCode bsl 3)) bor st(St)];
+ {{fpst,St}, {fpst,0}} ->
+ [16#DC, (16#C0 bor (OpCode bsl 3)) bor st(St)]
+ end.
+
+fp_comm_arith_pop_encode(OpCode, Opnds) ->
+ %% faddp, fmulp
+ case Opnds of
+ [] ->
+ [16#DE, 16#C0 bor (OpCode bsl 3) bor st(1)];
+ {{fpst,St},{fpst,0}} ->
+ [16#DE, 16#C0 bor (OpCode bsl 3) bor st(St)]
+ end.
+
+fp_arith_encode(OpCode, Opnds) ->
+ %% fdiv, fsub
+ case Opnds of
+ {{rm64fp, RM64fp}} ->
+ [16#DC | encode_rm(RM64fp, OpCode, [])];
+ {{fpst,0}, {fpst,St}} ->
+ OpCode0 = OpCode band 2#110,
+ [16#D8, 16#C0 bor (OpCode0 bsl 3) bor st(St)];
+ {{fpst,St}, {fpst,0}} ->
+ OpCode0 = OpCode bor 1,
+ [16#DC, 16#C0 bor (OpCode0 bsl 3) bor st(St)]
+ end.
+
+fp_arith_pop_encode(OpCode, Opnds) ->
+ %% fdivp, fsubp
+ OpCode0 = OpCode bor 1,
+ case Opnds of
+ [] ->
+ [16#DE, 16#C8 bor (OpCode0 bsl 3) bor st(1)];
+ {{fpst,St}, {fpst,0}} ->
+ [16#DE, 16#C8 bor (OpCode0 bsl 3) bor st(St)]
+ end.
+
+fp_arith_rev_encode(OpCode, Opnds) ->
+ %% fdivr, fsubr
+ case Opnds of
+ {{rm64fp, RM64fp}} ->
+ [16#DC | encode_rm(RM64fp, OpCode, [])];
+ {{fpst,0}, {fpst,St}} ->
+ OpCode0 = OpCode bor 1,
+ [16#D8, 16#C0 bor (OpCode0 bsl 3) bor st(St)];
+ {{fpst,St}, {fpst,0}} ->
+ OpCode0 = OpCode band 2#110,
+ [16#DC, 16#C0 bor (OpCode0 bsl 3) bor st(St)]
+ end.
+
+fp_arith_rev_pop_encode(OpCode, Opnds) ->
+ %% fdivrp, fsubrp
+ OpCode0 = OpCode band 2#110,
+ case Opnds of
+ [] ->
+ [16#DE, 16#C0 bor (OpCode0 bsl 3) bor st(1)];
+ {{fpst,St}, {fpst, 0}} ->
+ [16#DE, 16#C0 bor (OpCode0 bsl 3) bor st(St)]
+ end.
+
+fp_arith_sizeof(Opnds) ->
+ case Opnds of
+ {{rm64fp, RM64fp}} ->
+ 1 + sizeof_rm(RM64fp);
+ {{fpst,0}, {fpst,_}} ->
+ 2;
+ {{fpst,_}, {fpst,0}} ->
+ 2
+ end.
+
+fst_encode(OpCode, Opnds) ->
+ case Opnds of
+ {{rm64fp, RM64fp}} ->
+ [16#DD | encode_rm(RM64fp, OpCode, [])];
+ {{fpst, St}} ->
+ [16#DD, 16#C0 bor (OpCode bsl 3) bor st(St)]
+ end.
+
+fst_sizeof(Opnds) ->
+ case Opnds of
+ {{rm64fp, RM64fp}} ->
+ 1 + sizeof_rm(RM64fp);
+ {{fpst, _}} ->
+ 2
+ end.
+
+fchs_encode() ->
+ [16#D9, 16#E0].
+fchs_sizeof() ->
+ 2.
+
+ffree_encode({{fpst, St}})->
+ [16#DD, 16#C0 bor st(St)].
+ffree_sizeof() ->
+ 2.
+
+fwait_encode() ->
+ [16#9B].
+fwait_sizeof() ->
+ 1.
+
+fxch_encode(Opnds) ->
+ case Opnds of
+ [] ->
+ [16#D9, 16#C8 bor st(1)];
+ {{fpst, St}} ->
+ [16#D9, 16#C8 bor st(St)]
+ end.
+fxch_sizeof() ->
+ 2.
+
+insn_encode(Op, Opnds, Offset) ->
+ Bytes = insn_encode_internal(Op, Opnds),
+ case has_relocs(Bytes) of
+ false -> % the common case
+ {Bytes, []};
+ _ ->
+ fix_relocs(Bytes, Offset, [], [])
+ end.
+
+has_relocs([{le32,_,_}|_]) -> true;
+has_relocs([_|Bytes]) -> has_relocs(Bytes);
+has_relocs([]) -> false.
+
+fix_relocs([{le32,Tag,Val}|Bytes], Offset, Code, Relocs) ->
+ fix_relocs(Bytes, Offset+4,
+ [16#00, 16#00, 16#00, 16#00 | Code],
+ [{Tag,Offset,Val}|Relocs]);
+fix_relocs([Byte|Bytes], Offset, Code, Relocs) ->
+ fix_relocs(Bytes, Offset+1, [Byte|Code], Relocs);
+fix_relocs([], _Offset, Code, Relocs) ->
+ {lists:reverse(Code), lists:reverse(Relocs)}.
+
+insn_encode_internal(Op, Opnds) ->
+ case Op of
+ 'adc' -> arith_binop_encode(2#010, Opnds);
+ 'add' -> arith_binop_encode(2#000, Opnds);
+ 'and' -> arith_binop_encode(2#100, Opnds);
+ 'bsf' -> bs_op_encode(16#BC, Opnds);
+ 'bsr' -> bs_op_encode(16#BD, Opnds);
+ 'bswap' -> bswap_encode(Opnds);
+ 'bt' -> bt_op_encode(2#100, Opnds);
+ 'btc' -> bt_op_encode(2#111, Opnds);
+ 'btr' -> bt_op_encode(2#110, Opnds);
+ 'bts' -> bt_op_encode(2#101, Opnds);
+ 'call' -> call_encode(Opnds);
+ 'cbw' -> cbw_encode(Opnds);
+ 'cdq' -> nullary_op_encode(16#99, Opnds);
+ 'clc' -> nullary_op_encode(16#F8, Opnds);
+ 'cld' -> nullary_op_encode(16#FC, Opnds);
+ 'cmc' -> nullary_op_encode(16#F5, Opnds);
+ 'cmovcc' -> cmovcc_encode(Opnds);
+ 'cmp' -> arith_binop_encode(2#111, Opnds);
+ 'cwde' -> nullary_op_encode(16#98, Opnds);
+ 'dec' -> incdec_encode(2#001, Opnds);
+ 'div' -> arith_unop_encode(2#110, Opnds);
+ 'enter' -> enter_encode(Opnds);
+ 'fadd' -> fp_comm_arith_encode(2#000, Opnds);
+ 'faddp' -> fp_comm_arith_pop_encode(2#000, Opnds);
+ 'fchs' -> fchs_encode();
+ 'fdiv' -> fp_arith_encode(2#110, Opnds);
+ 'fdivp' -> fp_arith_pop_encode(2#110, Opnds);
+ 'fdivr' -> fp_arith_rev_encode(2#111, Opnds);
+ 'fdivrp' -> fp_arith_rev_pop_encode(2#111, Opnds);
+ 'ffree' -> ffree_encode(Opnds);
+ 'fild' -> fild_encode(Opnds);
+ 'fld' -> fld_encode(Opnds);
+ 'fmul' -> fp_comm_arith_encode(2#001, Opnds);
+ 'fmulp' -> fp_comm_arith_pop_encode(2#001, Opnds);
+ 'fst' -> fst_encode(2#010, Opnds);
+ 'fstp' -> fst_encode(2#011, Opnds);
+ 'fsub' -> fp_arith_encode(2#100, Opnds);
+ 'fsubp' -> fp_arith_pop_encode(2#100, Opnds);
+ 'fsubr' -> fp_arith_rev_encode(2#101, Opnds);
+ 'fsubrp' -> fp_arith_rev_pop_encode(2#101, Opnds);
+ 'fwait' -> fwait_encode();
+ 'fxch' -> fxch_encode(Opnds);
+ 'idiv' -> arith_unop_encode(2#111, Opnds);
+ 'imul' -> imul_encode(Opnds);
+ 'inc' -> incdec_encode(2#000, Opnds);
+ 'into' -> nullary_op_encode(16#CE, Opnds);
+ 'jcc' -> jcc_encode(Opnds);
+ 'jecxz' -> jmp8_op_encode(16#E3, Opnds);
+ 'jmp' -> jmp_encode(Opnds);
+ 'lea' -> lea_encode(Opnds);
+ 'leave' -> nullary_op_encode(16#C9, Opnds);
+ 'loop' -> jmp8_op_encode(16#E2, Opnds);
+ 'loope' -> jmp8_op_encode(16#E1, Opnds);
+ 'loopne' -> jmp8_op_encode(16#E0, Opnds);
+ 'mov' -> mov_encode(Opnds);
+ 'movsx' -> movx_op_encode(16#BE, Opnds);
+ 'movzx' -> movx_op_encode(16#B6, Opnds);
+ 'mul' -> arith_unop_encode(2#100, Opnds);
+ 'neg' -> arith_unop_encode(2#011, Opnds);
+ 'nop' -> nullary_op_encode(16#90, Opnds);
+ 'not' -> arith_unop_encode(2#010, Opnds);
+ 'or' -> arith_binop_encode(2#001, Opnds);
+ 'pop' -> pop_encode(Opnds);
+ 'prefix_fs' -> nullary_op_encode(16#64, Opnds);
+ 'push' -> push_encode(Opnds);
+ 'rcl' -> shift_op_encode(2#010, Opnds);
+ 'rcr' -> shift_op_encode(2#011, Opnds);
+ 'ret' -> ret_encode(Opnds);
+ 'rol' -> shift_op_encode(2#000, Opnds);
+ 'ror' -> shift_op_encode(2#001, Opnds);
+ 'sar' -> shift_op_encode(2#111, Opnds);
+ 'sbb' -> arith_binop_encode(2#011, Opnds);
+ 'setcc' -> setcc_encode(Opnds);
+ 'shl' -> shift_op_encode(2#100, Opnds);
+ 'shld' -> shd_op_encode(16#A4, Opnds);
+ 'shr' -> shift_op_encode(2#101, Opnds);
+ 'shrd' -> shd_op_encode(16#AC, Opnds);
+ 'stc' -> nullary_op_encode(16#F9, Opnds);
+ 'std' -> nullary_op_encode(16#FD, Opnds);
+ 'sub' -> arith_binop_encode(2#101, Opnds);
+ 'test' -> test_encode(Opnds);
+ 'xor' -> arith_binop_encode(2#110, Opnds);
+ _ -> exit({?MODULE,insn_encode,Op})
+ end.
+
+insn_sizeof(Op, Opnds) ->
+ case Op of
+ 'adc' -> arith_binop_sizeof(Opnds);
+ 'add' -> arith_binop_sizeof(Opnds);
+ 'and' -> arith_binop_sizeof(Opnds);
+ 'bsf' -> bs_op_sizeof(Opnds);
+ 'bsr' -> bs_op_sizeof(Opnds);
+ 'bswap' -> bswap_sizeof(Opnds);
+ 'bt' -> bt_op_sizeof(Opnds);
+ 'btc' -> bt_op_sizeof(Opnds);
+ 'btr' -> bt_op_sizeof(Opnds);
+ 'bts' -> bt_op_sizeof(Opnds);
+ 'call' -> call_sizeof(Opnds);
+ 'cbw' -> cbw_sizeof(Opnds);
+ 'cdq' -> nullary_op_sizeof(Opnds);
+ 'clc' -> nullary_op_sizeof(Opnds);
+ 'cld' -> nullary_op_sizeof(Opnds);
+ 'cmc' -> nullary_op_sizeof(Opnds);
+ 'cmovcc' -> cmovcc_sizeof(Opnds);
+ 'cmp' -> arith_binop_sizeof(Opnds);
+ 'cwde' -> nullary_op_sizeof(Opnds);
+ 'dec' -> incdec_sizeof(Opnds);
+ 'div' -> arith_unop_sizeof(Opnds);
+ 'enter' -> enter_sizeof(Opnds);
+ 'fadd' -> fp_arith_sizeof(Opnds);
+ 'faddp' -> fp_arith_sizeof(Opnds);
+ 'fchs' -> fchs_sizeof();
+ 'fdiv' -> fp_arith_sizeof(Opnds);
+ 'fdivp' -> fp_arith_sizeof(Opnds);
+ 'fdivr' -> fp_arith_sizeof(Opnds);
+ 'fdivrp' -> fp_arith_sizeof(Opnds);
+ 'ffree' -> ffree_sizeof();
+ 'fild' -> fild_sizeof(Opnds);
+ 'fld' -> fld_sizeof(Opnds);
+ 'fmul' -> fp_arith_sizeof(Opnds);
+ 'fmulp' -> fp_arith_sizeof(Opnds);
+ 'fst' -> fst_sizeof(Opnds);
+ 'fstp' -> fst_sizeof(Opnds);
+ 'fsub' -> fp_arith_sizeof(Opnds);
+ 'fsubp' -> fp_arith_sizeof(Opnds);
+ 'fsubr' -> fp_arith_sizeof(Opnds);
+ 'fsubrp' -> fp_arith_sizeof(Opnds);
+ 'fwait' -> fwait_sizeof();
+ 'fxch' -> fxch_sizeof();
+ 'idiv' -> arith_unop_sizeof(Opnds);
+ 'imul' -> imul_sizeof(Opnds);
+ 'inc' -> incdec_sizeof(Opnds);
+ 'into' -> nullary_op_sizeof(Opnds);
+ 'jcc' -> jcc_sizeof(Opnds);
+ 'jecxz' -> jmp8_op_sizeof(Opnds);
+ 'jmp' -> jmp_sizeof(Opnds);
+ 'lea' -> lea_sizeof(Opnds);
+ 'leave' -> nullary_op_sizeof(Opnds);
+ 'loop' -> jmp8_op_sizeof(Opnds);
+ 'loope' -> jmp8_op_sizeof(Opnds);
+ 'loopne' -> jmp8_op_sizeof(Opnds);
+ 'mov' -> mov_sizeof(Opnds);
+ 'movsx' -> movx_op_sizeof(Opnds);
+ 'movzx' -> movx_op_sizeof(Opnds);
+ 'mul' -> arith_unop_sizeof(Opnds);
+ 'neg' -> arith_unop_sizeof(Opnds);
+ 'nop' -> nullary_op_sizeof(Opnds);
+ 'not' -> arith_unop_sizeof(Opnds);
+ 'or' -> arith_binop_sizeof(Opnds);
+ 'pop' -> pop_sizeof(Opnds);
+ 'prefix_fs' -> nullary_op_sizeof(Opnds);
+ 'push' -> push_sizeof(Opnds);
+ 'rcl' -> shift_op_sizeof(Opnds);
+ 'rcr' -> shift_op_sizeof(Opnds);
+ 'ret' -> ret_sizeof(Opnds);
+ 'rol' -> shift_op_sizeof(Opnds);
+ 'ror' -> shift_op_sizeof(Opnds);
+ 'sar' -> shift_op_sizeof(Opnds);
+ 'sbb' -> arith_binop_sizeof(Opnds);
+ 'setcc' -> setcc_sizeof(Opnds);
+ 'shl' -> shift_op_sizeof(Opnds);
+ 'shld' -> shd_op_sizeof(Opnds);
+ 'shr' -> shift_op_sizeof(Opnds);
+ 'shrd' -> shd_op_sizeof(Opnds);
+ 'stc' -> nullary_op_sizeof(Opnds);
+ 'std' -> nullary_op_sizeof(Opnds);
+ 'sub' -> arith_binop_sizeof(Opnds);
+ 'test' -> test_sizeof(Opnds);
+ 'xor' -> arith_binop_sizeof(Opnds);
+ _ -> exit({?MODULE,insn_sizeof,Op})
+ end.
+
+%%=====================================================================
+%% testing interface
+%%=====================================================================
+
+-ifdef(DO_HIPE_X86_ENCODE_TEST).
+
+say(OS, Str) ->
+ file:write(OS, Str).
+
+digit16(Dig0) ->
+ Dig = Dig0 band 16#F,
+ if Dig >= 16#A -> $A + (Dig - 16#A);
+ true -> $0 + Dig
+ end.
+
+say_byte(OS, Byte) ->
+ say(OS, "0x"),
+ say(OS, [digit16(Byte bsr 4)]),
+ say(OS, [digit16(Byte)]).
+
+init(OS) ->
+ say(OS, "\t.text\n").
+
+say_bytes(OS, Byte0, Bytes0) ->
+ say_byte(OS, Byte0),
+ case Bytes0 of
+ [] ->
+ say(OS, "\n");
+ [Byte1|Bytes1] ->
+ say(OS, ","),
+ say_bytes(OS, Byte1, Bytes1)
+ end.
+
+t(OS, Op, Opnds) ->
+ insn_sizeof(Op, Opnds),
+ {[Byte|Bytes],[]} = insn_encode(Op, Opnds, 0),
+ say(OS, "\t.byte "),
+ say_bytes(OS, Byte, Bytes).
+
+dotest1(OS) ->
+ init(OS),
+ % exercise all rm32 types
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp32(16#87654321)}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_sib(sib(?ECX))}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_sib(sib(?ECX,sindex(2#10,?EDI)))}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp32_sindex(16#87654321)}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp32_sindex(16#87654321,sindex(2#10,?EDI))}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_base(?ECX)}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp8_sib(16#03,sib(?ECX))}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp8_sib(16#03,sib(?ECX,sindex(2#10,?EDI)))}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp8_base(16#3,?ECX)}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp32_sib(16#87654321,sib(?ECX))}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp32_sib(16#87654321,sib(?ECX,sindex(2#10,?EDI)))}}),
+ t(OS,lea,{{reg32,?EAX},{ea,ea_disp32_base(16#87654321,?EBP)}}),
+ t(OS,call,{{rm32,rm_reg(?EAX)}}),
+ t(OS,call,{{rm32,rm_mem(ea_disp32_sindex(16#87654321,sindex(2#10,?EDI)))}}),
+ t(OS,call,{{rel32,-5}}),
+ % default parameters for the tests below
+ Word32 = 16#87654321,
+ Word16 = 16#F00F,
+ Word8 = 16#80,
+ Imm32 = {imm32,Word32},
+ Imm16 = {imm16,Word16},
+ Imm8 = {imm8,Word8},
+ RM32 = {rm32,rm_reg(?EDX)},
+ RM16 = {rm16,rm_reg(?EDX)},
+ RM8 = {rm8,rm_reg(?EDX)},
+ Rel32 = {rel32,Word32},
+ Rel8 = {rel8,Word8},
+ Moffs32 = {moffs32,Word32},
+ Moffs16 = {moffs16,Word32},
+ Moffs8 = {moffs8,Word32},
+ CC = {cc,?CC_G},
+ Reg32 = {reg32,?EAX},
+ Reg16 = {reg16,?EAX},
+ Reg8 = {reg8,?AH},
+ EA = {ea,ea_base(?ECX)},
+ % exercise each instruction definition
+ t(OS,'adc',{eax,Imm32}),
+ t(OS,'adc',{RM32,Imm32}),
+ t(OS,'adc',{RM32,Imm8}),
+ t(OS,'adc',{RM32,Reg32}),
+ t(OS,'adc',{Reg32,RM32}),
+ t(OS,'add',{eax,Imm32}),
+ t(OS,'add',{RM32,Imm32}),
+ t(OS,'add',{RM32,Imm8}),
+ t(OS,'add',{RM32,Reg32}),
+ t(OS,'add',{Reg32,RM32}),
+ t(OS,'and',{eax,Imm32}),
+ t(OS,'and',{RM32,Imm32}),
+ t(OS,'and',{RM32,Imm8}),
+ t(OS,'and',{RM32,Reg32}),
+ t(OS,'and',{Reg32,RM32}),
+ t(OS,'bsf',{Reg32,RM32}),
+ t(OS,'bsr',{Reg32,RM32}),
+ t(OS,'bswap',{Reg32}),
+ t(OS,'bt',{RM32,Reg32}),
+ t(OS,'bt',{RM32,Imm8}),
+ t(OS,'btc',{RM32,Reg32}),
+ t(OS,'btc',{RM32,Imm8}),
+ t(OS,'btr',{RM32,Reg32}),
+ t(OS,'btr',{RM32,Imm8}),
+ t(OS,'bts',{RM32,Reg32}),
+ t(OS,'bts',{RM32,Imm8}),
+ t(OS,'call',{Rel32}),
+ t(OS,'call',{RM32}),
+ t(OS,'cbw',{}),
+ t(OS,'cdq',{}),
+ t(OS,'clc',{}),
+ t(OS,'cld',{}),
+ t(OS,'cmc',{}),
+ t(OS,'cmovcc',{CC,Reg32,RM32}),
+ t(OS,'cmp',{eax,Imm32}),
+ t(OS,'cmp',{RM32,Imm32}),
+ t(OS,'cmp',{RM32,Imm8}),
+ t(OS,'cmp',{RM32,Reg32}),
+ t(OS,'cmp',{Reg32,RM32}),
+ t(OS,'cwde',{}),
+ t(OS,'dec',{RM32}),
+ t(OS,'dec',{Reg32}),
+ t(OS,'div',{RM32}),
+ t(OS,'enter',{Imm16,{imm8,3}}),
+ t(OS,'idiv',{RM32}),
+ t(OS,'imul',{RM32}),
+ t(OS,'imul',{Reg32,RM32}),
+ t(OS,'imul',{Reg32,RM32,Imm8}),
+ t(OS,'imul',{Reg32,RM32,Imm32}),
+ t(OS,'inc',{RM32}),
+ t(OS,'inc',{Reg32}),
+ t(OS,'into',{}),
+ t(OS,'jcc',{CC,Rel8}),
+ t(OS,'jcc',{CC,Rel32}),
+ t(OS,'jecxz',{Rel8}),
+ t(OS,'jmp',{Rel8}),
+ t(OS,'jmp',{Rel32}),
+ t(OS,'jmp',{RM32}),
+ t(OS,'lea',{Reg32,EA}),
+ t(OS,'leave',{}),
+ t(OS,'loop',{Rel8}),
+ t(OS,'loope',{Rel8}),
+ t(OS,'loopne',{Rel8}),
+ t(OS,'mov',{RM8,Reg8}),
+ t(OS,'mov',{RM16,Reg16}),
+ t(OS,'mov',{RM32,Reg32}),
+ t(OS,'mov',{Reg8,RM8}),
+ t(OS,'mov',{Reg16,RM16}),
+ t(OS,'mov',{Reg32,RM32}),
+ t(OS,'mov',{al,Moffs8}),
+ t(OS,'mov',{ax,Moffs16}),
+ t(OS,'mov',{eax,Moffs32}),
+ t(OS,'mov',{Moffs8,al}),
+ t(OS,'mov',{Moffs16,ax}),
+ t(OS,'mov',{Moffs32,eax}),
+ t(OS,'mov',{Reg8,Imm8}),
+ t(OS,'mov',{Reg16,Imm16}),
+ t(OS,'mov',{Reg32,Imm32}),
+ t(OS,'mov',{RM8,Imm8}),
+ t(OS,'mov',{RM16,Imm16}),
+ t(OS,'mov',{RM32,Imm32}),
+ t(OS,'movsx',{Reg16,RM8}),
+ t(OS,'movsx',{Reg32,RM8}),
+ t(OS,'movsx',{Reg32,RM16}),
+ t(OS,'movzx',{Reg16,RM8}),
+ t(OS,'movzx',{Reg32,RM8}),
+ t(OS,'movzx',{Reg32,RM16}),
+ t(OS,'mul',{RM32}),
+ t(OS,'neg',{RM32}),
+ t(OS,'nop',{}),
+ t(OS,'not',{RM32}),
+ t(OS,'or',{eax,Imm32}),
+ t(OS,'or',{RM32,Imm32}),
+ t(OS,'or',{RM32,Imm8}),
+ t(OS,'or',{RM32,Reg32}),
+ t(OS,'or',{Reg32,RM32}),
+ t(OS,'pop',{RM32}),
+ t(OS,'pop',{Reg32}),
+ t(OS,'push',{RM32}),
+ t(OS,'push',{Reg32}),
+ t(OS,'push',{Imm8}),
+ t(OS,'push',{Imm32}),
+ t(OS,'rcl',{RM32,1}),
+ t(OS,'rcl',{RM32,cl}),
+ t(OS,'rcl',{RM32,Imm8}),
+ t(OS,'rcl',{RM16,Imm8}),
+ t(OS,'rcr',{RM32,1}),
+ t(OS,'rcr',{RM32,cl}),
+ t(OS,'rcr',{RM32,Imm8}),
+ t(OS,'rcr',{RM16,Imm8}),
+ t(OS,'ret',{}),
+ t(OS,'ret',{Imm16}),
+ t(OS,'rol',{RM32,1}),
+ t(OS,'rol',{RM32,cl}),
+ t(OS,'rol',{RM32,Imm8}),
+ t(OS,'rol',{RM16,Imm8}),
+ t(OS,'ror',{RM32,1}),
+ t(OS,'ror',{RM32,cl}),
+ t(OS,'ror',{RM32,Imm8}),
+ t(OS,'ror',{RM16,Imm8}),
+ t(OS,'sar',{RM32,1}),
+ t(OS,'sar',{RM32,cl}),
+ t(OS,'sar',{RM32,Imm8}),
+ t(OS,'sar',{RM16,Imm8}),
+ t(OS,'sbb',{eax,Imm32}),
+ t(OS,'sbb',{RM32,Imm32}),
+ t(OS,'sbb',{RM32,Imm8}),
+ t(OS,'sbb',{RM32,Reg32}),
+ t(OS,'sbb',{Reg32,RM32}),
+ t(OS,'setcc',{CC,RM8}),
+ t(OS,'shl',{RM32,1}),
+ t(OS,'shl',{RM32,cl}),
+ t(OS,'shl',{RM32,Imm8}),
+ t(OS,'shl',{RM16,Imm8}),
+ t(OS,'shld',{RM32,Reg32,Imm8}),
+ t(OS,'shld',{RM32,Reg32,cl}),
+ t(OS,'shr',{RM32,1}),
+ t(OS,'shr',{RM32,cl}),
+ t(OS,'shr',{RM32,Imm8}),
+ t(OS,'shr',{RM16,Imm8}),
+ t(OS,'shrd',{RM32,Reg32,Imm8}),
+ t(OS,'shrd',{RM32,Reg32,cl}),
+ t(OS,'stc',{}),
+ t(OS,'std',{}),
+ t(OS,'sub',{eax,Imm32}),
+ t(OS,'sub',{RM32,Imm32}),
+ t(OS,'sub',{RM32,Imm8}),
+ t(OS,'sub',{RM32,Reg32}),
+ t(OS,'sub',{Reg32,RM32}),
+ t(OS,'test',{eax,Imm32}),
+ t(OS,'test',{RM32,Imm32}),
+ t(OS,'test',{RM32,Reg32}),
+ t(OS,'xor',{eax,Imm32}),
+ t(OS,'xor',{RM32,Imm32}),
+ t(OS,'xor',{RM32,Imm8}),
+ t(OS,'xor',{RM32,Reg32}),
+ t(OS,'xor',{Reg32,RM32}),
+ t(OS,'prefix_fs',{}), t(OS,'add',{{reg32,?EAX},{rm32,rm_mem(ea_disp32(16#20))}}),
+ [].
+
+dotest() -> dotest1(group_leader()). % stdout == group_leader
+
+dotest(File) ->
+ {ok,OS} = file:open(File, [write]),
+ dotest1(OS),
+ file:close(OS).
+-endif.
generated by cgit v1.2.3 (git 2.25.1) at 2024-11-02 17:56:51 +0000