1 //===-- llvm/Target/TargetOpcodes.h - Target Indep Opcodes ------*- C++ -*-===// 2 // 3 // The LLVM Compiler Infrastructure 4 // 5 // This file is distributed under the University of Illinois Open Source 6 // License. See LICENSE.TXT for details. 7 // 8 //===----------------------------------------------------------------------===// 9 // 10 // This file defines the target independent instruction opcodes. 11 // 12 //===----------------------------------------------------------------------===// 13 14 #ifndef LLVM_TARGET_TARGETOPCODES_H 15 #define LLVM_TARGET_TARGETOPCODES_H 16 17 namespace llvm { 18 19 /// Invariant opcodes: All instruction sets have these as their low opcodes. 20 /// 21 /// Every instruction defined here must also appear in Target.td and the order 22 /// must be the same as in CodeGenTarget.cpp. 23 /// 24 namespace TargetOpcode { 25 enum { 26 PHI = 0, 27 INLINEASM = 1, 28 CFI_INSTRUCTION = 2, 29 EH_LABEL = 3, 30 GC_LABEL = 4, 31 32 /// KILL - This instruction is a noop that is used only to adjust the 33 /// liveness of registers. This can be useful when dealing with 34 /// sub-registers. 35 KILL = 5, 36 37 /// EXTRACT_SUBREG - This instruction takes two operands: a register 38 /// that has subregisters, and a subregister index. It returns the 39 /// extracted subregister value. This is commonly used to implement 40 /// truncation operations on target architectures which support it. 41 EXTRACT_SUBREG = 6, 42 43 /// INSERT_SUBREG - This instruction takes three operands: a register that 44 /// has subregisters, a register providing an insert value, and a 45 /// subregister index. It returns the value of the first register with the 46 /// value of the second register inserted. The first register is often 47 /// defined by an IMPLICIT_DEF, because it is commonly used to implement 48 /// anyext operations on target architectures which support it. 49 INSERT_SUBREG = 7, 50 51 /// IMPLICIT_DEF - This is the MachineInstr-level equivalent of undef. 52 IMPLICIT_DEF = 8, 53 54 /// SUBREG_TO_REG - This instruction is similar to INSERT_SUBREG except that 55 /// the first operand is an immediate integer constant. This constant is 56 /// often zero, because it is commonly used to assert that the instruction 57 /// defining the register implicitly clears the high bits. 58 SUBREG_TO_REG = 9, 59 60 /// COPY_TO_REGCLASS - This instruction is a placeholder for a plain 61 /// register-to-register copy into a specific register class. This is only 62 /// used between instruction selection and MachineInstr creation, before 63 /// virtual registers have been created for all the instructions, and it's 64 /// only needed in cases where the register classes implied by the 65 /// instructions are insufficient. It is emitted as a COPY MachineInstr. 66 COPY_TO_REGCLASS = 10, 67 68 /// DBG_VALUE - a mapping of the llvm.dbg.value intrinsic 69 DBG_VALUE = 11, 70 71 /// REG_SEQUENCE - This variadic instruction is used to form a register that 72 /// represents a consecutive sequence of sub-registers. It's used as a 73 /// register coalescing / allocation aid and must be eliminated before code 74 /// emission. 75 // In SDNode form, the first operand encodes the register class created by 76 // the REG_SEQUENCE, while each subsequent pair names a vreg + subreg index 77 // pair. Once it has been lowered to a MachineInstr, the regclass operand 78 // is no longer present. 79 /// e.g. v1027 = REG_SEQUENCE v1024, 3, v1025, 4, v1026, 5 80 /// After register coalescing references of v1024 should be replace with 81 /// v1027:3, v1025 with v1027:4, etc. 82 REG_SEQUENCE = 12, 83 84 /// COPY - Target-independent register copy. This instruction can also be 85 /// used to copy between subregisters of virtual registers. 86 COPY = 13, 87 88 /// BUNDLE - This instruction represents an instruction bundle. Instructions 89 /// which immediately follow a BUNDLE instruction which are marked with 90 /// 'InsideBundle' flag are inside the bundle. 91 BUNDLE = 14, 92 93 /// Lifetime markers. 94 LIFETIME_START = 15, 95 LIFETIME_END = 16, 96 97 /// A Stackmap instruction captures the location of live variables at its 98 /// position in the instruction stream. It is followed by a shadow of bytes 99 /// that must lie within the function and not contain another stackmap. 100 STACKMAP = 17, 101 102 /// Patchable call instruction - this instruction represents a call to a 103 /// constant address, followed by a series of NOPs. It is intended to 104 /// support optimizations for dynamic languages (such as javascript) that 105 /// rewrite calls to runtimes with more efficient code sequences. 106 /// This also implies a stack map. 107 PATCHPOINT = 18, 108 109 /// This pseudo-instruction loads the stack guard value. Targets which need 110 /// to prevent the stack guard value or address from being spilled to the 111 /// stack should override TargetLowering::emitLoadStackGuardNode and 112 /// additionally expand this pseudo after register allocation. 113 LOAD_STACK_GUARD = 19, 114 115 /// Call instruction with associated vm state for deoptimization and list 116 /// of live pointers for relocation by the garbage collector. It is 117 /// intended to support garbage collection with fully precise relocating 118 /// collectors and deoptimizations in either the callee or caller. 119 STATEPOINT = 20, 120 121 /// Instruction that records the offset of a function's frame allocation in a 122 /// label. Created by the llvm.frameallocate intrinsic. It has two arguments: 123 /// the symbol for the label and the frame index of the stack allocation. 124 FRAME_ALLOC = 21, 125 }; 126 } // end namespace TargetOpcode 127 } // end namespace llvm 128 129 #endif 130