xref: /freebsd/contrib/llvm-project/llvm/lib/Target/ARM/MCTargetDesc/ARMBaseInfo.h (revision a7623790fb345e6dc986dfd31df0ace115e6f2e4)
1 //===-- ARMBaseInfo.h - Top level definitions for ARM -------- --*- C++ -*-===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 //
9 // This file contains small standalone helper functions and enum definitions for
10 // the ARM target useful for the compiler back-end and the MC libraries.
11 // As such, it deliberately does not include references to LLVM core
12 // code gen types, passes, etc..
13 //
14 //===----------------------------------------------------------------------===//
15 
16 #ifndef LLVM_LIB_TARGET_ARM_MCTARGETDESC_ARMBASEINFO_H
17 #define LLVM_LIB_TARGET_ARM_MCTARGETDESC_ARMBASEINFO_H
18 
19 #include "ARMMCTargetDesc.h"
20 #include "llvm/Support/ErrorHandling.h"
21 #include "Utils/ARMBaseInfo.h"
22 
23 namespace llvm {
24 
25 namespace ARM_PROC {
26   enum IMod {
27     IE = 2,
28     ID = 3
29   };
30 
31   enum IFlags {
32     F = 1,
33     I = 2,
34     A = 4
35   };
36 
37   inline static const char *IFlagsToString(unsigned val) {
38     switch (val) {
39     default: llvm_unreachable("Unknown iflags operand");
40     case F: return "f";
41     case I: return "i";
42     case A: return "a";
43     }
44   }
45 
46   inline static const char *IModToString(unsigned val) {
47     switch (val) {
48     default: llvm_unreachable("Unknown imod operand");
49     case IE: return "ie";
50     case ID: return "id";
51     }
52   }
53 }
54 
55 namespace ARM_MB {
56   // The Memory Barrier Option constants map directly to the 4-bit encoding of
57   // the option field for memory barrier operations.
58   enum MemBOpt {
59     RESERVED_0 = 0,
60     OSHLD = 1,
61     OSHST = 2,
62     OSH   = 3,
63     RESERVED_4 = 4,
64     NSHLD = 5,
65     NSHST = 6,
66     NSH   = 7,
67     RESERVED_8 = 8,
68     ISHLD = 9,
69     ISHST = 10,
70     ISH   = 11,
71     RESERVED_12 = 12,
72     LD = 13,
73     ST    = 14,
74     SY    = 15
75   };
76 
77   inline static const char *MemBOptToString(unsigned val, bool HasV8) {
78     switch (val) {
79     default: llvm_unreachable("Unknown memory operation");
80     case SY:    return "sy";
81     case ST:    return "st";
82     case LD: return HasV8 ? "ld" : "#0xd";
83     case RESERVED_12: return "#0xc";
84     case ISH:   return "ish";
85     case ISHST: return "ishst";
86     case ISHLD: return HasV8 ?  "ishld" : "#0x9";
87     case RESERVED_8: return "#0x8";
88     case NSH:   return "nsh";
89     case NSHST: return "nshst";
90     case NSHLD: return HasV8 ? "nshld" : "#0x5";
91     case RESERVED_4: return "#0x4";
92     case OSH:   return "osh";
93     case OSHST: return "oshst";
94     case OSHLD: return HasV8 ? "oshld" : "#0x1";
95     case RESERVED_0: return "#0x0";
96     }
97   }
98 } // namespace ARM_MB
99 
100 namespace ARM_TSB {
101   enum TraceSyncBOpt {
102     CSYNC = 0
103   };
104 
105   inline static const char *TraceSyncBOptToString(unsigned val) {
106     switch (val) {
107     default:
108       llvm_unreachable("Unknown trace synchronization barrier operation");
109       case CSYNC: return "csync";
110     }
111   }
112 } // namespace ARM_TSB
113 
114 namespace ARM_ISB {
115   enum InstSyncBOpt {
116     RESERVED_0 = 0,
117     RESERVED_1 = 1,
118     RESERVED_2 = 2,
119     RESERVED_3 = 3,
120     RESERVED_4 = 4,
121     RESERVED_5 = 5,
122     RESERVED_6 = 6,
123     RESERVED_7 = 7,
124     RESERVED_8 = 8,
125     RESERVED_9 = 9,
126     RESERVED_10 = 10,
127     RESERVED_11 = 11,
128     RESERVED_12 = 12,
129     RESERVED_13 = 13,
130     RESERVED_14 = 14,
131     SY = 15
132   };
133 
134   inline static const char *InstSyncBOptToString(unsigned val) {
135     switch (val) {
136     default:
137       llvm_unreachable("Unknown memory operation");
138       case RESERVED_0:  return "#0x0";
139       case RESERVED_1:  return "#0x1";
140       case RESERVED_2:  return "#0x2";
141       case RESERVED_3:  return "#0x3";
142       case RESERVED_4:  return "#0x4";
143       case RESERVED_5:  return "#0x5";
144       case RESERVED_6:  return "#0x6";
145       case RESERVED_7:  return "#0x7";
146       case RESERVED_8:  return "#0x8";
147       case RESERVED_9:  return "#0x9";
148       case RESERVED_10: return "#0xa";
149       case RESERVED_11: return "#0xb";
150       case RESERVED_12: return "#0xc";
151       case RESERVED_13: return "#0xd";
152       case RESERVED_14: return "#0xe";
153       case SY:          return "sy";
154     }
155   }
156 } // namespace ARM_ISB
157 
158 /// isARMLowRegister - Returns true if the register is a low register (r0-r7).
159 ///
160 static inline bool isARMLowRegister(unsigned Reg) {
161   using namespace ARM;
162   switch (Reg) {
163   case R0:  case R1:  case R2:  case R3:
164   case R4:  case R5:  case R6:  case R7:
165     return true;
166   default:
167     return false;
168   }
169 }
170 
171 /// ARMII - This namespace holds all of the target specific flags that
172 /// instruction info tracks.
173 ///
174 namespace ARMII {
175 
176   /// ARM Index Modes
177   enum IndexMode {
178     IndexModeNone  = 0,
179     IndexModePre   = 1,
180     IndexModePost  = 2,
181     IndexModeUpd   = 3
182   };
183 
184   /// ARM Addressing Modes
185   enum AddrMode {
186     AddrModeNone    = 0,
187     AddrMode1       = 1,
188     AddrMode2       = 2,
189     AddrMode3       = 3,
190     AddrMode4       = 4,
191     AddrMode5       = 5,
192     AddrMode6       = 6,
193     AddrModeT1_1    = 7,
194     AddrModeT1_2    = 8,
195     AddrModeT1_4    = 9,
196     AddrModeT1_s    = 10, // i8 * 4 for pc and sp relative data
197     AddrModeT2_i12  = 11,
198     AddrModeT2_i8   = 12,
199     AddrModeT2_so   = 13,
200     AddrModeT2_pc   = 14, // +/- i12 for pc relative data
201     AddrModeT2_i8s4 = 15, // i8 * 4
202     AddrMode_i12    = 16,
203     AddrMode5FP16   = 17,  // i8 * 2
204     AddrModeT2_ldrex = 18, // i8 * 4, with unscaled offset in MCInst
205     AddrModeT2_i7s4 = 19, // i7 * 4
206     AddrModeT2_i7s2 = 20, // i7 * 2
207     AddrModeT2_i7   = 21, // i7 * 1
208   };
209 
210   inline static const char *AddrModeToString(AddrMode addrmode) {
211     switch (addrmode) {
212     case AddrModeNone:    return "AddrModeNone";
213     case AddrMode1:       return "AddrMode1";
214     case AddrMode2:       return "AddrMode2";
215     case AddrMode3:       return "AddrMode3";
216     case AddrMode4:       return "AddrMode4";
217     case AddrMode5:       return "AddrMode5";
218     case AddrMode5FP16:   return "AddrMode5FP16";
219     case AddrMode6:       return "AddrMode6";
220     case AddrModeT1_1:    return "AddrModeT1_1";
221     case AddrModeT1_2:    return "AddrModeT1_2";
222     case AddrModeT1_4:    return "AddrModeT1_4";
223     case AddrModeT1_s:    return "AddrModeT1_s";
224     case AddrModeT2_i12:  return "AddrModeT2_i12";
225     case AddrModeT2_i8:   return "AddrModeT2_i8";
226     case AddrModeT2_so:   return "AddrModeT2_so";
227     case AddrModeT2_pc:   return "AddrModeT2_pc";
228     case AddrModeT2_i8s4: return "AddrModeT2_i8s4";
229     case AddrMode_i12:    return "AddrMode_i12";
230     case AddrModeT2_ldrex:return "AddrModeT2_ldrex";
231     case AddrModeT2_i7s4: return "AddrModeT2_i7s4";
232     case AddrModeT2_i7s2: return "AddrModeT2_i7s2";
233     case AddrModeT2_i7:   return "AddrModeT2_i7";
234     }
235   }
236 
237   /// Target Operand Flag enum.
238   enum TOF {
239     //===------------------------------------------------------------------===//
240     // ARM Specific MachineOperand flags.
241 
242     MO_NO_FLAG = 0,
243 
244     /// MO_LO16 - On a symbol operand, this represents a relocation containing
245     /// lower 16 bit of the address. Used only via movw instruction.
246     MO_LO16 = 0x1,
247 
248     /// MO_HI16 - On a symbol operand, this represents a relocation containing
249     /// higher 16 bit of the address. Used only via movt instruction.
250     MO_HI16 = 0x2,
251 
252     /// MO_OPTION_MASK - Most flags are mutually exclusive; this mask selects
253     /// just that part of the flag set.
254     MO_OPTION_MASK = 0x3,
255 
256     /// MO_COFFSTUB - On a symbol operand "FOO", this indicates that the
257     /// reference is actually to the ".refptrp.FOO" symbol.  This is used for
258     /// stub symbols on windows.
259     MO_COFFSTUB = 0x4,
260 
261     /// MO_GOT - On a symbol operand, this represents a GOT relative relocation.
262     MO_GOT = 0x8,
263 
264     /// MO_SBREL - On a symbol operand, this represents a static base relative
265     /// relocation. Used in movw and movt instructions.
266     MO_SBREL = 0x10,
267 
268     /// MO_DLLIMPORT - On a symbol operand, this represents that the reference
269     /// to the symbol is for an import stub.  This is used for DLL import
270     /// storage class indication on Windows.
271     MO_DLLIMPORT = 0x20,
272 
273     /// MO_SECREL - On a symbol operand this indicates that the immediate is
274     /// the offset from beginning of section.
275     ///
276     /// This is the TLS offset for the COFF/Windows TLS mechanism.
277     MO_SECREL = 0x40,
278 
279     /// MO_NONLAZY - This is an independent flag, on a symbol operand "FOO" it
280     /// represents a symbol which, if indirect, will get special Darwin mangling
281     /// as a non-lazy-ptr indirect symbol (i.e. "L_FOO$non_lazy_ptr"). Can be
282     /// combined with MO_LO16, MO_HI16 or MO_NO_FLAG (in a constant-pool, for
283     /// example).
284     MO_NONLAZY = 0x80,
285 
286     // It's undefined behaviour if an enum overflows the range between its
287     // smallest and largest values, but since these are |ed together, it can
288     // happen. Put a sentinel in (values of this enum are stored as "unsigned
289     // char").
290     MO_UNUSED_MAXIMUM = 0xff
291   };
292 
293   enum {
294     //===------------------------------------------------------------------===//
295     // Instruction Flags.
296 
297     //===------------------------------------------------------------------===//
298     // This four-bit field describes the addressing mode used.
299     AddrModeMask  = 0x1f, // The AddrMode enums are declared in ARMBaseInfo.h
300 
301     // IndexMode - Unindex, pre-indexed, or post-indexed are valid for load
302     // and store ops only.  Generic "updating" flag is used for ld/st multiple.
303     // The index mode enums are declared in ARMBaseInfo.h
304     IndexModeShift = 5,
305     IndexModeMask  = 3 << IndexModeShift,
306 
307     //===------------------------------------------------------------------===//
308     // Instruction encoding formats.
309     //
310     FormShift     = 7,
311     FormMask      = 0x3f << FormShift,
312 
313     // Pseudo instructions
314     Pseudo        = 0  << FormShift,
315 
316     // Multiply instructions
317     MulFrm        = 1  << FormShift,
318 
319     // Branch instructions
320     BrFrm         = 2  << FormShift,
321     BrMiscFrm     = 3  << FormShift,
322 
323     // Data Processing instructions
324     DPFrm         = 4  << FormShift,
325     DPSoRegFrm    = 5  << FormShift,
326 
327     // Load and Store
328     LdFrm         = 6  << FormShift,
329     StFrm         = 7  << FormShift,
330     LdMiscFrm     = 8  << FormShift,
331     StMiscFrm     = 9  << FormShift,
332     LdStMulFrm    = 10 << FormShift,
333 
334     LdStExFrm     = 11 << FormShift,
335 
336     // Miscellaneous arithmetic instructions
337     ArithMiscFrm  = 12 << FormShift,
338     SatFrm        = 13 << FormShift,
339 
340     // Extend instructions
341     ExtFrm        = 14 << FormShift,
342 
343     // VFP formats
344     VFPUnaryFrm   = 15 << FormShift,
345     VFPBinaryFrm  = 16 << FormShift,
346     VFPConv1Frm   = 17 << FormShift,
347     VFPConv2Frm   = 18 << FormShift,
348     VFPConv3Frm   = 19 << FormShift,
349     VFPConv4Frm   = 20 << FormShift,
350     VFPConv5Frm   = 21 << FormShift,
351     VFPLdStFrm    = 22 << FormShift,
352     VFPLdStMulFrm = 23 << FormShift,
353     VFPMiscFrm    = 24 << FormShift,
354 
355     // Thumb format
356     ThumbFrm      = 25 << FormShift,
357 
358     // Miscelleaneous format
359     MiscFrm       = 26 << FormShift,
360 
361     // NEON formats
362     NGetLnFrm     = 27 << FormShift,
363     NSetLnFrm     = 28 << FormShift,
364     NDupFrm       = 29 << FormShift,
365     NLdStFrm      = 30 << FormShift,
366     N1RegModImmFrm= 31 << FormShift,
367     N2RegFrm      = 32 << FormShift,
368     NVCVTFrm      = 33 << FormShift,
369     NVDupLnFrm    = 34 << FormShift,
370     N2RegVShLFrm  = 35 << FormShift,
371     N2RegVShRFrm  = 36 << FormShift,
372     N3RegFrm      = 37 << FormShift,
373     N3RegVShFrm   = 38 << FormShift,
374     NVExtFrm      = 39 << FormShift,
375     NVMulSLFrm    = 40 << FormShift,
376     NVTBLFrm      = 41 << FormShift,
377     N3RegCplxFrm  = 43 << FormShift,
378 
379     //===------------------------------------------------------------------===//
380     // Misc flags.
381 
382     // UnaryDP - Indicates this is a unary data processing instruction, i.e.
383     // it doesn't have a Rn operand.
384     UnaryDP       = 1 << 13,
385 
386     // Xform16Bit - Indicates this Thumb2 instruction may be transformed into
387     // a 16-bit Thumb instruction if certain conditions are met.
388     Xform16Bit    = 1 << 14,
389 
390     // ThumbArithFlagSetting - The instruction is a 16-bit flag setting Thumb
391     // instruction. Used by the parser to determine whether to require the 'S'
392     // suffix on the mnemonic (when not in an IT block) or preclude it (when
393     // in an IT block).
394     ThumbArithFlagSetting = 1 << 19,
395 
396     // Whether an instruction can be included in an MVE tail-predicated loop,
397     // though extra validity checks may need to be performed too.
398     ValidForTailPredication = 1 << 20,
399 
400     // Whether an instruction writes to the top/bottom half of a vector element
401     // and leaves the other half untouched.
402     RetainsPreviousHalfElement = 1 << 21,
403 
404     // Whether the instruction produces a scalar result from vector operands.
405     HorizontalReduction = 1 << 22,
406 
407     // Whether this instruction produces a vector result that is larger than
408     // its input, typically reading from the top/bottom halves of the input(s).
409     DoubleWidthResult = 1 << 23,
410 
411     //===------------------------------------------------------------------===//
412     // Code domain.
413     DomainShift   = 15,
414     DomainMask    = 15 << DomainShift,
415     DomainGeneral = 0 << DomainShift,
416     DomainVFP     = 1 << DomainShift,
417     DomainNEON    = 2 << DomainShift,
418     DomainNEONA8  = 4 << DomainShift,
419     DomainMVE     = 8 << DomainShift,
420 
421     //===------------------------------------------------------------------===//
422     // Field shifts - such shifts are used to set field while generating
423     // machine instructions.
424     //
425     // FIXME: This list will need adjusting/fixing as the MC code emitter
426     // takes shape and the ARMCodeEmitter.cpp bits go away.
427     ShiftTypeShift = 4,
428 
429     M_BitShift     = 5,
430     ShiftImmShift  = 5,
431     ShiftShift     = 7,
432     N_BitShift     = 7,
433     ImmHiShift     = 8,
434     SoRotImmShift  = 8,
435     RegRsShift     = 8,
436     ExtRotImmShift = 10,
437     RegRdLoShift   = 12,
438     RegRdShift     = 12,
439     RegRdHiShift   = 16,
440     RegRnShift     = 16,
441     S_BitShift     = 20,
442     W_BitShift     = 21,
443     AM3_I_BitShift = 22,
444     D_BitShift     = 22,
445     U_BitShift     = 23,
446     P_BitShift     = 24,
447     I_BitShift     = 25,
448     CondShift      = 28
449   };
450 
451 } // end namespace ARMII
452 
453 } // end namespace llvm;
454 
455 #endif
456