xref: /freebsd/contrib/llvm-project/lldb/include/lldb/Utility/ArchSpec.h (revision 0fca6ea1d4eea4c934cfff25ac9ee8ad6fe95583)
1 //===-- ArchSpec.h ----------------------------------------------*- 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 #ifndef LLDB_UTILITY_ARCHSPEC_H
10 #define LLDB_UTILITY_ARCHSPEC_H
11 
12 #include "lldb/Utility/CompletionRequest.h"
13 #include "lldb/lldb-enumerations.h"
14 #include "lldb/lldb-forward.h"
15 #include "lldb/lldb-private-enumerations.h"
16 #include "llvm/ADT/StringRef.h"
17 #include "llvm/TargetParser/Triple.h"
18 #include <cstddef>
19 #include <cstdint>
20 #include <string>
21 
22 namespace lldb_private {
23 
24 /// \class ArchSpec ArchSpec.h "lldb/Utility/ArchSpec.h" An architecture
25 /// specification class.
26 ///
27 /// A class designed to be created from a cpu type and subtype, a
28 /// string representation, or an llvm::Triple.  Keeping all of the conversions
29 /// of strings to architecture enumeration values confined to this class
30 /// allows new architecture support to be added easily.
31 class ArchSpec {
32 public:
33   enum MIPSSubType {
34     eMIPSSubType_unknown,
35     eMIPSSubType_mips32,
36     eMIPSSubType_mips32r2,
37     eMIPSSubType_mips32r6,
38     eMIPSSubType_mips32el,
39     eMIPSSubType_mips32r2el,
40     eMIPSSubType_mips32r6el,
41     eMIPSSubType_mips64,
42     eMIPSSubType_mips64r2,
43     eMIPSSubType_mips64r6,
44     eMIPSSubType_mips64el,
45     eMIPSSubType_mips64r2el,
46     eMIPSSubType_mips64r6el,
47   };
48 
49   // Masks for the ases word of an ABI flags structure.
50   enum MIPSASE {
51     eMIPSAse_dsp = 0x00000001,       // DSP ASE
52     eMIPSAse_dspr2 = 0x00000002,     // DSP R2 ASE
53     eMIPSAse_eva = 0x00000004,       // Enhanced VA Scheme
54     eMIPSAse_mcu = 0x00000008,       // MCU (MicroController) ASE
55     eMIPSAse_mdmx = 0x00000010,      // MDMX ASE
56     eMIPSAse_mips3d = 0x00000020,    // MIPS-3D ASE
57     eMIPSAse_mt = 0x00000040,        // MT ASE
58     eMIPSAse_smartmips = 0x00000080, // SmartMIPS ASE
59     eMIPSAse_virt = 0x00000100,      // VZ ASE
60     eMIPSAse_msa = 0x00000200,       // MSA ASE
61     eMIPSAse_mips16 = 0x00000400,    // MIPS16 ASE
62     eMIPSAse_micromips = 0x00000800, // MICROMIPS ASE
63     eMIPSAse_xpa = 0x00001000,       // XPA ASE
64     eMIPSAse_mask = 0x00001fff,
65     eMIPSABI_O32 = 0x00002000,
66     eMIPSABI_N32 = 0x00004000,
67     eMIPSABI_N64 = 0x00008000,
68     eMIPSABI_O64 = 0x00020000,
69     eMIPSABI_EABI32 = 0x00040000,
70     eMIPSABI_EABI64 = 0x00080000,
71     eMIPSABI_mask = 0x000ff000
72   };
73 
74   // MIPS Floating point ABI Values
75   enum MIPS_ABI_FP {
76     eMIPS_ABI_FP_ANY = 0x00000000,
77     eMIPS_ABI_FP_DOUBLE = 0x00100000, // hard float / -mdouble-float
78     eMIPS_ABI_FP_SINGLE = 0x00200000, // hard float / -msingle-float
79     eMIPS_ABI_FP_SOFT = 0x00300000,   // soft float
80     eMIPS_ABI_FP_OLD_64 = 0x00400000, // -mips32r2 -mfp64
81     eMIPS_ABI_FP_XX = 0x00500000,     // -mfpxx
82     eMIPS_ABI_FP_64 = 0x00600000,     // -mips32r2 -mfp64
83     eMIPS_ABI_FP_64A = 0x00700000,    // -mips32r2 -mfp64 -mno-odd-spreg
84     eMIPS_ABI_FP_mask = 0x00700000
85   };
86 
87   // ARM specific e_flags
88   enum ARMeflags {
89     eARM_abi_soft_float = 0x00000200,
90     eARM_abi_hard_float = 0x00000400
91   };
92 
93   enum RISCVeflags {
94     eRISCV_rvc              = 0x00000001, /// RVC, +c
95     eRISCV_float_abi_soft   = 0x00000000, /// soft float
96     eRISCV_float_abi_single = 0x00000002, /// single precision floating point, +f
97     eRISCV_float_abi_double = 0x00000004, /// double precision floating point, +d
98     eRISCV_float_abi_quad   = 0x00000006, /// quad precision floating point, +q
99     eRISCV_float_abi_mask   = 0x00000006,
100     eRISCV_rve              = 0x00000008, /// RVE, +e
101     eRISCV_tso              = 0x00000010, /// RVTSO (total store ordering)
102   };
103 
104   enum RISCVSubType {
105     eRISCVSubType_unknown,
106     eRISCVSubType_riscv32,
107     eRISCVSubType_riscv64,
108   };
109 
110   enum LoongArchSubType {
111     eLoongArchSubType_unknown,
112     eLoongArchSubType_loongarch32,
113     eLoongArchSubType_loongarch64,
114   };
115 
116   enum Core {
117     eCore_arm_generic,
118     eCore_arm_armv4,
119     eCore_arm_armv4t,
120     eCore_arm_armv5,
121     eCore_arm_armv5e,
122     eCore_arm_armv5t,
123     eCore_arm_armv6,
124     eCore_arm_armv6m,
125     eCore_arm_armv7,
126     eCore_arm_armv7l,
127     eCore_arm_armv7f,
128     eCore_arm_armv7s,
129     eCore_arm_armv7k,
130     eCore_arm_armv7m,
131     eCore_arm_armv7em,
132     eCore_arm_xscale,
133 
134     eCore_thumb,
135     eCore_thumbv4t,
136     eCore_thumbv5,
137     eCore_thumbv5e,
138     eCore_thumbv6,
139     eCore_thumbv6m,
140     eCore_thumbv7,
141     eCore_thumbv7s,
142     eCore_thumbv7k,
143     eCore_thumbv7f,
144     eCore_thumbv7m,
145     eCore_thumbv7em,
146     eCore_arm_arm64,
147     eCore_arm_armv8,
148     eCore_arm_armv8l,
149     eCore_arm_arm64e,
150     eCore_arm_arm64_32,
151     eCore_arm_aarch64,
152 
153     eCore_mips32,
154     eCore_mips32r2,
155     eCore_mips32r3,
156     eCore_mips32r5,
157     eCore_mips32r6,
158     eCore_mips32el,
159     eCore_mips32r2el,
160     eCore_mips32r3el,
161     eCore_mips32r5el,
162     eCore_mips32r6el,
163     eCore_mips64,
164     eCore_mips64r2,
165     eCore_mips64r3,
166     eCore_mips64r5,
167     eCore_mips64r6,
168     eCore_mips64el,
169     eCore_mips64r2el,
170     eCore_mips64r3el,
171     eCore_mips64r5el,
172     eCore_mips64r6el,
173 
174     eCore_msp430,
175 
176     eCore_ppc_generic,
177     eCore_ppc_ppc601,
178     eCore_ppc_ppc602,
179     eCore_ppc_ppc603,
180     eCore_ppc_ppc603e,
181     eCore_ppc_ppc603ev,
182     eCore_ppc_ppc604,
183     eCore_ppc_ppc604e,
184     eCore_ppc_ppc620,
185     eCore_ppc_ppc750,
186     eCore_ppc_ppc7400,
187     eCore_ppc_ppc7450,
188     eCore_ppc_ppc970,
189 
190     eCore_ppc64le_generic,
191     eCore_ppc64_generic,
192     eCore_ppc64_ppc970_64,
193 
194     eCore_s390x_generic,
195 
196     eCore_sparc_generic,
197 
198     eCore_sparc9_generic,
199 
200     eCore_x86_32_i386,
201     eCore_x86_32_i486,
202     eCore_x86_32_i486sx,
203     eCore_x86_32_i686,
204 
205     eCore_x86_64_x86_64,
206     eCore_x86_64_x86_64h, // Haswell enabled x86_64
207     eCore_hexagon_generic,
208     eCore_hexagon_hexagonv4,
209     eCore_hexagon_hexagonv5,
210 
211     eCore_riscv32,
212     eCore_riscv64,
213 
214     eCore_loongarch32,
215     eCore_loongarch64,
216 
217     eCore_uknownMach32,
218     eCore_uknownMach64,
219 
220     eCore_arc, // little endian ARC
221 
222     eCore_avr,
223 
224     eCore_wasm32,
225 
226     kNumCores,
227 
228     kCore_invalid,
229     // The following constants are used for wildcard matching only
230     kCore_any,
231     kCore_arm_any,
232     kCore_ppc_any,
233     kCore_ppc64_any,
234     kCore_x86_32_any,
235     kCore_x86_64_any,
236     kCore_hexagon_any,
237 
238     kCore_arm_first = eCore_arm_generic,
239     kCore_arm_last = eCore_arm_xscale,
240 
241     kCore_thumb_first = eCore_thumb,
242     kCore_thumb_last = eCore_thumbv7em,
243 
244     kCore_ppc_first = eCore_ppc_generic,
245     kCore_ppc_last = eCore_ppc_ppc970,
246 
247     kCore_ppc64_first = eCore_ppc64_generic,
248     kCore_ppc64_last = eCore_ppc64_ppc970_64,
249 
250     kCore_x86_32_first = eCore_x86_32_i386,
251     kCore_x86_32_last = eCore_x86_32_i686,
252 
253     kCore_x86_64_first = eCore_x86_64_x86_64,
254     kCore_x86_64_last = eCore_x86_64_x86_64h,
255 
256     kCore_hexagon_first = eCore_hexagon_generic,
257     kCore_hexagon_last = eCore_hexagon_hexagonv5,
258 
259     kCore_mips32_first = eCore_mips32,
260     kCore_mips32_last = eCore_mips32r6,
261 
262     kCore_mips32el_first = eCore_mips32el,
263     kCore_mips32el_last = eCore_mips32r6el,
264 
265     kCore_mips64_first = eCore_mips64,
266     kCore_mips64_last = eCore_mips64r6,
267 
268     kCore_mips64el_first = eCore_mips64el,
269     kCore_mips64el_last = eCore_mips64r6el,
270 
271     kCore_mips_first = eCore_mips32,
272     kCore_mips_last = eCore_mips64r6el
273 
274   };
275 
276   /// Default constructor.
277   ///
278   /// Default constructor that initializes the object with invalid cpu type
279   /// and subtype values.
280   ArchSpec();
281 
282   /// Constructor over triple.
283   ///
284   /// Constructs an ArchSpec with properties consistent with the given Triple.
285   explicit ArchSpec(const llvm::Triple &triple);
286   explicit ArchSpec(const char *triple_cstr);
287   explicit ArchSpec(llvm::StringRef triple_str);
288   /// Constructor over architecture name.
289   ///
290   /// Constructs an ArchSpec with properties consistent with the given object
291   /// type and architecture name.
292   explicit ArchSpec(ArchitectureType arch_type, uint32_t cpu_type,
293                     uint32_t cpu_subtype);
294 
295   /// Destructor.
296   ~ArchSpec();
297 
298   /// Returns true if the OS, vendor and environment fields of the triple are
299   /// unset. The triple is expected to be normalized
300   /// (llvm::Triple::normalize).
301   static bool ContainsOnlyArch(const llvm::Triple &normalized_triple);
302 
303   static void ListSupportedArchNames(StringList &list);
304   static void AutoComplete(CompletionRequest &request);
305 
306   /// Returns a static string representing the current architecture.
307   ///
308   /// \return A static string corresponding to the current
309   ///         architecture.
310   const char *GetArchitectureName() const;
311 
312   /// if MIPS architecture return true.
313   ///
314   ///  \return a boolean value.
315   bool IsMIPS() const;
316 
317   /// Returns a string representing current architecture as a target CPU for
318   /// tools like compiler, disassembler etc.
319   ///
320   /// \return A string representing target CPU for the current
321   ///         architecture.
322   std::string GetClangTargetCPU() const;
323 
324   /// Return a string representing target application ABI.
325   ///
326   /// \return A string representing target application ABI.
327   std::string GetTargetABI() const;
328 
329   /// Clears the object state.
330   ///
331   /// Clears the object state back to a default invalid state.
332   void Clear();
333 
334   /// Returns the size in bytes of an address of the current architecture.
335   ///
336   /// \return The byte size of an address of the current architecture.
337   uint32_t GetAddressByteSize() const;
338 
339   /// Returns a machine family for the current architecture.
340   ///
341   /// \return An LLVM arch type.
342   llvm::Triple::ArchType GetMachine() const;
343 
344   /// Tests if this ArchSpec is valid.
345   ///
346   /// \return True if the current architecture is valid, false
347   ///         otherwise.
IsValid()348   bool IsValid() const {
349     return m_core >= eCore_arm_generic && m_core < kNumCores;
350   }
351   explicit operator bool() const { return IsValid(); }
352 
TripleVendorWasSpecified()353   bool TripleVendorWasSpecified() const {
354     return !m_triple.getVendorName().empty();
355   }
356 
TripleOSWasSpecified()357   bool TripleOSWasSpecified() const { return !m_triple.getOSName().empty(); }
358 
TripleEnvironmentWasSpecified()359   bool TripleEnvironmentWasSpecified() const {
360     return m_triple.hasEnvironment();
361   }
362 
363   /// Merges fields from another ArchSpec into this ArchSpec.
364   ///
365   /// This will use the supplied ArchSpec to fill in any fields of the triple
366   /// in this ArchSpec which were unspecified.  This can be used to refine a
367   /// generic ArchSpec with a more specific one. For example, if this
368   /// ArchSpec's triple is something like i386-unknown-unknown-unknown, and we
369   /// have a triple which is x64-pc-windows-msvc, then merging that triple
370   /// into this one will result in the triple i386-pc-windows-msvc.
371   ///
372   void MergeFrom(const ArchSpec &other);
373 
374   /// Change the architecture object type, CPU type and OS type.
375   ///
376   /// \param[in] arch_type The object type of this ArchSpec.
377   ///
378   /// \param[in] cpu The required CPU type.
379   ///
380   /// \param[in] os The optional OS type
381   /// The default value of 0 was chosen to from the ELF spec value
382   /// ELFOSABI_NONE.  ELF is the only one using this parameter.  If another
383   /// format uses this parameter and 0 does not work, use a value over
384   /// 255 because in the ELF header this is value is only a byte.
385   ///
386   /// \return True if the object, and CPU were successfully set.
387   ///
388   /// As a side effect, the vendor value is usually set to unknown. The
389   /// exceptions are
390   ///   aarch64-apple-ios
391   ///   arm-apple-ios
392   ///   thumb-apple-ios
393   ///   x86-apple-
394   ///   x86_64-apple-
395   ///
396   /// As a side effect, the os value is usually set to unknown The exceptions
397   /// are
398   ///   *-*-aix
399   ///   aarch64-apple-ios
400   ///   arm-apple-ios
401   ///   thumb-apple-ios
402   ///   powerpc-apple-darwin
403   ///   *-*-freebsd
404   ///   *-*-linux
405   ///   *-*-netbsd
406   ///   *-*-openbsd
407   ///   *-*-solaris
408   bool SetArchitecture(ArchitectureType arch_type, uint32_t cpu, uint32_t sub,
409                        uint32_t os = 0);
410 
411   /// Returns the byte order for the architecture specification.
412   ///
413   /// \return The endian enumeration for the current endianness of
414   ///     the architecture specification
415   lldb::ByteOrder GetByteOrder() const;
416 
417   /// Sets this ArchSpec's byte order.
418   ///
419   /// In the common case there is no need to call this method as the byte
420   /// order can almost always be determined by the architecture. However, many
421   /// CPU's are bi-endian (ARM, Alpha, PowerPC, etc) and the default/assumed
422   /// byte order may be incorrect.
SetByteOrder(lldb::ByteOrder byte_order)423   void SetByteOrder(lldb::ByteOrder byte_order) { m_byte_order = byte_order; }
424 
425   uint32_t GetMinimumOpcodeByteSize() const;
426 
427   uint32_t GetMaximumOpcodeByteSize() const;
428 
GetCore()429   Core GetCore() const { return m_core; }
430 
431   uint32_t GetMachOCPUType() const;
432 
433   uint32_t GetMachOCPUSubType() const;
434 
435   /// Architecture data byte width accessor
436   ///
437   /// \return the size in 8-bit (host) bytes of a minimum addressable unit
438   /// from the Architecture's data bus
439   uint32_t GetDataByteSize() const;
440 
441   /// Architecture code byte width accessor
442   ///
443   /// \return the size in 8-bit (host) bytes of a minimum addressable unit
444   /// from the Architecture's code bus
445   uint32_t GetCodeByteSize() const;
446 
447   /// Architecture triple accessor.
448   ///
449   /// \return A triple describing this ArchSpec.
GetTriple()450   llvm::Triple &GetTriple() { return m_triple; }
451 
452   /// Architecture triple accessor.
453   ///
454   /// \return A triple describing this ArchSpec.
GetTriple()455   const llvm::Triple &GetTriple() const { return m_triple; }
456 
457   void DumpTriple(llvm::raw_ostream &s) const;
458 
459   /// Architecture triple setter.
460   ///
461   /// Configures this ArchSpec according to the given triple.  If the triple
462   /// has unknown components in all of the vendor, OS, and the optional
463   /// environment field (i.e. "i386-unknown-unknown") then default values are
464   /// taken from the host.  Architecture and environment components are used
465   /// to further resolve the CPU type and subtype, endian characteristics,
466   /// etc.
467   ///
468   /// \return A triple describing this ArchSpec.
469   bool SetTriple(const llvm::Triple &triple);
470 
471   bool SetTriple(llvm::StringRef triple_str);
472 
473   /// Returns the default endianness of the architecture.
474   ///
475   /// \return The endian enumeration for the default endianness of
476   ///         the architecture.
477   lldb::ByteOrder GetDefaultEndian() const;
478 
479   /// Returns true if 'char' is a signed type by default in the architecture
480   /// false otherwise
481   ///
482   /// \return True if 'char' is a signed type by default on the
483   ///         architecture and false otherwise.
484   bool CharIsSignedByDefault() const;
485 
486   enum MatchType : bool { CompatibleMatch, ExactMatch };
487 
488   /// Compare this ArchSpec to another ArchSpec. \a match specifies the kind of
489   /// matching that is to be done. CompatibleMatch requires only a compatible
490   /// cpu type (e.g., armv7s is compatible with armv7). ExactMatch requires an
491   /// exact match (armv7s is not an exact match with armv7).
492   ///
493   /// \return true if the two ArchSpecs match.
494   bool IsMatch(const ArchSpec &rhs, MatchType match) const;
495 
496   /// Shorthand for IsMatch(rhs, ExactMatch).
IsExactMatch(const ArchSpec & rhs)497   bool IsExactMatch(const ArchSpec &rhs) const {
498     return IsMatch(rhs, ExactMatch);
499   }
500 
501   /// Shorthand for IsMatch(rhs, CompatibleMatch).
IsCompatibleMatch(const ArchSpec & rhs)502   bool IsCompatibleMatch(const ArchSpec &rhs) const {
503     return IsMatch(rhs, CompatibleMatch);
504   }
505 
506   bool IsFullySpecifiedTriple() const;
507 
508   /// Detect whether this architecture uses thumb code exclusively
509   ///
510   /// Some embedded ARM chips (e.g. the ARM Cortex M0-7 line) can only execute
511   /// the Thumb instructions, never Arm.  We should normally pick up
512   /// arm/thumbness from their the processor status bits (cpsr/xpsr) or hints
513   /// on each function - but when doing bare-boards low level debugging
514   /// (especially common with these embedded processors), we may not have
515   /// those things easily accessible.
516   ///
517   /// \return true if this is an arm ArchSpec which can only execute Thumb
518   ///         instructions
519   bool IsAlwaysThumbInstructions() const;
520 
GetFlags()521   uint32_t GetFlags() const { return m_flags; }
522 
SetFlags(uint32_t flags)523   void SetFlags(uint32_t flags) { m_flags = flags; }
524 
525   void SetFlags(const std::string &elf_abi);
526 
527 protected:
528   void UpdateCore();
529 
530   llvm::Triple m_triple;
531   Core m_core = kCore_invalid;
532   lldb::ByteOrder m_byte_order = lldb::eByteOrderInvalid;
533 
534   // Additional arch flags which we cannot get from triple and core For MIPS
535   // these are application specific extensions like micromips, mips16 etc.
536   uint32_t m_flags = 0;
537 
538   // Called when m_def or m_entry are changed.  Fills in all remaining members
539   // with default values.
540   void CoreUpdated(bool update_triple);
541 };
542 
543 /// \fn bool operator< (const ArchSpec& lhs, const ArchSpec& rhs) Less than
544 /// operator.
545 ///
546 /// Tests two ArchSpec objects to see if \a lhs is less than \a rhs.
547 ///
548 /// \param[in] lhs The Left Hand Side ArchSpec object to compare. \param[in]
549 /// rhs The Left Hand Side ArchSpec object to compare.
550 ///
551 /// \return true if \a lhs is less than \a rhs
552 bool operator<(const ArchSpec &lhs, const ArchSpec &rhs);
553 bool operator==(const ArchSpec &lhs, const ArchSpec &rhs);
554 
555 bool ParseMachCPUDashSubtypeTriple(llvm::StringRef triple_str, ArchSpec &arch);
556 
557 } // namespace lldb_private
558 
559 #endif // LLDB_UTILITY_ARCHSPEC_H
560