PowerPC: move SO bit to a more convenient location
Spacing the LT and SO bits like in the native PowerPC format makes it easier to convert to that format (see mfcr).
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@ -25,7 +25,7 @@ enum CRBits
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// Optimized CR implementation. Instead of storing CR in its PowerPC format
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// (4 bit value, SO/EQ/LT/GT), we store instead a 64 bit value for each of
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// the 8 CR register parts. This 64 bit value follows this format:
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// - SO iff. bit 61 is set
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// - SO iff. bit 59 is set
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// - EQ iff. lower 32 bits == 0
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// - GT iff. (s64)cr_val > 0
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// - LT iff. bit 62 is set
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@ -46,7 +46,7 @@ struct ConditionRegister
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static u64 PPCToInternal(u8 value)
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{
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u64 cr_val = 0x100000000;
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cr_val |= (u64) !!(value & CR_SO) << 61;
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cr_val |= (u64) !!(value & CR_SO) << 59;
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cr_val |= (u64) !(value & CR_EQ);
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cr_val |= (u64) !(value & CR_GT) << 63;
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cr_val |= (u64) !!(value & CR_LT) << 62;
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@ -63,14 +63,12 @@ struct ConditionRegister
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const u64 cr_val = fields[cr_field];
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u32 ppc_cr = 0;
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// SO
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ppc_cr |= !!(cr_val & (1ull << 61));
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// LT/SO
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ppc_cr |= (cr_val >> 59) & (PowerPC::CR_LT | PowerPC::CR_SO);
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// EQ
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ppc_cr |= ((cr_val & 0xFFFFFFFF) == 0) << 1;
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ppc_cr |= ((cr_val & 0xFFFFFFFF) == 0) << PowerPC::CR_EQ_BIT;
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// GT
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ppc_cr |= (static_cast<s64>(cr_val) > 0) << 2;
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// LT
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ppc_cr |= !!(cr_val & (1ull << 62)) << 3;
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ppc_cr |= (static_cast<s64>(cr_val) > 0) << PowerPC::CR_GT_BIT;
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return ppc_cr;
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}
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@ -13,7 +13,7 @@ void Interpreter::Helper_UpdateCR0(u32 value)
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{
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s64 sign_extended = (s64)(s32)value;
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u64 cr_val = (u64)sign_extended;
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cr_val = (cr_val & ~(1ull << 61)) | ((u64)PowerPC::GetXER_SO() << 61);
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cr_val = (cr_val & ~(1ull << 59)) | ((u64)PowerPC::GetXER_SO() << 59);
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PowerPC::ppcState.cr.fields[0] = cr_val;
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}
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@ -24,8 +24,8 @@ void Jit64::GetCRFieldBit(int field, int bit, X64Reg out, bool negate)
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{
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switch (bit)
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{
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case PowerPC::CR_SO_BIT: // check bit 61 set
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BT(64, CROffset(field), Imm8(61));
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case PowerPC::CR_SO_BIT: // check bit 59 set
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BT(64, CROffset(field), Imm8(59));
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SETcc(negate ? CC_NC : CC_C, R(out));
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break;
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@ -59,9 +59,9 @@ void Jit64::SetCRFieldBit(int field, int bit, X64Reg in)
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switch (bit)
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{
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case PowerPC::CR_SO_BIT: // set bit 61 to input
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BTR(64, R(RSCRATCH2), Imm8(61));
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SHL(64, R(in), Imm8(61));
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case PowerPC::CR_SO_BIT: // set bit 59 to input
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BTR(64, R(RSCRATCH2), Imm8(59));
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SHL(64, R(in), Imm8(59));
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OR(64, R(RSCRATCH2), R(in));
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break;
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@ -95,7 +95,7 @@ void Jit64::ClearCRFieldBit(int field, int bit)
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switch (bit)
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{
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case PowerPC::CR_SO_BIT:
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BTR(64, CROffset(field), Imm8(61));
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BTR(64, CROffset(field), Imm8(59));
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break;
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case PowerPC::CR_EQ_BIT:
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@ -126,7 +126,7 @@ void Jit64::SetCRFieldBit(int field, int bit)
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switch (bit)
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{
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case PowerPC::CR_SO_BIT:
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BTS(64, R(RSCRATCH), Imm8(61));
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BTS(64, R(RSCRATCH), Imm8(59));
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break;
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case PowerPC::CR_EQ_BIT:
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@ -162,8 +162,8 @@ FixupBranch Jit64::JumpIfCRFieldBit(int field, int bit, bool jump_if_set)
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{
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switch (bit)
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{
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case PowerPC::CR_SO_BIT: // check bit 61 set
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BT(64, CROffset(field), Imm8(61));
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case PowerPC::CR_SO_BIT: // check bit 59 set
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BT(64, CROffset(field), Imm8(59));
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return J_CC(jump_if_set ? CC_C : CC_NC, true);
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case PowerPC::CR_EQ_BIT: // check bits 31-0 == 0
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@ -301,19 +301,15 @@ void CommonAsmRoutines::GenMfcr()
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X64Reg tmp = RSCRATCH2;
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X64Reg cr_val = RSCRATCH_EXTRA;
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XOR(32, R(dst), R(dst));
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// Upper bits of tmp need to be zeroed.
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XOR(32, R(tmp), R(tmp));
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for (int i = 0; i < 8; i++)
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{
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static const u32 m_flagTable[8] = {0x0, 0x1, 0x8, 0x9, 0x0, 0x1, 0x8, 0x9};
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if (i != 0)
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SHL(32, R(dst), Imm8(4));
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MOV(64, R(cr_val), PPCSTATE(cr.fields[i]));
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// Upper bits of tmp need to be zeroed.
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// Note: tmp is used later for address calculations and thus
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// can't be zero-ed once. This also prevents partial
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// register stalls due to SETcc.
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XOR(32, R(tmp), R(tmp));
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// EQ: Bits 31-0 == 0; set flag bit 1
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TEST(32, R(cr_val), R(cr_val));
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SETcc(CC_Z, R(tmp));
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@ -324,11 +320,11 @@ void CommonAsmRoutines::GenMfcr()
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SETcc(CC_G, R(tmp));
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LEA(32, dst, MComplex(dst, tmp, SCALE_4, 0));
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// SO: Bit 61 set; set flag bit 0
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// SO: Bit 59 set; set flag bit 0
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// LT: Bit 62 set; set flag bit 3
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SHR(64, R(cr_val), Imm8(61));
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LEA(64, tmp, MConst(m_flagTable));
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OR(32, R(dst), MComplex(tmp, cr_val, SCALE_4, 0));
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SHR(64, R(cr_val), Imm8(59));
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AND(32, R(cr_val), Imm8(PowerPC::CR_LT | PowerPC::CR_SO));
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OR(32, R(dst), R(cr_val));
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}
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RET();
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@ -21,8 +21,8 @@ FixupBranch JitArm64::JumpIfCRFieldBit(int field, int bit, bool jump_if_set)
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switch (bit)
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{
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case PowerPC::CR_SO_BIT: // check bit 61 set
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return jump_if_set ? TBNZ(XA, 61) : TBZ(XA, 61);
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case PowerPC::CR_SO_BIT: // check bit 59 set
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return jump_if_set ? TBNZ(XA, 59) : TBZ(XA, 59);
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case PowerPC::CR_EQ_BIT: // check bits 31-0 == 0
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return jump_if_set ? CBZ(WA) : CBNZ(WA);
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case PowerPC::CR_GT_BIT: // check val > 0
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@ -441,20 +441,20 @@ void JitArm64::crXXX(UGeckoInstruction inst)
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switch (bit)
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{
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case PowerPC::CR_SO_BIT:
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AND(XA, XA, 64 - 62, 62, true); // XA & ~(1<<61)
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ANDI2R(XA, XA, ~(u64(1) << 59));
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break;
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case PowerPC::CR_EQ_BIT:
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FixGTBeforeSettingCRFieldBit(XA);
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ORR(XA, XA, 0, 0, true); // XA | 1<<0
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ORRI2R(XA, XA, 1);
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break;
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case PowerPC::CR_GT_BIT:
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ORR(XA, XA, 64 - 63, 0, true); // XA | 1<<63
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ORRI2R(XA, XA, u64(1) << 63);
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break;
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case PowerPC::CR_LT_BIT:
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AND(XA, XA, 64 - 63, 62, true); // XA & ~(1<<62)
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ANDI2R(XA, XA, ~(u64(1) << 62));
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break;
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}
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return;
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@ -476,23 +476,23 @@ void JitArm64::crXXX(UGeckoInstruction inst)
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switch (bit)
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{
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case PowerPC::CR_SO_BIT:
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ORR(XA, XA, 64 - 61, 0, true); // XA | 1<<61
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ORRI2R(XA, XA, u64(1) << 59);
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break;
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case PowerPC::CR_EQ_BIT:
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AND(XA, XA, 32, 31, true); // Clear lower 32bits
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ANDI2R(XA, XA, 0xFFFF'FFFF'0000'0000);
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break;
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case PowerPC::CR_GT_BIT:
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AND(XA, XA, 0, 62, true); // XA & ~(1<<63)
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ANDI2R(XA, XA, ~(u64(1) << 63));
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break;
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case PowerPC::CR_LT_BIT:
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ORR(XA, XA, 64 - 62, 0, true); // XA | 1<<62
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ORRI2R(XA, XA, u64(1) << 62);
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break;
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}
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ORR(XA, XA, 32, 0, true); // XA | 1<<32
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ORRI2R(XA, XA, u64(1) << 32);
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return;
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}
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@ -519,8 +519,8 @@ void JitArm64::crXXX(UGeckoInstruction inst)
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ARM64Reg WC = EncodeRegTo32(XC);
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switch (bit)
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{
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case PowerPC::CR_SO_BIT: // check bit 61 set
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UBFX(out, XC, 61, 1);
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case PowerPC::CR_SO_BIT: // check bit 59 set
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UBFX(out, XC, 59, 1);
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if (negate)
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EOR(out, out, 0, 0, true); // XC ^ 1
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break;
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@ -581,8 +581,8 @@ void JitArm64::crXXX(UGeckoInstruction inst)
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switch (bit)
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{
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case PowerPC::CR_SO_BIT: // set bit 61 to input
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BFI(XB, XA, 61, 1);
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case PowerPC::CR_SO_BIT: // set bit 59 to input
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BFI(XB, XA, 59, 1);
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break;
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case PowerPC::CR_EQ_BIT: // clear low 32 bits, set bit 0 to !input
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@ -625,11 +625,11 @@ void JitArm64::mfcr(UGeckoInstruction inst)
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// SO
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if (i == 0)
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{
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UBFX(XA, CR, 61, 1);
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UBFX(XA, CR, 59, 1);
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}
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else
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{
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UBFX(XC, CR, 61, 1);
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UBFX(XC, CR, 59, 1);
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ORR(XA, XC, XA, ArithOption(XA, ShiftType::LSL, 4));
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}
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