1 /* 2 * Copyright (C) 2014 The Android Open Source Project 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17 #ifndef ART_COMPILER_DEX_REG_STORAGE_H_ 18 #define ART_COMPILER_DEX_REG_STORAGE_H_ 19 20 #include "base/logging.h" 21 #include "base/value_object.h" 22 #include "compiler_enums.h" // For WideKind 23 24 namespace art { 25 26 /* 27 * 16-bit representation of the physical register container holding a Dalvik value. 28 * The encoding allows up to 64 physical elements per storage class, and supports eight 29 * register container shapes. 30 * 31 * [V] [HHHHH] [SSS] [F] [LLLLLL] 32 * 33 * [LLLLLL] 34 * Physical register number for the low or solo register. 35 * 0..63 36 * 37 * [F] 38 * Describes type of the [LLLLL] register. 39 * 0: Core 40 * 1: Floating point 41 * 42 * [SSS] 43 * Shape of the register container. 44 * 000: Invalid 45 * 001: 32-bit solo register 46 * 010: 64-bit solo register 47 * 011: 64-bit pair consisting of two 32-bit solo registers 48 * 100: 128-bit solo register 49 * 101: 256-bit solo register 50 * 110: 512-bit solo register 51 * 111: 1024-bit solo register 52 * 53 * [HHHHH] 54 * Physical register number of the high register (valid only for register pair). 55 * 0..31 56 * 57 * [V] 58 * 0 -> Invalid 59 * 1 -> Valid 60 * 61 * Note that in all non-invalid cases, we can determine if the storage is floating point 62 * by testing bit 7. Note also that a register pair is effectively limited to a pair of 63 * physical register numbers in the 0..31 range. 64 * 65 * On some target architectures, the same underlying physical register container can be given 66 * different views. For example, Arm's 32-bit single-precision floating point registers 67 * s2 and s3 map to the low and high halves of double-precision d1. Similarly, X86's xmm3 68 * vector register can be viewed as 32-bit, 64-bit, 128-bit, etc. In these cases the use of 69 * one view will affect the other views. The RegStorage class does not concern itself 70 * with potential aliasing. That will be done using the associated RegisterInfo struct. 71 * Distinct RegStorage elements should be created for each view of a physical register 72 * container. The management of the aliased physical elements will be handled via RegisterInfo 73 * records. 74 */ 75 76 class RegStorage : public ValueObject { 77 public: 78 enum RegStorageKind { 79 kValidMask = 0x8000, 80 kValid = 0x8000, 81 kInvalid = 0x0000, 82 kShapeMask = 0x0380, 83 k32BitSolo = 0x0080, 84 k64BitSolo = 0x0100, 85 k64BitPair = 0x0180, 86 k128BitSolo = 0x0200, 87 k256BitSolo = 0x0280, 88 k512BitSolo = 0x0300, 89 k1024BitSolo = 0x0380, 90 k64BitMask = 0x0300, 91 k64Bits = 0x0100, 92 kShapeTypeMask = 0x03c0, 93 kFloatingPoint = 0x0040, 94 kCoreRegister = 0x0000, 95 }; 96 97 static const uint16_t kRegValMask = 0x03ff; // Num, type and shape. 98 static const uint16_t kRegTypeMask = 0x007f; // Num and type. 99 static const uint16_t kRegNumMask = 0x003f; // Num only. 100 static const uint16_t kHighRegNumMask = 0x001f; // 0..31 for high reg 101 static const uint16_t kMaxRegs = kRegValMask + 1; 102 // TODO: deprecate use of kInvalidRegVal and speed up GetReg(). Rely on valid bit instead. 103 static const uint16_t kInvalidRegVal = 0x03ff; 104 static const uint16_t kHighRegShift = 10; 105 static const uint16_t kHighRegMask = (kHighRegNumMask << kHighRegShift); 106 107 // Reg is [F][LLLLL], will override any existing shape and use rs_kind. RegStorage(RegStorageKind rs_kind,int reg)108 constexpr RegStorage(RegStorageKind rs_kind, int reg) 109 : reg_( 110 DCHECK_CONSTEXPR(rs_kind != k64BitPair, , 0u) 111 DCHECK_CONSTEXPR((rs_kind & ~kShapeMask) == 0, , 0u) 112 kValid | rs_kind | (reg & kRegTypeMask)) { 113 } RegStorage(RegStorageKind rs_kind,int low_reg,int high_reg)114 constexpr RegStorage(RegStorageKind rs_kind, int low_reg, int high_reg) 115 : reg_( 116 DCHECK_CONSTEXPR(rs_kind == k64BitPair, << static_cast<int>(rs_kind), 0u) 117 DCHECK_CONSTEXPR((low_reg & kFloatingPoint) == (high_reg & kFloatingPoint), 118 << low_reg << ", " << high_reg, 0u) 119 DCHECK_CONSTEXPR((high_reg & kRegNumMask) <= kHighRegNumMask, 120 << "High reg must be in 0..31: " << high_reg, false) 121 kValid | rs_kind | ((high_reg & kHighRegNumMask) << kHighRegShift) | 122 (low_reg & kRegTypeMask)) { 123 } RegStorage(uint16_t val)124 constexpr explicit RegStorage(uint16_t val) : reg_(val) {} RegStorage()125 RegStorage() : reg_(kInvalid) {} 126 127 // We do not provide a general operator overload for equality of reg storage, as this is 128 // dangerous in the case of architectures with multiple views, and the naming ExactEquals 129 // expresses the exact match expressed here. It is more likely that a comparison between the views 130 // is intended in most cases. Such code can be found in, for example, Mir2Lir::IsSameReg. 131 // 132 // If you know what you are doing, include reg_storage_eq.h, which defines == and != for brevity. 133 ExactlyEquals(const RegStorage & rhs)134 bool ExactlyEquals(const RegStorage& rhs) const { 135 return (reg_ == rhs.GetRawBits()); 136 } 137 NotExactlyEquals(const RegStorage & rhs)138 bool NotExactlyEquals(const RegStorage& rhs) const { 139 return (reg_ != rhs.GetRawBits()); 140 } 141 Valid()142 constexpr bool Valid() const { 143 return ((reg_ & kValidMask) == kValid); 144 } 145 Is32Bit()146 constexpr bool Is32Bit() const { 147 return ((reg_ & kShapeMask) == k32BitSolo); 148 } 149 Is64Bit()150 constexpr bool Is64Bit() const { 151 return ((reg_ & k64BitMask) == k64Bits); 152 } 153 GetWideKind()154 constexpr WideKind GetWideKind() const { 155 return Is64Bit() ? kWide : kNotWide; 156 } 157 Is64BitSolo()158 constexpr bool Is64BitSolo() const { 159 return ((reg_ & kShapeMask) == k64BitSolo); 160 } 161 IsPair()162 constexpr bool IsPair() const { 163 return ((reg_ & kShapeMask) == k64BitPair); 164 } 165 IsFloat()166 constexpr bool IsFloat() const { 167 return 168 DCHECK_CONSTEXPR(Valid(), , false) 169 ((reg_ & kFloatingPoint) == kFloatingPoint); 170 } 171 IsDouble()172 constexpr bool IsDouble() const { 173 return 174 DCHECK_CONSTEXPR(Valid(), , false) 175 (reg_ & (kFloatingPoint | k64BitMask)) == (kFloatingPoint | k64Bits); 176 } 177 IsSingle()178 constexpr bool IsSingle() const { 179 return 180 DCHECK_CONSTEXPR(Valid(), , false) 181 (reg_ & (kFloatingPoint | k64BitMask)) == kFloatingPoint; 182 } 183 IsFloat(uint16_t reg)184 static constexpr bool IsFloat(uint16_t reg) { 185 return ((reg & kFloatingPoint) == kFloatingPoint); 186 } 187 IsDouble(uint16_t reg)188 static constexpr bool IsDouble(uint16_t reg) { 189 return (reg & (kFloatingPoint | k64BitMask)) == (kFloatingPoint | k64Bits); 190 } 191 IsSingle(uint16_t reg)192 static constexpr bool IsSingle(uint16_t reg) { 193 return (reg & (kFloatingPoint | k64BitMask)) == kFloatingPoint; 194 } 195 Is32Bit(uint16_t reg)196 static constexpr bool Is32Bit(uint16_t reg) { 197 return ((reg & kShapeMask) == k32BitSolo); 198 } 199 Is64Bit(uint16_t reg)200 static constexpr bool Is64Bit(uint16_t reg) { 201 return ((reg & k64BitMask) == k64Bits); 202 } 203 Is64BitSolo(uint16_t reg)204 static constexpr bool Is64BitSolo(uint16_t reg) { 205 return ((reg & kShapeMask) == k64BitSolo); 206 } 207 208 // Used to retrieve either the low register of a pair, or the only register. GetReg()209 int GetReg() const { 210 DCHECK(!IsPair()) << "reg_ = 0x" << std::hex << reg_; 211 return Valid() ? (reg_ & kRegValMask) : kInvalidRegVal; 212 } 213 214 // Sets shape, type and num of solo. SetReg(int reg)215 void SetReg(int reg) { 216 DCHECK(Valid()); 217 DCHECK(!IsPair()); 218 reg_ = (reg_ & ~kRegValMask) | reg; 219 } 220 221 // Set the reg number and type only, target remain 64-bit pair. SetLowReg(int reg)222 void SetLowReg(int reg) { 223 DCHECK(IsPair()); 224 reg_ = (reg_ & ~kRegTypeMask) | (reg & kRegTypeMask); 225 } 226 227 // Retrieve the least significant register of a pair and return as 32-bit solo. GetLowReg()228 int GetLowReg() const { 229 DCHECK(IsPair()); 230 return ((reg_ & kRegTypeMask) | k32BitSolo); 231 } 232 233 // Create a stand-alone RegStorage from the low reg of a pair. GetLow()234 RegStorage GetLow() const { 235 DCHECK(IsPair()); 236 return RegStorage(k32BitSolo, reg_ & kRegTypeMask); 237 } 238 239 // Retrieve the most significant register of a pair. GetHighReg()240 int GetHighReg() const { 241 DCHECK(IsPair()); 242 return k32BitSolo | ((reg_ & kHighRegMask) >> kHighRegShift) | (reg_ & kFloatingPoint); 243 } 244 245 // Create a stand-alone RegStorage from the high reg of a pair. GetHigh()246 RegStorage GetHigh() const { 247 DCHECK(IsPair()); 248 return RegStorage(kValid | GetHighReg()); 249 } 250 SetHighReg(int reg)251 void SetHighReg(int reg) { 252 DCHECK(IsPair()); 253 reg_ = (reg_ & ~kHighRegMask) | ((reg & kHighRegNumMask) << kHighRegShift); 254 } 255 256 // Return the register number of low or solo. GetRegNum()257 constexpr int GetRegNum() const { 258 return reg_ & kRegNumMask; 259 } 260 261 // Is register number in 0..7? Low8()262 constexpr bool Low8() const { 263 return GetRegNum() < 8; 264 } 265 266 // Is register number in 0..3? Low4()267 constexpr bool Low4() const { 268 return GetRegNum() < 4; 269 } 270 271 // Combine 2 32-bit solo regs into a pair. MakeRegPair(RegStorage low,RegStorage high)272 static RegStorage MakeRegPair(RegStorage low, RegStorage high) { 273 DCHECK(!low.IsPair()); 274 DCHECK(low.Is32Bit()); 275 DCHECK(!high.IsPair()); 276 DCHECK(high.Is32Bit()); 277 return RegStorage(k64BitPair, low.GetReg(), high.GetReg()); 278 } 279 SameRegType(RegStorage reg1,RegStorage reg2)280 static constexpr bool SameRegType(RegStorage reg1, RegStorage reg2) { 281 return ((reg1.reg_ & kShapeTypeMask) == (reg2.reg_ & kShapeTypeMask)); 282 } 283 SameRegType(int reg1,int reg2)284 static constexpr bool SameRegType(int reg1, int reg2) { 285 return ((reg1 & kShapeTypeMask) == (reg2 & kShapeTypeMask)); 286 } 287 288 // Create a 32-bit solo. Solo32(int reg_num)289 static RegStorage Solo32(int reg_num) { 290 return RegStorage(k32BitSolo, reg_num & kRegTypeMask); 291 } 292 293 // Create a floating point 32-bit solo. FloatSolo32(int reg_num)294 static constexpr RegStorage FloatSolo32(int reg_num) { 295 return RegStorage(k32BitSolo, (reg_num & kRegNumMask) | kFloatingPoint); 296 } 297 298 // Create a 128-bit solo. Solo128(int reg_num)299 static constexpr RegStorage Solo128(int reg_num) { 300 return RegStorage(k128BitSolo, reg_num & kRegTypeMask); 301 } 302 303 // Create a 64-bit solo. Solo64(int reg_num)304 static constexpr RegStorage Solo64(int reg_num) { 305 return RegStorage(k64BitSolo, reg_num & kRegTypeMask); 306 } 307 308 // Create a floating point 64-bit solo. FloatSolo64(int reg_num)309 static RegStorage FloatSolo64(int reg_num) { 310 return RegStorage(k64BitSolo, (reg_num & kRegNumMask) | kFloatingPoint); 311 } 312 InvalidReg()313 static constexpr RegStorage InvalidReg() { 314 return RegStorage(kInvalid); 315 } 316 RegNum(int raw_reg_bits)317 static constexpr uint16_t RegNum(int raw_reg_bits) { 318 return raw_reg_bits & kRegNumMask; 319 } 320 GetRawBits()321 constexpr int GetRawBits() const { 322 return reg_; 323 } 324 StorageSize()325 size_t StorageSize() const { 326 switch (reg_ & kShapeMask) { 327 case kInvalid: return 0; 328 case k32BitSolo: return 4; 329 case k64BitSolo: return 8; 330 case k64BitPair: return 8; // Is this useful? Might want to disallow taking size of pair. 331 case k128BitSolo: return 16; 332 case k256BitSolo: return 32; 333 case k512BitSolo: return 64; 334 case k1024BitSolo: return 128; 335 default: LOG(FATAL) << "Unexpected shape"; UNREACHABLE(); 336 } 337 } 338 339 private: 340 uint16_t reg_; 341 }; 342 static inline std::ostream& operator<<(std::ostream& o, const RegStorage& rhs) { 343 return o << rhs.GetRawBits(); // TODO: better output. 344 } 345 346 } // namespace art 347 348 #endif // ART_COMPILER_DEX_REG_STORAGE_H_ 349