382 lines
14 KiB
Diff
382 lines
14 KiB
Diff
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commit 81d9832226d6e3d1ee78ee3133189d7b520e7eea
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Author: Julian Seward <jseward@acm.org>
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Date: Tue Nov 20 11:36:53 2018 +0100
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ppc front end: use new IROps added in 42719898.
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This pertains to bug 386945.
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VEX/priv/guest_ppc_toIR.c:
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gen_POPCOUNT: use Iop_PopCount{32,64} where possible.
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gen_vpopcntd_mode32: use Iop_PopCount32.
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for cntlz{w,d}, use Iop_CtzNat{32,64}.
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gen_byterev32: use Iop_Reverse8sIn32_x1 instead of lengthy sequence.
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verbose_Clz32: remove (was unused anyway).
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diff --git a/VEX/priv/guest_ppc_toIR.c b/VEX/priv/guest_ppc_toIR.c
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index cb1cae1..8977d4f 100644
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--- a/VEX/priv/guest_ppc_toIR.c
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+++ b/VEX/priv/guest_ppc_toIR.c
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@@ -1595,7 +1595,8 @@ typedef enum {
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/* Generate an IR sequence to do a popcount operation on the supplied
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IRTemp, and return a new IRTemp holding the result. 'ty' may be
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Ity_I32 or Ity_I64 only. */
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-static IRTemp gen_POPCOUNT ( IRType ty, IRTemp src, _popcount_data_type data_type )
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+static IRTemp gen_POPCOUNT ( IRType ty, IRTemp src,
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+ _popcount_data_type data_type )
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{
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/* Do count across 2^data_type bits,
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byte: data_type = 3
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@@ -1611,6 +1612,22 @@ static IRTemp gen_POPCOUNT ( IRType ty, IRTemp src, _popcount_data_type data_typ
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vassert(ty == Ity_I64 || ty == Ity_I32);
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+ // Use a single IROp in cases where we can.
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+
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+ if (ty == Ity_I64 && data_type == DWORD) {
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+ IRTemp res = newTemp(Ity_I64);
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+ assign(res, unop(Iop_PopCount64, mkexpr(src)));
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+ return res;
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+ }
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+
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+ if (ty == Ity_I32 && data_type == WORD) {
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+ IRTemp res = newTemp(Ity_I32);
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+ assign(res, unop(Iop_PopCount32, mkexpr(src)));
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+ return res;
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+ }
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+
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+ // For the rest, we have to do it the slow way.
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+
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if (ty == Ity_I32) {
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for (idx = 0; idx < WORD; idx++) {
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@@ -1638,7 +1655,7 @@ static IRTemp gen_POPCOUNT ( IRType ty, IRTemp src, _popcount_data_type data_typ
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return nyu;
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}
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-// else, ty == Ity_I64
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+ // else, ty == Ity_I64
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vassert(mode64);
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for (i = 0; i < DWORD; i++) {
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@@ -1670,52 +1687,15 @@ static IRTemp gen_POPCOUNT ( IRType ty, IRTemp src, _popcount_data_type data_typ
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*/
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static IRTemp gen_vpopcntd_mode32 ( IRTemp src1, IRTemp src2 )
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{
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- Int i, shift[6];
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- IRTemp mask[6];
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- IRTemp old = IRTemp_INVALID;
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- IRTemp nyu1 = IRTemp_INVALID;
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- IRTemp nyu2 = IRTemp_INVALID;
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IRTemp retval = newTemp(Ity_I64);
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vassert(!mode64);
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- for (i = 0; i < WORD; i++) {
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- mask[i] = newTemp(Ity_I32);
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- shift[i] = 1 << i;
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- }
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- assign(mask[0], mkU32(0x55555555));
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- assign(mask[1], mkU32(0x33333333));
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- assign(mask[2], mkU32(0x0F0F0F0F));
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- assign(mask[3], mkU32(0x00FF00FF));
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- assign(mask[4], mkU32(0x0000FFFF));
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- old = src1;
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- for (i = 0; i < WORD; i++) {
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- nyu1 = newTemp(Ity_I32);
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- assign(nyu1,
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- binop(Iop_Add32,
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- binop(Iop_And32,
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- mkexpr(old),
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- mkexpr(mask[i])),
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- binop(Iop_And32,
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- binop(Iop_Shr32, mkexpr(old), mkU8(shift[i])),
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- mkexpr(mask[i]))));
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- old = nyu1;
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- }
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-
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- old = src2;
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- for (i = 0; i < WORD; i++) {
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- nyu2 = newTemp(Ity_I32);
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- assign(nyu2,
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- binop(Iop_Add32,
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- binop(Iop_And32,
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- mkexpr(old),
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- mkexpr(mask[i])),
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- binop(Iop_And32,
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- binop(Iop_Shr32, mkexpr(old), mkU8(shift[i])),
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- mkexpr(mask[i]))));
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- old = nyu2;
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- }
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- assign(retval, unop(Iop_32Uto64, binop(Iop_Add32, mkexpr(nyu1), mkexpr(nyu2))));
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+ assign(retval,
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+ unop(Iop_32Uto64,
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+ binop(Iop_Add32,
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+ unop(Iop_PopCount32, mkexpr(src1)),
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+ unop(Iop_PopCount32, mkexpr(src2)))));
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return retval;
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}
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@@ -5715,7 +5695,7 @@ static Bool dis_modulo_int ( UInt theInstr )
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rA_address, rS_address);
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assign( rS, getIReg( rS_address ) );
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- assign( result, unop( Iop_Ctz32,
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+ assign( result, unop( Iop_CtzNat32,
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unop( Iop_64to32, mkexpr( rS ) ) ) );
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assign( rA, binop( Iop_32HLto64, mkU32( 0 ), mkexpr( result ) ) );
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@@ -5746,7 +5726,7 @@ static Bool dis_modulo_int ( UInt theInstr )
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rA_address, rS_address);
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assign( rS, getIReg( rS_address ) );
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- assign( rA, unop( Iop_Ctz64, mkexpr( rS ) ) );
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+ assign( rA, unop( Iop_CtzNat64, mkexpr( rS ) ) );
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if ( flag_rC == 1 )
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set_CR0( mkexpr( rA ) );
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@@ -6307,7 +6287,6 @@ static Bool dis_int_logic ( UInt theInstr )
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IRTemp rS = newTemp(ty);
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IRTemp rA = newTemp(ty);
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IRTemp rB = newTemp(ty);
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- IRExpr* irx;
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Bool do_rc = False;
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assign( rS, getIReg(rS_addr) );
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@@ -6404,26 +6383,16 @@ static Bool dis_int_logic ( UInt theInstr )
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break;
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case 0x01A: { // cntlzw (Count Leading Zeros Word, PPC32 p371)
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- IRExpr* lo32;
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if (rB_addr!=0) {
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vex_printf("dis_int_logic(ppc)(cntlzw,rB_addr)\n");
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return False;
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}
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- DIP("cntlzw%s r%u,r%u\n",
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- flag_rC ? ".":"", rA_addr, rS_addr);
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+ DIP("cntlzw%s r%u,r%u\n", flag_rC ? ".":"", rA_addr, rS_addr);
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// mode64: count in low word only
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- lo32 = mode64 ? unop(Iop_64to32, mkexpr(rS)) : mkexpr(rS);
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-
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- // Iop_Clz32 undefined for arg==0, so deal with that case:
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- irx = binop(Iop_CmpNE32, lo32, mkU32(0));
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- assign(rA, mkWidenFrom32(ty,
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- IRExpr_ITE( irx,
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- unop(Iop_Clz32, lo32),
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- mkU32(32)),
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- False));
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-
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- // TODO: alternatively: assign(rA, verbose_Clz32(rS));
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+ IRExpr* lo32 = mode64 ? unop(Iop_64to32, mkexpr(rS)) : mkexpr(rS);
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+ IRExpr* res32 = unop(Iop_ClzNat32, lo32);
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+ assign(rA, mode64 ? unop(Iop_32Uto64, res32) : res32);
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break;
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}
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@@ -6521,14 +6490,8 @@ static Bool dis_int_logic ( UInt theInstr )
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vex_printf("dis_int_logic(ppc)(cntlzd,rB_addr)\n");
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return False;
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}
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- DIP("cntlzd%s r%u,r%u\n",
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- flag_rC ? ".":"", rA_addr, rS_addr);
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- // Iop_Clz64 undefined for arg==0, so deal with that case:
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- irx = binop(Iop_CmpNE64, mkexpr(rS), mkU64(0));
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- assign(rA, IRExpr_ITE( irx,
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- unop(Iop_Clz64, mkexpr(rS)),
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- mkU64(64) ));
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- // TODO: alternatively: assign(rA, verbose_Clz64(rS));
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+ DIP("cntlzd%s r%u,r%u\n", flag_rC ? ".":"", rA_addr, rS_addr);
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+ assign(rA, unop(Iop_ClzNat64, mkexpr(rS)));
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break;
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case 0x1FC: // cmpb (Power6: compare bytes)
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@@ -6574,8 +6537,9 @@ static Bool dis_int_logic ( UInt theInstr )
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putFReg( rS_addr, mkexpr(frA));
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return True;
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}
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- case 0x1FA: // popcntd (population count doubleword
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+ case 0x1FA: // popcntd (population count doubleword)
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{
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+ vassert(mode64);
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DIP("popcntd r%u,r%u\n", rA_addr, rS_addr);
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IRTemp result = gen_POPCOUNT(ty, rS, DWORD);
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putIReg( rA_addr, mkexpr(result) );
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@@ -9154,18 +9118,7 @@ static Bool dis_int_shift ( UInt theInstr )
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static IRExpr* /* :: Ity_I32 */ gen_byterev32 ( IRTemp t )
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{
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vassert(typeOfIRTemp(irsb->tyenv, t) == Ity_I32);
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- return
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- binop(Iop_Or32,
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- binop(Iop_Shl32, mkexpr(t), mkU8(24)),
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- binop(Iop_Or32,
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- binop(Iop_And32, binop(Iop_Shl32, mkexpr(t), mkU8(8)),
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- mkU32(0x00FF0000)),
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- binop(Iop_Or32,
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- binop(Iop_And32, binop(Iop_Shr32, mkexpr(t), mkU8(8)),
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- mkU32(0x0000FF00)),
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- binop(Iop_And32, binop(Iop_Shr32, mkexpr(t), mkU8(24)),
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- mkU32(0x000000FF) )
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- )));
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+ return unop(Iop_Reverse8sIn32_x1, mkexpr(t));
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}
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/* Generates code to swap the byte order in the lower half of an Ity_I32,
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@@ -9225,6 +9178,10 @@ static Bool dis_int_ldst_rev ( UInt theInstr )
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case 0x214: // ldbrx (Load Doubleword Byte-Reverse Indexed)
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{
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+ // JRS FIXME:
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+ // * is the host_endness conditional below actually necessary?
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+ // * can we just do a 64-bit load followed by by Iop_Reverse8sIn64_x1?
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+ // That would be a lot more efficient.
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IRExpr * nextAddr;
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IRTemp w3 = newTemp( Ity_I32 );
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IRTemp w4 = newTemp( Ity_I32 );
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@@ -17056,8 +17013,8 @@ dis_av_count_bitTranspose ( UInt theInstr, UInt opc2 )
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case 0x7C3: // vpopcntd
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{
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if (mode64) {
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- /* Break vector into 64-bit double words and do the population count
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- * on each double word.
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+ /* Break vector into 64-bit double words and do the population
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+ count on each double word.
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*/
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IRType ty = Ity_I64;
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IRTemp bits0_63 = newTemp(Ity_I64);
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@@ -17077,15 +17034,16 @@ dis_av_count_bitTranspose ( UInt theInstr, UInt opc2 )
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mkexpr( cnt_bits0_63 ) ) );
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} else {
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/* Break vector into 32-bit words and do the population count
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- * on each doubleword.
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+ on each 32-bit word.
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*/
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IRTemp bits0_31, bits32_63, bits64_95, bits96_127;
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bits0_31 = bits32_63 = bits64_95 = bits96_127 = IRTemp_INVALID;
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- IRTemp cnt_bits0_63 = newTemp(Ity_I64);
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+ IRTemp cnt_bits0_63 = newTemp(Ity_I64);
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IRTemp cnt_bits64_127 = newTemp(Ity_I64);
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DIP("vpopcntd v%d,v%d\n", vRT_addr, vRB_addr);
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- breakV128to4x32(mkexpr( vB), &bits96_127, &bits64_95, &bits32_63, &bits0_31 );
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+ breakV128to4x32(mkexpr( vB), &bits96_127, &bits64_95,
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+ &bits32_63, &bits0_31 );
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cnt_bits0_63 = gen_vpopcntd_mode32(bits0_31, bits32_63);
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cnt_bits64_127 = gen_vpopcntd_mode32(bits64_95, bits96_127);
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@@ -29103,10 +29061,12 @@ DisResult disInstr_PPC_WRK (
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/* Miscellaneous ISA 2.06 instructions */
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case 0x1FA: // popcntd
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+ if (!mode64) goto decode_failure;
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+ /* else fallthru */
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case 0x17A: // popcntw
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case 0x7A: // popcntb
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- if (dis_int_logic( theInstr )) goto decode_success;
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- goto decode_failure;
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+ if (dis_int_logic( theInstr )) goto decode_success;
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+ goto decode_failure;
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case 0x0FC: // bpermd
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if (!mode64) goto decode_failure;
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@@ -29669,94 +29629,6 @@ DisResult disInstr_PPC ( IRSB* irsb_IN,
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return dres;
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}
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-
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-/*------------------------------------------------------------*/
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-/*--- Unused stuff ---*/
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-/*------------------------------------------------------------*/
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-
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-///* A potentially more memcheck-friendly implementation of Clz32, with
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-// the boundary case Clz32(0) = 32, which is what ppc requires. */
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-//
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-//static IRExpr* /* :: Ity_I32 */ verbose_Clz32 ( IRTemp arg )
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-//{
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-// /* Welcome ... to SSA R Us. */
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-// IRTemp n1 = newTemp(Ity_I32);
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-// IRTemp n2 = newTemp(Ity_I32);
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-// IRTemp n3 = newTemp(Ity_I32);
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-// IRTemp n4 = newTemp(Ity_I32);
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-// IRTemp n5 = newTemp(Ity_I32);
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-// IRTemp n6 = newTemp(Ity_I32);
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-// IRTemp n7 = newTemp(Ity_I32);
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-// IRTemp n8 = newTemp(Ity_I32);
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-// IRTemp n9 = newTemp(Ity_I32);
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-// IRTemp n10 = newTemp(Ity_I32);
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-// IRTemp n11 = newTemp(Ity_I32);
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-// IRTemp n12 = newTemp(Ity_I32);
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-//
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-// /* First, propagate the most significant 1-bit into all lower
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-// positions in the word. */
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-// /* unsigned int clz ( unsigned int n )
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-// {
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-// n |= (n >> 1);
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-// n |= (n >> 2);
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-// n |= (n >> 4);
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-// n |= (n >> 8);
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-// n |= (n >> 16);
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-// return bitcount(~n);
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-// }
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-// */
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-// assign(n1, mkexpr(arg));
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-// assign(n2, binop(Iop_Or32, mkexpr(n1), binop(Iop_Shr32, mkexpr(n1), mkU8(1))));
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-// assign(n3, binop(Iop_Or32, mkexpr(n2), binop(Iop_Shr32, mkexpr(n2), mkU8(2))));
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-// assign(n4, binop(Iop_Or32, mkexpr(n3), binop(Iop_Shr32, mkexpr(n3), mkU8(4))));
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-// assign(n5, binop(Iop_Or32, mkexpr(n4), binop(Iop_Shr32, mkexpr(n4), mkU8(8))));
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-// assign(n6, binop(Iop_Or32, mkexpr(n5), binop(Iop_Shr32, mkexpr(n5), mkU8(16))));
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-// /* This gives a word of the form 0---01---1. Now invert it, giving
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-// a word of the form 1---10---0, then do a population-count idiom
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-// (to count the 1s, which is the number of leading zeroes, or 32
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-// if the original word was 0. */
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-// assign(n7, unop(Iop_Not32, mkexpr(n6)));
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-//
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-// /* unsigned int bitcount ( unsigned int n )
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-// {
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|
-// n = n - ((n >> 1) & 0x55555555);
|
||
|
-// n = (n & 0x33333333) + ((n >> 2) & 0x33333333);
|
||
|
-// n = (n + (n >> 4)) & 0x0F0F0F0F;
|
||
|
-// n = n + (n >> 8);
|
||
|
-// n = (n + (n >> 16)) & 0x3F;
|
||
|
-// return n;
|
||
|
-// }
|
||
|
-// */
|
||
|
-// assign(n8,
|
||
|
-// binop(Iop_Sub32,
|
||
|
-// mkexpr(n7),
|
||
|
-// binop(Iop_And32,
|
||
|
-// binop(Iop_Shr32, mkexpr(n7), mkU8(1)),
|
||
|
-// mkU32(0x55555555))));
|
||
|
-// assign(n9,
|
||
|
-// binop(Iop_Add32,
|
||
|
-// binop(Iop_And32, mkexpr(n8), mkU32(0x33333333)),
|
||
|
-// binop(Iop_And32,
|
||
|
-// binop(Iop_Shr32, mkexpr(n8), mkU8(2)),
|
||
|
-// mkU32(0x33333333))));
|
||
|
-// assign(n10,
|
||
|
-// binop(Iop_And32,
|
||
|
-// binop(Iop_Add32,
|
||
|
-// mkexpr(n9),
|
||
|
-// binop(Iop_Shr32, mkexpr(n9), mkU8(4))),
|
||
|
-// mkU32(0x0F0F0F0F)));
|
||
|
-// assign(n11,
|
||
|
-// binop(Iop_Add32,
|
||
|
-// mkexpr(n10),
|
||
|
-// binop(Iop_Shr32, mkexpr(n10), mkU8(8))));
|
||
|
-// assign(n12,
|
||
|
-// binop(Iop_Add32,
|
||
|
-// mkexpr(n11),
|
||
|
-// binop(Iop_Shr32, mkexpr(n11), mkU8(16))));
|
||
|
-// return
|
||
|
-// binop(Iop_And32, mkexpr(n12), mkU32(0x3F));
|
||
|
-//}
|
||
|
-
|
||
|
/*--------------------------------------------------------------------*/
|
||
|
/*--- end guest_ppc_toIR.c ---*/
|
||
|
/*--------------------------------------------------------------------*/
|