1 // Copyright 2014 the V8 project authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
4 
5 #ifndef V8_PPC_CONSTANTS_PPC_H_
6 #define V8_PPC_CONSTANTS_PPC_H_
7 
8 #include <stdint.h>
9 
10 #include "src/base/logging.h"
11 #include "src/base/macros.h"
12 #include "src/globals.h"
13 
14 namespace v8 {
15 namespace internal {
16 
17 // Number of registers
18 const int kNumRegisters = 32;
19 
20 // FP support.
21 const int kNumDoubleRegisters = 32;
22 
23 const int kNoRegister = -1;
24 
25 // Used in embedded constant pool builder - max reach in bits for
26 // various load instructions (one less due to unsigned)
27 const int kLoadPtrMaxReachBits = 15;
28 const int kLoadDoubleMaxReachBits = 15;
29 
30 // sign-extend the least significant 16-bits of value <imm>
31 #define SIGN_EXT_IMM16(imm) ((static_cast<int>(imm) << 16) >> 16)
32 
33 // sign-extend the least significant 26-bits of value <imm>
34 #define SIGN_EXT_IMM26(imm) ((static_cast<int>(imm) << 6) >> 6)
35 
36 // -----------------------------------------------------------------------------
37 // Conditions.
38 
39 // Defines constants and accessor classes to assemble, disassemble and
40 // simulate PPC instructions.
41 //
42 // Section references in the code refer to the "PowerPC Microprocessor
43 // Family: The Programmer.s Reference Guide" from 10/95
44 // https://www-01.ibm.com/chips/techlib/techlib.nsf/techdocs/852569B20050FF778525699600741775/$file/prg.pdf
45 //
46 
47 // Constants for specific fields are defined in their respective named enums.
48 // General constants are in an anonymous enum in class Instr.
49 enum Condition {
50   kNoCondition = -1,
51   eq = 0,         // Equal.
52   ne = 1,         // Not equal.
53   ge = 2,         // Greater or equal.
54   lt = 3,         // Less than.
55   gt = 4,         // Greater than.
56   le = 5,         // Less then or equal
57   unordered = 6,  // Floating-point unordered
58   ordered = 7,
59   overflow = 8,  // Summary overflow
60   nooverflow = 9,
61   al = 10  // Always.
62 };
63 
64 
NegateCondition(Condition cond)65 inline Condition NegateCondition(Condition cond) {
66   DCHECK(cond != al);
67   return static_cast<Condition>(cond ^ ne);
68 }
69 
70 
71 // Commute a condition such that {a cond b == b cond' a}.
CommuteCondition(Condition cond)72 inline Condition CommuteCondition(Condition cond) {
73   switch (cond) {
74     case lt:
75       return gt;
76     case gt:
77       return lt;
78     case ge:
79       return le;
80     case le:
81       return ge;
82     default:
83       return cond;
84   }
85 }
86 
87 // -----------------------------------------------------------------------------
88 // Instructions encoding.
89 
90 // Instr is merely used by the Assembler to distinguish 32bit integers
91 // representing instructions from usual 32 bit values.
92 // Instruction objects are pointers to 32bit values, and provide methods to
93 // access the various ISA fields.
94 typedef int32_t Instr;
95 
96 // Opcodes as defined in section 4.2 table 34 (32bit PowerPC)
97 enum Opcode {
98   TWI = 3 << 26,       // Trap Word Immediate
99   MULLI = 7 << 26,     // Multiply Low Immediate
100   SUBFIC = 8 << 26,    // Subtract from Immediate Carrying
101   CMPLI = 10 << 26,    // Compare Logical Immediate
102   CMPI = 11 << 26,     // Compare Immediate
103   ADDIC = 12 << 26,    // Add Immediate Carrying
104   ADDICx = 13 << 26,   // Add Immediate Carrying and Record
105   ADDI = 14 << 26,     // Add Immediate
106   ADDIS = 15 << 26,    // Add Immediate Shifted
107   BCX = 16 << 26,      // Branch Conditional
108   SC = 17 << 26,       // System Call
109   BX = 18 << 26,       // Branch
110   EXT1 = 19 << 26,     // Extended code set 1
111   RLWIMIX = 20 << 26,  // Rotate Left Word Immediate then Mask Insert
112   RLWINMX = 21 << 26,  // Rotate Left Word Immediate then AND with Mask
113   RLWNMX = 23 << 26,   // Rotate Left Word then AND with Mask
114   ORI = 24 << 26,      // OR Immediate
115   ORIS = 25 << 26,     // OR Immediate Shifted
116   XORI = 26 << 26,     // XOR Immediate
117   XORIS = 27 << 26,    // XOR Immediate Shifted
118   ANDIx = 28 << 26,    // AND Immediate
119   ANDISx = 29 << 26,   // AND Immediate Shifted
120   EXT5 = 30 << 26,     // Extended code set 5 - 64bit only
121   EXT2 = 31 << 26,     // Extended code set 2
122   LWZ = 32 << 26,      // Load Word and Zero
123   LWZU = 33 << 26,     // Load Word with Zero Update
124   LBZ = 34 << 26,      // Load Byte and Zero
125   LBZU = 35 << 26,     // Load Byte and Zero with Update
126   STW = 36 << 26,      // Store
127   STWU = 37 << 26,     // Store Word with Update
128   STB = 38 << 26,      // Store Byte
129   STBU = 39 << 26,     // Store Byte with Update
130   LHZ = 40 << 26,      // Load Half and Zero
131   LHZU = 41 << 26,     // Load Half and Zero with Update
132   LHA = 42 << 26,      // Load Half Algebraic
133   LHAU = 43 << 26,     // Load Half Algebraic with Update
134   STH = 44 << 26,      // Store Half
135   STHU = 45 << 26,     // Store Half with Update
136   LMW = 46 << 26,      // Load Multiple Word
137   STMW = 47 << 26,     // Store Multiple Word
138   LFS = 48 << 26,      // Load Floating-Point Single
139   LFSU = 49 << 26,     // Load Floating-Point Single with Update
140   LFD = 50 << 26,      // Load Floating-Point Double
141   LFDU = 51 << 26,     // Load Floating-Point Double with Update
142   STFS = 52 << 26,     // Store Floating-Point Single
143   STFSU = 53 << 26,    // Store Floating-Point Single with Update
144   STFD = 54 << 26,     // Store Floating-Point Double
145   STFDU = 55 << 26,    // Store Floating-Point Double with Update
146   LD = 58 << 26,       // Load Double Word
147   EXT3 = 59 << 26,     // Extended code set 3
148   STD = 62 << 26,      // Store Double Word (optionally with Update)
149   EXT4 = 63 << 26      // Extended code set 4
150 };
151 
152 // Bits 10-1
153 enum OpcodeExt1 {
154   MCRF = 0 << 1,      // Move Condition Register Field
155   BCLRX = 16 << 1,    // Branch Conditional Link Register
156   CRNOR = 33 << 1,    // Condition Register NOR)
157   RFI = 50 << 1,      // Return from Interrupt
158   CRANDC = 129 << 1,  // Condition Register AND with Complement
159   ISYNC = 150 << 1,   // Instruction Synchronize
160   CRXOR = 193 << 1,   // Condition Register XOR
161   CRNAND = 225 << 1,  // Condition Register NAND
162   CRAND = 257 << 1,   // Condition Register AND
163   CREQV = 289 << 1,   // Condition Register Equivalent
164   CRORC = 417 << 1,   // Condition Register OR with Complement
165   CROR = 449 << 1,    // Condition Register OR
166   BCCTRX = 528 << 1   // Branch Conditional to Count Register
167 };
168 
169 // Bits 9-1 or 10-1
170 enum OpcodeExt2 {
171   CMP = 0 << 1,
172   TW = 4 << 1,
173   SUBFCX = 8 << 1,
174   ADDCX = 10 << 1,
175   MULHWUX = 11 << 1,
176   ISEL = 15 << 1,
177   MFCR = 19 << 1,
178   LWARX = 20 << 1,
179   LDX = 21 << 1,
180   LWZX = 23 << 1,  // load word zero w/ x-form
181   SLWX = 24 << 1,
182   CNTLZWX = 26 << 1,
183   SLDX = 27 << 1,
184   ANDX = 28 << 1,
185   CMPL = 32 << 1,
186   SUBFX = 40 << 1,
187   MFVSRD = 51 << 1,  // Move From VSR Doubleword
188   LDUX = 53 << 1,
189   DCBST = 54 << 1,
190   LWZUX = 55 << 1,  // load word zero w/ update x-form
191   CNTLZDX = 58 << 1,
192   ANDCX = 60 << 1,
193   MULHWX = 75 << 1,
194   DCBF = 86 << 1,
195   LBZX = 87 << 1,  // load byte zero w/ x-form
196   NEGX = 104 << 1,
197   MFVSRWZ = 115 << 1,  // Move From VSR Word And Zero
198   LBZUX = 119 << 1,    // load byte zero w/ update x-form
199   NORX = 124 << 1,
200   SUBFEX = 136 << 1,
201   ADDEX = 138 << 1,
202   STDX = 149 << 1,
203   STWX = 151 << 1,    // store word w/ x-form
204   MTVSRD = 179 << 1,  // Move To VSR Doubleword
205   STDUX = 181 << 1,
206   STWUX = 183 << 1,    // store word w/ update x-form
207                        /*
208       MTCRF
209       MTMSR
210       STWCXx
211       SUBFZEX
212     */
213   ADDZEX = 202 << 1,   // Add to Zero Extended
214                        /*
215      MTSR
216    */
217   MTVSRWA = 211 << 1,  // Move To VSR Word Algebraic
218   STBX = 215 << 1,     // store byte w/ x-form
219   MULLD = 233 << 1,    // Multiply Low Double Word
220   MULLW = 235 << 1,    // Multiply Low Word
221   MTVSRWZ = 243 << 1,  // Move To VSR Word And Zero
222   STBUX = 247 << 1,    // store byte w/ update x-form
223   ADDX = 266 << 1,     // Add
224   LHZX = 279 << 1,     // load half-word zero w/ x-form
225   LHZUX = 311 << 1,    // load half-word zero w/ update x-form
226   LWAX = 341 << 1,     // load word algebraic w/ x-form
227   LHAX = 343 << 1,     // load half-word algebraic w/ x-form
228   LHAUX = 375 << 1,    // load half-word algebraic w/ update x-form
229   XORX = 316 << 1,     // Exclusive OR
230   MFSPR = 339 << 1,    // Move from Special-Purpose-Register
231   POPCNTW = 378 << 1,  // Population Count Words
232   STHX = 407 << 1,     // store half-word w/ x-form
233   ORC = 412 << 1,      // Or with Complement
234   STHUX = 439 << 1,    // store half-word w/ update x-form
235   ORX = 444 << 1,      // Or
236   DIVDU = 457 << 1,    // Divide Double Word Unsigned
237   DIVWU = 459 << 1,    // Divide Word Unsigned
238   MTSPR = 467 << 1,    // Move to Special-Purpose-Register
239   DIVD = 489 << 1,     // Divide Double Word
240   DIVW = 491 << 1,     // Divide Word
241   POPCNTD = 506 << 1,  // Population Count Doubleword
242 
243   // Below represent bits 10-1  (any value >= 512)
244   LFSX = 535 << 1,    // load float-single w/ x-form
245   SRWX = 536 << 1,    // Shift Right Word
246   SRDX = 539 << 1,    // Shift Right Double Word
247   LFSUX = 567 << 1,   // load float-single w/ update x-form
248   SYNC = 598 << 1,    // Synchronize
249   LFDX = 599 << 1,    // load float-double w/ x-form
250   LFDUX = 631 << 1,   // load float-double w/ update X-form
251   STFSX = 663 << 1,   // store float-single w/ x-form
252   STFSUX = 695 << 1,  // store float-single w/ update x-form
253   STFDX = 727 << 1,   // store float-double w/ x-form
254   STFDUX = 759 << 1,  // store float-double w/ update x-form
255   SRAW = 792 << 1,    // Shift Right Algebraic Word
256   SRAD = 794 << 1,    // Shift Right Algebraic Double Word
257   SRAWIX = 824 << 1,  // Shift Right Algebraic Word Immediate
258   SRADIX = 413 << 2,  // Shift Right Algebraic Double Word Immediate
259   EXTSH = 922 << 1,   // Extend Sign Halfword
260   EXTSB = 954 << 1,   // Extend Sign Byte
261   ICBI = 982 << 1,    // Instruction Cache Block Invalidate
262   EXTSW = 986 << 1    // Extend Sign Word
263 };
264 
265 // Some use Bits 10-1 and other only 5-1 for the opcode
266 enum OpcodeExt4 {
267   // Bits 5-1
268   FDIV = 18 << 1,   // Floating Divide
269   FSUB = 20 << 1,   // Floating Subtract
270   FADD = 21 << 1,   // Floating Add
271   FSQRT = 22 << 1,  // Floating Square Root
272   FSEL = 23 << 1,   // Floating Select
273   FMUL = 25 << 1,   // Floating Multiply
274   FMSUB = 28 << 1,  // Floating Multiply-Subtract
275   FMADD = 29 << 1,  // Floating Multiply-Add
276 
277   // Bits 10-1
278   FCMPU = 0 << 1,      // Floating Compare Unordered
279   FRSP = 12 << 1,      // Floating-Point Rounding
280   FCTIW = 14 << 1,     // Floating Convert to Integer Word X-form
281   FCTIWZ = 15 << 1,    // Floating Convert to Integer Word with Round to Zero
282   MTFSB1 = 38 << 1,    // Move to FPSCR Bit 1
283   FNEG = 40 << 1,      // Floating Negate
284   MCRFS = 64 << 1,     // Move to Condition Register from FPSCR
285   MTFSB0 = 70 << 1,    // Move to FPSCR Bit 0
286   FMR = 72 << 1,       // Floating Move Register
287   MTFSFI = 134 << 1,   // Move to FPSCR Field Immediate
288   FABS = 264 << 1,     // Floating Absolute Value
289   FRIN = 392 << 1,     // Floating Round to Integer Nearest
290   FRIZ = 424 << 1,     // Floating Round to Integer Toward Zero
291   FRIP = 456 << 1,     // Floating Round to Integer Plus
292   FRIM = 488 << 1,     // Floating Round to Integer Minus
293   MFFS = 583 << 1,     // move from FPSCR x-form
294   MTFSF = 711 << 1,    // move to FPSCR fields XFL-form
295   FCTID = 814 << 1,    // Floating convert to integer doubleword
296   FCTIDZ = 815 << 1,   // ^^^ with round toward zero
297   FCFID = 846 << 1,    // Floating convert from integer doubleword
298   FCTIDU = 942 << 1,   // Floating convert to integer doubleword unsigned
299   FCTIDUZ = 943 << 1,  // ^^^ with round toward zero
300   FCFIDU = 974 << 1    // Floating convert from integer doubleword unsigned
301 };
302 
303 enum OpcodeExt5 {
304   // Bits 4-2
305   RLDICL = 0 << 1,  // Rotate Left Double Word Immediate then Clear Left
306   RLDICR = 2 << 1,  // Rotate Left Double Word Immediate then Clear Right
307   RLDIC = 4 << 1,   // Rotate Left Double Word Immediate then Clear
308   RLDIMI = 6 << 1,  // Rotate Left Double Word Immediate then Mask Insert
309   // Bits 4-1
310   RLDCL = 8 << 1,  // Rotate Left Double Word then Clear Left
311   RLDCR = 9 << 1   // Rotate Left Double Word then Clear Right
312 };
313 
314 // Instruction encoding bits and masks.
315 enum {
316   // Instruction encoding bit
317   B1 = 1 << 1,
318   B4 = 1 << 4,
319   B5 = 1 << 5,
320   B7 = 1 << 7,
321   B8 = 1 << 8,
322   B9 = 1 << 9,
323   B12 = 1 << 12,
324   B18 = 1 << 18,
325   B19 = 1 << 19,
326   B20 = 1 << 20,
327   B22 = 1 << 22,
328   B23 = 1 << 23,
329   B24 = 1 << 24,
330   B25 = 1 << 25,
331   B26 = 1 << 26,
332   B27 = 1 << 27,
333   B28 = 1 << 28,
334   B6 = 1 << 6,
335   B10 = 1 << 10,
336   B11 = 1 << 11,
337   B16 = 1 << 16,
338   B17 = 1 << 17,
339   B21 = 1 << 21,
340 
341   // Instruction bit masks
342   kCondMask = 0x1F << 21,
343   kOff12Mask = (1 << 12) - 1,
344   kImm24Mask = (1 << 24) - 1,
345   kOff16Mask = (1 << 16) - 1,
346   kImm16Mask = (1 << 16) - 1,
347   kImm26Mask = (1 << 26) - 1,
348   kBOfieldMask = 0x1f << 21,
349   kOpcodeMask = 0x3f << 26,
350   kExt1OpcodeMask = 0x3ff << 1,
351   kExt2OpcodeMask = 0x3ff << 1,
352   kExt2OpcodeVariant2Mask = 0x1ff << 2,
353   kExt5OpcodeMask = 0x3 << 2,
354   kBOMask = 0x1f << 21,
355   kBIMask = 0x1F << 16,
356   kBDMask = 0x14 << 2,
357   kAAMask = 0x01 << 1,
358   kLKMask = 0x01,
359   kRCMask = 0x01,
360   kTOMask = 0x1f << 21
361 };
362 
363 // -----------------------------------------------------------------------------
364 // Addressing modes and instruction variants.
365 
366 // Overflow Exception
367 enum OEBit {
368   SetOE = 1 << 10,   // Set overflow exception
369   LeaveOE = 0 << 10  // No overflow exception
370 };
371 
372 // Record bit
373 enum RCBit {   // Bit 0
374   SetRC = 1,   // LT,GT,EQ,SO
375   LeaveRC = 0  // None
376 };
377 
378 // Link bit
379 enum LKBit {   // Bit 0
380   SetLK = 1,   // Load effective address of next instruction
381   LeaveLK = 0  // No action
382 };
383 
384 enum BOfield {        // Bits 25-21
385   DCBNZF = 0 << 21,   // Decrement CTR; branch if CTR != 0 and condition false
386   DCBEZF = 2 << 21,   // Decrement CTR; branch if CTR == 0 and condition false
387   BF = 4 << 21,       // Branch if condition false
388   DCBNZT = 8 << 21,   // Decrement CTR; branch if CTR != 0 and condition true
389   DCBEZT = 10 << 21,  // Decrement CTR; branch if CTR == 0 and condition true
390   BT = 12 << 21,      // Branch if condition true
391   DCBNZ = 16 << 21,   // Decrement CTR; branch if CTR != 0
392   DCBEZ = 18 << 21,   // Decrement CTR; branch if CTR == 0
393   BA = 20 << 21       // Branch always
394 };
395 
396 #if V8_OS_AIX
397 #undef CR_LT
398 #undef CR_GT
399 #undef CR_EQ
400 #undef CR_SO
401 #endif
402 
403 enum CRBit { CR_LT = 0, CR_GT = 1, CR_EQ = 2, CR_SO = 3, CR_FU = 3 };
404 
405 #define CRWIDTH 4
406 
407 // These are the documented bit positions biased down by 32
408 enum FPSCRBit {
409   VXSOFT = 21,  // 53: Software-Defined Condition
410   VXSQRT = 22,  // 54: Invalid Square Root
411   VXCVI = 23    // 55: Invalid Integer Convert
412 };
413 
414 // -----------------------------------------------------------------------------
415 // Supervisor Call (svc) specific support.
416 
417 // Special Software Interrupt codes when used in the presence of the PPC
418 // simulator.
419 // svc (formerly swi) provides a 24bit immediate value. Use bits 22:0 for
420 // standard SoftwareInterrupCode. Bit 23 is reserved for the stop feature.
421 enum SoftwareInterruptCodes {
422   // transition to C code
423   kCallRtRedirected = 0x10,
424   // break point
425   kBreakpoint = 0x821008,  // bits23-0 of 0x7d821008 = twge r2, r2
426   // stop
427   kStopCode = 1 << 23
428 };
429 const uint32_t kStopCodeMask = kStopCode - 1;
430 const uint32_t kMaxStopCode = kStopCode - 1;
431 const int32_t kDefaultStopCode = -1;
432 
433 // FP rounding modes.
434 enum FPRoundingMode {
435   RN = 0,  // Round to Nearest.
436   RZ = 1,  // Round towards zero.
437   RP = 2,  // Round towards Plus Infinity.
438   RM = 3,  // Round towards Minus Infinity.
439 
440   // Aliases.
441   kRoundToNearest = RN,
442   kRoundToZero = RZ,
443   kRoundToPlusInf = RP,
444   kRoundToMinusInf = RM
445 };
446 
447 const uint32_t kFPRoundingModeMask = 3;
448 
449 enum CheckForInexactConversion {
450   kCheckForInexactConversion,
451   kDontCheckForInexactConversion
452 };
453 
454 // -----------------------------------------------------------------------------
455 // Specific instructions, constants, and masks.
456 // These constants are declared in assembler-arm.cc, as they use named registers
457 // and other constants.
458 
459 
460 // add(sp, sp, 4) instruction (aka Pop())
461 extern const Instr kPopInstruction;
462 
463 // str(r, MemOperand(sp, 4, NegPreIndex), al) instruction (aka push(r))
464 // register r is not encoded.
465 extern const Instr kPushRegPattern;
466 
467 // ldr(r, MemOperand(sp, 4, PostIndex), al) instruction (aka pop(r))
468 // register r is not encoded.
469 extern const Instr kPopRegPattern;
470 
471 // use TWI to indicate redirection call for simulation mode
472 const Instr rtCallRedirInstr = TWI;
473 
474 // -----------------------------------------------------------------------------
475 // Instruction abstraction.
476 
477 // The class Instruction enables access to individual fields defined in the PPC
478 // architecture instruction set encoding.
479 // Note that the Assembler uses typedef int32_t Instr.
480 //
481 // Example: Test whether the instruction at ptr does set the condition code
482 // bits.
483 //
484 // bool InstructionSetsConditionCodes(byte* ptr) {
485 //   Instruction* instr = Instruction::At(ptr);
486 //   int type = instr->TypeValue();
487 //   return ((type == 0) || (type == 1)) && instr->HasS();
488 // }
489 //
490 class Instruction {
491  public:
492   enum { kInstrSize = 4, kInstrSizeLog2 = 2, kPCReadOffset = 8 };
493 
494 // Helper macro to define static accessors.
495 // We use the cast to char* trick to bypass the strict anti-aliasing rules.
496 #define DECLARE_STATIC_TYPED_ACCESSOR(return_type, Name) \
497   static inline return_type Name(Instr instr) {          \
498     char* temp = reinterpret_cast<char*>(&instr);        \
499     return reinterpret_cast<Instruction*>(temp)->Name(); \
500   }
501 
502 #define DECLARE_STATIC_ACCESSOR(Name) DECLARE_STATIC_TYPED_ACCESSOR(int, Name)
503 
504   // Get the raw instruction bits.
InstructionBits()505   inline Instr InstructionBits() const {
506     return *reinterpret_cast<const Instr*>(this);
507   }
508 
509   // Set the raw instruction bits to value.
SetInstructionBits(Instr value)510   inline void SetInstructionBits(Instr value) {
511     *reinterpret_cast<Instr*>(this) = value;
512   }
513 
514   // Read one particular bit out of the instruction bits.
Bit(int nr)515   inline int Bit(int nr) const { return (InstructionBits() >> nr) & 1; }
516 
517   // Read a bit field's value out of the instruction bits.
Bits(int hi,int lo)518   inline int Bits(int hi, int lo) const {
519     return (InstructionBits() >> lo) & ((2 << (hi - lo)) - 1);
520   }
521 
522   // Read a bit field out of the instruction bits.
BitField(int hi,int lo)523   inline int BitField(int hi, int lo) const {
524     return InstructionBits() & (((2 << (hi - lo)) - 1) << lo);
525   }
526 
527   // Static support.
528 
529   // Read one particular bit out of the instruction bits.
Bit(Instr instr,int nr)530   static inline int Bit(Instr instr, int nr) { return (instr >> nr) & 1; }
531 
532   // Read the value of a bit field out of the instruction bits.
Bits(Instr instr,int hi,int lo)533   static inline int Bits(Instr instr, int hi, int lo) {
534     return (instr >> lo) & ((2 << (hi - lo)) - 1);
535   }
536 
537 
538   // Read a bit field out of the instruction bits.
BitField(Instr instr,int hi,int lo)539   static inline int BitField(Instr instr, int hi, int lo) {
540     return instr & (((2 << (hi - lo)) - 1) << lo);
541   }
542 
RSValue()543   inline int RSValue() const { return Bits(25, 21); }
RTValue()544   inline int RTValue() const { return Bits(25, 21); }
RAValue()545   inline int RAValue() const { return Bits(20, 16); }
546   DECLARE_STATIC_ACCESSOR(RAValue);
RBValue()547   inline int RBValue() const { return Bits(15, 11); }
548   DECLARE_STATIC_ACCESSOR(RBValue);
RCValue()549   inline int RCValue() const { return Bits(10, 6); }
550   DECLARE_STATIC_ACCESSOR(RCValue);
551 
OpcodeValue()552   inline int OpcodeValue() const { return static_cast<Opcode>(Bits(31, 26)); }
OpcodeField()553   inline Opcode OpcodeField() const {
554     return static_cast<Opcode>(BitField(24, 21));
555   }
556 
557   // Fields used in Software interrupt instructions
SvcValue()558   inline SoftwareInterruptCodes SvcValue() const {
559     return static_cast<SoftwareInterruptCodes>(Bits(23, 0));
560   }
561 
562   // Instructions are read of out a code stream. The only way to get a
563   // reference to an instruction is to convert a pointer. There is no way
564   // to allocate or create instances of class Instruction.
565   // Use the At(pc) function to create references to Instruction.
At(byte * pc)566   static Instruction* At(byte* pc) {
567     return reinterpret_cast<Instruction*>(pc);
568   }
569 
570 
571  private:
572   // We need to prevent the creation of instances of class Instruction.
573   DISALLOW_IMPLICIT_CONSTRUCTORS(Instruction);
574 };
575 
576 
577 // Helper functions for converting between register numbers and names.
578 class Registers {
579  public:
580   // Lookup the register number for the name provided.
581   static int Number(const char* name);
582 
583  private:
584   static const char* names_[kNumRegisters];
585 };
586 
587 // Helper functions for converting between FP register numbers and names.
588 class DoubleRegisters {
589  public:
590   // Lookup the register number for the name provided.
591   static int Number(const char* name);
592 
593  private:
594   static const char* names_[kNumDoubleRegisters];
595 };
596 }  // namespace internal
597 }  // namespace v8
598 
599 #endif  // V8_PPC_CONSTANTS_PPC_H_
600