JitArm64: Accept LogicalImm struct as bitwise inst parameter

2021-07-06 16:22:23 +02:00 · 2021-07-06 16:22:23 +02:00 · ab024b218e
parent f6ca70d094
commit ab024b218e
2 changed files with 69 additions and 30 deletions
--- a/Source/Core/Common/Arm64Emitter.cpp
+++ b/Source/Core/Common/Arm64Emitter.cpp
@ -46,7 +46,7 @@ std::optional<std::pair<u32, bool>> IsImmArithmetic(uint64_t input)
 }

 // For AND/TST/ORR/EOR etc
-std::optional<std::tuple<u32, u32, u32>> IsImmLogical(u64 value, u32 width)
+LogicalImm IsImmLogical(u64 value, u32 width)
 {
  bool negate = false;

@ -154,7 +154,7 @@ std::optional<std::tuple<u32, u32, u32>> IsImmLogical(u64 value, u32 width)
      // The input was zero (or all 1 bits, which will come to here too after we
      // inverted it at the start of the function), for which we just return
      // false.
-      return std::nullopt;
+      return LogicalImm();
    }
    else
    {
@ -171,12 +171,12 @@ std::optional<std::tuple<u32, u32, u32>> IsImmLogical(u64 value, u32 width)

  // If the repeat period d is not a power of two, it can't be encoded.
  if (!MathUtil::IsPow2<u64>(d))
-    return std::nullopt;
+    return LogicalImm();

  // If the bit stretch (b - a) does not fit within the mask derived from the
  // repeat period, then fail.
  if (((b - a) & ~mask) != 0)
-    return std::nullopt;
+    return LogicalImm();

  // The only possible option is b - a repeated every d bits. Now we're going to
  // actually construct the valid logical immediate derived from that
@ -204,7 +204,7 @@ std::optional<std::tuple<u32, u32, u32>> IsImmLogical(u64 value, u32 width)

  // The candidate pattern doesn't match our input value, so fail.
  if (value != candidate)
-    return std::nullopt;
+    return LogicalImm();

  // We have a match! This is a valid logical immediate, so now we have to
  // construct the bits and pieces of the instruction encoding that generates
@ -246,11 +246,8 @@ std::optional<std::tuple<u32, u32, u32>> IsImmLogical(u64 value, u32 width)
  //    11110s     2    UInt(s)
  //
  // So we 'or' (-d << 1) with our computed s to form imms.
-  return std::tuple{
-      static_cast<u32>(out_n),
-      static_cast<u32>(((-d << 1) | (s - 1)) & 0x3f),
-      static_cast<u32>(r),
-  };
+  return LogicalImm(static_cast<u8>(r), static_cast<u8>(((-d << 1) | (s - 1)) & 0x3f),
+                    static_cast<u8>(out_n));
 }

 float FPImm8ToFloat(u8 bits)
@ -780,10 +777,18 @@ void ARM64XEmitter::EncodeLogicalImmInst(u32 op, ARM64Reg Rd, ARM64Reg Rn, u32 i
  // Use Rn to determine bitness here.
  bool b64Bit = Is64Bit(Rn);

+  ASSERT_MSG(DYNAREC, b64Bit || !n, "64-bit logical immediate does not fit in 32-bit register");
+
  Write32((b64Bit << 31) | (op << 29) | (0x24 << 23) | (n << 22) | (immr << 16) | (imms << 10) |
          (DecodeReg(Rn) << 5) | DecodeReg(Rd));
 }

+void ARM64XEmitter::EncodeLogicalImmInst(u32 op, ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm)
+{
+  ASSERT_MSG(DYNAREC, imm.valid, "Invalid logical immediate");
+  EncodeLogicalImmInst(op, Rd, Rn, imm.r, imm.s, imm.n);
+}
+
 void ARM64XEmitter::EncodeLoadStorePair(u32 op, u32 load, IndexType type, ARM64Reg Rt, ARM64Reg Rt2,
                                        ARM64Reg Rn, s32 imm)
 {
@ -1545,22 +1550,42 @@ void ARM64XEmitter::AND(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, bool inver
 {
  EncodeLogicalImmInst(0, Rd, Rn, immr, imms, invert);
 }
+void ARM64XEmitter::AND(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm)
+{
+  EncodeLogicalImmInst(0, Rd, Rn, imm);
+}
 void ARM64XEmitter::ANDS(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, bool invert)
 {
  EncodeLogicalImmInst(3, Rd, Rn, immr, imms, invert);
 }
+void ARM64XEmitter::ANDS(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm)
+{
+  EncodeLogicalImmInst(3, Rd, Rn, imm);
+}
 void ARM64XEmitter::EOR(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, bool invert)
 {
  EncodeLogicalImmInst(2, Rd, Rn, immr, imms, invert);
 }
+void ARM64XEmitter::EOR(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm)
+{
+  EncodeLogicalImmInst(2, Rd, Rn, imm);
+}
 void ARM64XEmitter::ORR(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, bool invert)
 {
  EncodeLogicalImmInst(1, Rd, Rn, immr, imms, invert);
 }
+void ARM64XEmitter::ORR(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm)
+{
+  EncodeLogicalImmInst(1, Rd, Rn, imm);
+}
 void ARM64XEmitter::TST(ARM64Reg Rn, u32 immr, u32 imms, bool invert)
 {
  EncodeLogicalImmInst(3, Is64Bit(Rn) ? ARM64Reg::ZR : ARM64Reg::WZR, Rn, immr, imms, invert);
 }
+void ARM64XEmitter::TST(ARM64Reg Rn, LogicalImm imm)
+{
+  EncodeLogicalImmInst(3, Is64Bit(Rn) ? ARM64Reg::ZR : ARM64Reg::WZR, Rn, imm);
+}

 // Add/subtract (immediate)
 void ARM64XEmitter::ADD(ARM64Reg Rd, ARM64Reg Rn, u32 imm, bool shift)
@ -4129,8 +4154,7 @@ void ARM64XEmitter::ANDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch)

  if (const auto result = IsImmLogical(imm, Is64Bit(Rn) ? 64 : 32))
  {
-    const auto& [n, imm_s, imm_r] = *result;
-    AND(Rd, Rn, imm_r, imm_s, n != 0);
+    AND(Rd, Rn, result);
  }
  else
  {
@ -4146,8 +4170,7 @@ void ARM64XEmitter::ORRI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch)
 {
  if (const auto result = IsImmLogical(imm, Is64Bit(Rn) ? 64 : 32))
  {
-    const auto& [n, imm_s, imm_r] = *result;
-    ORR(Rd, Rn, imm_r, imm_s, n != 0);
+    ORR(Rd, Rn, result);
  }
  else
  {
@ -4163,8 +4186,7 @@ void ARM64XEmitter::EORI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch)
 {
  if (const auto result = IsImmLogical(imm, Is64Bit(Rn) ? 64 : 32))
  {
-    const auto& [n, imm_s, imm_r] = *result;
-    EOR(Rd, Rn, imm_r, imm_s, n != 0);
+    EOR(Rd, Rn, result);
  }
  else
  {
@ -4180,8 +4202,7 @@ void ARM64XEmitter::ANDSI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch)
 {
  if (const auto result = IsImmLogical(imm, Is64Bit(Rn) ? 64 : 32))
  {
-    const auto& [n, imm_s, imm_r] = *result;
-    ANDS(Rd, Rn, imm_r, imm_s, n != 0);
+    ANDS(Rd, Rn, result);
  }
  else
  {
@ -4342,10 +4363,9 @@ bool ARM64XEmitter::TryCMPI2R(ARM64Reg Rn, u64 imm)

 bool ARM64XEmitter::TryANDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm)
 {
-  if (const auto result = IsImmLogical(imm, Is64Bit(Rd) ? 64 : 32))
+  if (const auto result = IsImmLogical(imm, Is64Bit(Rn) ? 64 : 32))
  {
-    const auto& [n, imm_s, imm_r] = *result;
-    AND(Rd, Rn, imm_r, imm_s, n != 0);
+    AND(Rd, Rn, result);
    return true;
  }

@ -4354,10 +4374,9 @@ bool ARM64XEmitter::TryANDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm)

 bool ARM64XEmitter::TryORRI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm)
 {
-  if (const auto result = IsImmLogical(imm, Is64Bit(Rd) ? 64 : 32))
+  if (const auto result = IsImmLogical(imm, Is64Bit(Rn) ? 64 : 32))
  {
-    const auto& [n, imm_s, imm_r] = *result;
-    ORR(Rd, Rn, imm_r, imm_s, n != 0);
+    ORR(Rd, Rn, result);
    return true;
  }

@ -4366,10 +4385,9 @@ bool ARM64XEmitter::TryORRI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm)

 bool ARM64XEmitter::TryEORI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm)
 {
-  if (const auto result = IsImmLogical(imm, Is64Bit(Rd) ? 64 : 32))
+  if (const auto result = IsImmLogical(imm, Is64Bit(Rn) ? 64 : 32))
  {
-    const auto& [n, imm_s, imm_r] = *result;
-    EOR(Rd, Rn, imm_r, imm_s, n != 0);
+    EOR(Rd, Rn, result);
    return true;
  }

--- a/Source/Core/Common/Arm64Emitter.h
+++ b/Source/Core/Common/Arm64Emitter.h
@ -496,6 +496,19 @@ public:
  bool IsExtended() const { return m_type == TypeSpecifier::ExtendedReg; }
 };

+struct LogicalImm
+{
+  constexpr LogicalImm() : r(0), s(0), n(false), valid(false) {}
+  constexpr LogicalImm(u8 r_, u8 s_, bool n_) : r(r_), s(s_), n(n_), valid(true) {}
+
+  constexpr operator bool() const { return valid; }
+
+  u8 r;
+  u8 s;
+  bool n;
+  bool valid;
+};
+
 class ARM64XEmitter
 {
  friend class ARM64FloatEmitter;
@ -531,6 +544,7 @@ private:
  void EncodeLoadStoreRegisterOffset(u32 size, u32 opc, ARM64Reg Rt, ARM64Reg Rn, ArithOption Rm);
  void EncodeAddSubImmInst(u32 op, bool flags, u32 shift, u32 imm, ARM64Reg Rn, ARM64Reg Rd);
  void EncodeLogicalImmInst(u32 op, ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, int n);
+  void EncodeLogicalImmInst(u32 op, ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
  void EncodeLoadStorePair(u32 op, u32 load, IndexType type, ARM64Reg Rt, ARM64Reg Rt2, ARM64Reg Rn,
                           s32 imm);
  void EncodeAddressInst(u32 op, ARM64Reg Rd, s32 imm);
@ -772,10 +786,15 @@ public:

  // Logical (immediate)
  void AND(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, bool invert = false);
+  void AND(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
  void ANDS(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, bool invert = false);
+  void ANDS(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
  void EOR(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, bool invert = false);
+  void EOR(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
  void ORR(ARM64Reg Rd, ARM64Reg Rn, u32 immr, u32 imms, bool invert = false);
+  void ORR(ARM64Reg Rd, ARM64Reg Rn, LogicalImm imm);
  void TST(ARM64Reg Rn, u32 immr, u32 imms, bool invert = false);
+  void TST(ARM64Reg Rn, LogicalImm imm);
  // Add/subtract (immediate)
  void ADD(ARM64Reg Rd, ARM64Reg Rn, u32 imm, bool shift = false);
  void ADDS(ARM64Reg Rd, ARM64Reg Rn, u32 imm, bool shift = false);
@ -893,8 +912,10 @@ public:
    MOVI2R(Rd, (uintptr_t)ptr);
  }

-  // Wrapper around AND x, y, imm etc. If you are sure the imm will work, no need to pass a scratch
-  // register.
+  // Wrapper around AND x, y, imm etc.
+  // If you are sure the imm will work, no need to pass a scratch register.
+  // If the imm is constant, preferably call EncodeLogicalImm directly instead of using these
+  // functions, as this lets the computation of the imm encoding be performed during compilation.
  void ANDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
  void ANDSI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
  void TSTI2R(ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG)
@ -903,7 +924,6 @@ public:
  }
  void ORRI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
  void EORI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
-  void CMPI2R(ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);

  void ADDI2R_internal(ARM64Reg Rd, ARM64Reg Rn, u64 imm, bool negative, bool flags,
                       ARM64Reg scratch);
@ -911,6 +931,7 @@ public:
  void ADDSI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
  void SUBI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
  void SUBSI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);
+  void CMPI2R(ARM64Reg Rn, u64 imm, ARM64Reg scratch = ARM64Reg::INVALID_REG);

  bool TryADDI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm);
  bool TrySUBI2R(ARM64Reg Rd, ARM64Reg Rn, u64 imm);