syzkaller/vendor/honnef.co/go/tools/ir/ssa.go
Dmitry Vyukov 4705549800 vendor: update vendored files
Required to switch dashboard/app to go1.11.

Update #1461
2020-01-29 16:01:06 +01:00

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// Copyright 2013 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package ir
// This package defines a high-level intermediate representation for
// Go programs using static single-information (SSI) form.
import (
"fmt"
"go/ast"
"go/constant"
"go/token"
"go/types"
"sync"
"golang.org/x/tools/go/types/typeutil"
)
type ID int32
// A Program is a partial or complete Go program converted to IR form.
type Program struct {
Fset *token.FileSet // position information for the files of this Program
PrintFunc string // create ir.html for function specified in PrintFunc
imported map[string]*Package // all importable Packages, keyed by import path
packages map[*types.Package]*Package // all loaded Packages, keyed by object
mode BuilderMode // set of mode bits for IR construction
MethodSets typeutil.MethodSetCache // cache of type-checker's method-sets
methodsMu sync.Mutex // guards the following maps:
methodSets typeutil.Map // maps type to its concrete methodSet
runtimeTypes typeutil.Map // types for which rtypes are needed
canon typeutil.Map // type canonicalization map
bounds map[*types.Func]*Function // bounds for curried x.Method closures
thunks map[selectionKey]*Function // thunks for T.Method expressions
}
// A Package is a single analyzed Go package containing Members for
// all package-level functions, variables, constants and types it
// declares. These may be accessed directly via Members, or via the
// type-specific accessor methods Func, Type, Var and Const.
//
// Members also contains entries for "init" (the synthetic package
// initializer) and "init#%d", the nth declared init function,
// and unspecified other things too.
//
type Package struct {
Prog *Program // the owning program
Pkg *types.Package // the corresponding go/types.Package
Members map[string]Member // all package members keyed by name (incl. init and init#%d)
Functions []*Function // all functions, including anonymous ones
values map[types.Object]Value // package members (incl. types and methods), keyed by object
init *Function // Func("init"); the package's init function
debug bool // include full debug info in this package
printFunc string // which function to print in HTML form
// The following fields are set transiently, then cleared
// after building.
buildOnce sync.Once // ensures package building occurs once
ninit int32 // number of init functions
info *types.Info // package type information
files []*ast.File // package ASTs
}
// A Member is a member of a Go package, implemented by *NamedConst,
// *Global, *Function, or *Type; they are created by package-level
// const, var, func and type declarations respectively.
//
type Member interface {
Name() string // declared name of the package member
String() string // package-qualified name of the package member
RelString(*types.Package) string // like String, but relative refs are unqualified
Object() types.Object // typechecker's object for this member, if any
Type() types.Type // type of the package member
Token() token.Token // token.{VAR,FUNC,CONST,TYPE}
Package() *Package // the containing package
}
// A Type is a Member of a Package representing a package-level named type.
type Type struct {
object *types.TypeName
pkg *Package
}
// A NamedConst is a Member of a Package representing a package-level
// named constant.
//
// Pos() returns the position of the declaring ast.ValueSpec.Names[*]
// identifier.
//
// NB: a NamedConst is not a Value; it contains a constant Value, which
// it augments with the name and position of its 'const' declaration.
//
type NamedConst struct {
object *types.Const
Value *Const
pkg *Package
}
// A Value is an IR value that can be referenced by an instruction.
type Value interface {
setID(ID)
// Name returns the name of this value, and determines how
// this Value appears when used as an operand of an
// Instruction.
//
// This is the same as the source name for Parameters,
// Builtins, Functions, FreeVars, Globals.
// For constants, it is a representation of the constant's value
// and type. For all other Values this is the name of the
// virtual register defined by the instruction.
//
// The name of an IR Value is not semantically significant,
// and may not even be unique within a function.
Name() string
// ID returns the ID of this value. IDs are unique within a single
// function and are densely numbered, but may contain gaps.
// Values and other Instructions share the same ID space.
// Globally, values are identified by their addresses. However,
// IDs exist to facilitate efficient storage of mappings between
// values and data when analysing functions.
//
// NB: IDs are allocated late in the IR construction process and
// are not available to early stages of said process.
ID() ID
// If this value is an Instruction, String returns its
// disassembled form; otherwise it returns unspecified
// human-readable information about the Value, such as its
// kind, name and type.
String() string
// Type returns the type of this value. Many instructions
// (e.g. IndexAddr) change their behaviour depending on the
// types of their operands.
Type() types.Type
// Parent returns the function to which this Value belongs.
// It returns nil for named Functions, Builtin and Global.
Parent() *Function
// Referrers returns the list of instructions that have this
// value as one of their operands; it may contain duplicates
// if an instruction has a repeated operand.
//
// Referrers actually returns a pointer through which the
// caller may perform mutations to the object's state.
//
// Referrers is currently only defined if Parent()!=nil,
// i.e. for the function-local values FreeVar, Parameter,
// Functions (iff anonymous) and all value-defining instructions.
// It returns nil for named Functions, Builtin and Global.
//
// Instruction.Operands contains the inverse of this relation.
Referrers() *[]Instruction
Operands(rands []*Value) []*Value // nil for non-Instructions
// Source returns the AST node responsible for creating this
// value. A single AST node may be responsible for more than one
// value, and not all values have an associated AST node.
//
// Do not use this method to find a Value given an ast.Expr; use
// ValueForExpr instead.
Source() ast.Node
// Pos returns Source().Pos() if Source is not nil, else it
// returns token.NoPos.
Pos() token.Pos
}
// An Instruction is an IR instruction that computes a new Value or
// has some effect.
//
// An Instruction that defines a value (e.g. BinOp) also implements
// the Value interface; an Instruction that only has an effect (e.g. Store)
// does not.
//
type Instruction interface {
setSource(ast.Node)
setID(ID)
// String returns the disassembled form of this value.
//
// Examples of Instructions that are Values:
// "BinOp <int> {+} t1 t2" (BinOp)
// "Call <int> len t1" (Call)
// Note that the name of the Value is not printed.
//
// Examples of Instructions that are not Values:
// "Return t1" (Return)
// "Store {int} t2 t1" (Store)
//
// (The separation of Value.Name() from Value.String() is useful
// for some analyses which distinguish the operation from the
// value it defines, e.g., 'y = local int' is both an allocation
// of memory 'local int' and a definition of a pointer y.)
String() string
// ID returns the ID of this instruction. IDs are unique within a single
// function and are densely numbered, but may contain gaps.
// Globally, instructions are identified by their addresses. However,
// IDs exist to facilitate efficient storage of mappings between
// instructions and data when analysing functions.
//
// NB: IDs are allocated late in the IR construction process and
// are not available to early stages of said process.
ID() ID
// Parent returns the function to which this instruction
// belongs.
Parent() *Function
// Block returns the basic block to which this instruction
// belongs.
Block() *BasicBlock
// setBlock sets the basic block to which this instruction belongs.
setBlock(*BasicBlock)
// Operands returns the operands of this instruction: the
// set of Values it references.
//
// Specifically, it appends their addresses to rands, a
// user-provided slice, and returns the resulting slice,
// permitting avoidance of memory allocation.
//
// The operands are appended in undefined order, but the order
// is consistent for a given Instruction; the addresses are
// always non-nil but may point to a nil Value. Clients may
// store through the pointers, e.g. to effect a value
// renaming.
//
// Value.Referrers is a subset of the inverse of this
// relation. (Referrers are not tracked for all types of
// Values.)
Operands(rands []*Value) []*Value
Referrers() *[]Instruction // nil for non-Values
// Source returns the AST node responsible for creating this
// instruction. A single AST node may be responsible for more than
// one instruction, and not all instructions have an associated
// AST node.
Source() ast.Node
// Pos returns Source().Pos() if Source is not nil, else it
// returns token.NoPos.
Pos() token.Pos
}
// A Node is a node in the IR value graph. Every concrete type that
// implements Node is also either a Value, an Instruction, or both.
//
// Node contains the methods common to Value and Instruction, plus the
// Operands and Referrers methods generalized to return nil for
// non-Instructions and non-Values, respectively.
//
// Node is provided to simplify IR graph algorithms. Clients should
// use the more specific and informative Value or Instruction
// interfaces where appropriate.
//
type Node interface {
setID(ID)
// Common methods:
ID() ID
String() string
Source() ast.Node
Pos() token.Pos
Parent() *Function
// Partial methods:
Operands(rands []*Value) []*Value // nil for non-Instructions
Referrers() *[]Instruction // nil for non-Values
}
// Function represents the parameters, results, and code of a function
// or method.
//
// If Blocks is nil, this indicates an external function for which no
// Go source code is available. In this case, FreeVars and Locals
// are nil too. Clients performing whole-program analysis must
// handle external functions specially.
//
// Blocks contains the function's control-flow graph (CFG).
// Blocks[0] is the function entry point; block order is not otherwise
// semantically significant, though it may affect the readability of
// the disassembly.
// To iterate over the blocks in dominance order, use DomPreorder().
//
// A nested function (Parent()!=nil) that refers to one or more
// lexically enclosing local variables ("free variables") has FreeVars.
// Such functions cannot be called directly but require a
// value created by MakeClosure which, via its Bindings, supplies
// values for these parameters.
//
// If the function is a method (Signature.Recv() != nil) then the first
// element of Params is the receiver parameter.
//
// A Go package may declare many functions called "init".
// For each one, Object().Name() returns "init" but Name() returns
// "init#1", etc, in declaration order.
//
// Pos() returns the declaring ast.FuncLit.Type.Func or the position
// of the ast.FuncDecl.Name, if the function was explicit in the
// source. Synthetic wrappers, for which Synthetic != "", may share
// the same position as the function they wrap.
// Syntax.Pos() always returns the position of the declaring "func" token.
//
// Type() returns the function's Signature.
//
type Function struct {
node
name string
object types.Object // a declared *types.Func or one of its wrappers
method *types.Selection // info about provenance of synthetic methods
Signature *types.Signature
Synthetic string // provenance of synthetic function; "" for true source functions
parent *Function // enclosing function if anon; nil if global
Pkg *Package // enclosing package; nil for shared funcs (wrappers and error.Error)
Prog *Program // enclosing program
Params []*Parameter // function parameters; for methods, includes receiver
FreeVars []*FreeVar // free variables whose values must be supplied by closure
Locals []*Alloc // local variables of this function
Blocks []*BasicBlock // basic blocks of the function; nil => external
Exit *BasicBlock // The function's exit block
AnonFuncs []*Function // anonymous functions directly beneath this one
referrers []Instruction // referring instructions (iff Parent() != nil)
hasDefer bool
WillExit bool // Calling this function will always terminate the process
WillUnwind bool // Calling this function will always unwind (it will call runtime.Goexit or panic)
// The following fields are set transiently during building,
// then cleared.
currentBlock *BasicBlock // where to emit code
objects map[types.Object]Value // addresses of local variables
namedResults []*Alloc // tuple of named results
implicitResults []*Alloc // tuple of results
targets *targets // linked stack of branch targets
lblocks map[*ast.Object]*lblock // labelled blocks
consts []*Const
wr *HTMLWriter
fakeExits BlockSet
blocksets [5]BlockSet
}
func (fn *Function) results() []*Alloc {
if len(fn.namedResults) > 0 {
return fn.namedResults
}
return fn.implicitResults
}
// BasicBlock represents an IR basic block.
//
// The final element of Instrs is always an explicit transfer of
// control (If, Jump, Return, Panic, or Unreachable).
//
// A block may contain no Instructions only if it is unreachable,
// i.e., Preds is nil. Empty blocks are typically pruned.
//
// BasicBlocks and their Preds/Succs relation form a (possibly cyclic)
// graph independent of the IR Value graph: the control-flow graph or
// CFG. It is illegal for multiple edges to exist between the same
// pair of blocks.
//
// Each BasicBlock is also a node in the dominator tree of the CFG.
// The tree may be navigated using Idom()/Dominees() and queried using
// Dominates().
//
// The order of Preds and Succs is significant (to Phi and If
// instructions, respectively).
//
type BasicBlock struct {
Index int // index of this block within Parent().Blocks
Comment string // optional label; no semantic significance
parent *Function // parent function
Instrs []Instruction // instructions in order
Preds, Succs []*BasicBlock // predecessors and successors
succs2 [2]*BasicBlock // initial space for Succs
dom domInfo // dominator tree info
pdom domInfo // post-dominator tree info
post int
gaps int // number of nil Instrs (transient)
rundefers int // number of rundefers (transient)
}
// Pure values ----------------------------------------
// A FreeVar represents a free variable of the function to which it
// belongs.
//
// FreeVars are used to implement anonymous functions, whose free
// variables are lexically captured in a closure formed by
// MakeClosure. The value of such a free var is an Alloc or another
// FreeVar and is considered a potentially escaping heap address, with
// pointer type.
//
// FreeVars are also used to implement bound method closures. Such a
// free var represents the receiver value and may be of any type that
// has concrete methods.
//
// Pos() returns the position of the value that was captured, which
// belongs to an enclosing function.
//
type FreeVar struct {
node
name string
typ types.Type
parent *Function
referrers []Instruction
// Transiently needed during building.
outer Value // the Value captured from the enclosing context.
}
// A Parameter represents an input parameter of a function.
//
type Parameter struct {
register
name string
object types.Object // a *types.Var; nil for non-source locals
}
// A Const represents the value of a constant expression.
//
// The underlying type of a constant may be any boolean, numeric, or
// string type. In addition, a Const may represent the nil value of
// any reference type---interface, map, channel, pointer, slice, or
// function---but not "untyped nil".
//
// All source-level constant expressions are represented by a Const
// of the same type and value.
//
// Value holds the exact value of the constant, independent of its
// Type(), using the same representation as package go/constant uses for
// constants, or nil for a typed nil value.
//
// Pos() returns token.NoPos.
//
// Example printed form:
// Const <int> {42}
// Const <untyped string> {"test"}
// Const <MyComplex> {(3 + 4i)}
//
type Const struct {
register
Value constant.Value
}
// A Global is a named Value holding the address of a package-level
// variable.
//
// Pos() returns the position of the ast.ValueSpec.Names[*]
// identifier.
//
type Global struct {
node
name string
object types.Object // a *types.Var; may be nil for synthetics e.g. init$guard
typ types.Type
Pkg *Package
}
// A Builtin represents a specific use of a built-in function, e.g. len.
//
// Builtins are immutable values. Builtins do not have addresses.
// Builtins can only appear in CallCommon.Func.
//
// Name() indicates the function: one of the built-in functions from the
// Go spec (excluding "make" and "new") or one of these ir-defined
// intrinsics:
//
// // wrapnilchk returns ptr if non-nil, panics otherwise.
// // (For use in indirection wrappers.)
// func ir:wrapnilchk(ptr *T, recvType, methodName string) *T
//
// Object() returns a *types.Builtin for built-ins defined by the spec,
// nil for others.
//
// Type() returns a *types.Signature representing the effective
// signature of the built-in for this call.
//
type Builtin struct {
node
name string
sig *types.Signature
}
// Value-defining instructions ----------------------------------------
// The Alloc instruction reserves space for a variable of the given type,
// zero-initializes it, and yields its address.
//
// Alloc values are always addresses, and have pointer types, so the
// type of the allocated variable is actually
// Type().Underlying().(*types.Pointer).Elem().
//
// If Heap is false, Alloc allocates space in the function's
// activation record (frame); we refer to an Alloc(Heap=false) as a
// "stack" alloc. Each stack Alloc returns the same address each time
// it is executed within the same activation; the space is
// re-initialized to zero.
//
// If Heap is true, Alloc allocates space in the heap; we
// refer to an Alloc(Heap=true) as a "heap" alloc. Each heap Alloc
// returns a different address each time it is executed.
//
// When Alloc is applied to a channel, map or slice type, it returns
// the address of an uninitialized (nil) reference of that kind; store
// the result of MakeSlice, MakeMap or MakeChan in that location to
// instantiate these types.
//
// Pos() returns the ast.CompositeLit.Lbrace for a composite literal,
// or the ast.CallExpr.Rparen for a call to new() or for a call that
// allocates a varargs slice.
//
// Example printed form:
// t1 = StackAlloc <*int>
// t2 = HeapAlloc <*int> (new)
//
type Alloc struct {
register
Comment string
Heap bool
index int // dense numbering; for lifting
}
var _ Instruction = (*Sigma)(nil)
var _ Value = (*Sigma)(nil)
// The Sigma instruction represents an SSI σ-node, which splits values
// at branches in the control flow.
//
// Conceptually, σ-nodes exist at the end of blocks that branch and
// constitute parallel assignments to one value per destination block.
// However, such a representation would be awkward to work with, so
// instead we place σ-nodes at the beginning of branch targets. The
// From field denotes to which incoming edge the node applies.
//
// Within a block, all σ-nodes must appear before all non-σ nodes.
//
// Example printed form:
// t2 = Sigma <int> [#0] t1 (x)
//
type Sigma struct {
register
From *BasicBlock
X Value
Comment string
live bool // used during lifting
}
// The Phi instruction represents an SSA φ-node, which combines values
// that differ across incoming control-flow edges and yields a new
// value. Within a block, all φ-nodes must appear before all non-φ, non-σ
// nodes.
//
// Pos() returns the position of the && or || for short-circuit
// control-flow joins, or that of the *Alloc for φ-nodes inserted
// during SSA renaming.
//
// Example printed form:
// t3 = Phi <int> 2:t1 4:t2 (x)
//
type Phi struct {
register
Comment string // a hint as to its purpose
Edges []Value // Edges[i] is value for Block().Preds[i]
live bool // used during lifting
}
// The Call instruction represents a function or method call.
//
// The Call instruction yields the function result if there is exactly
// one. Otherwise it returns a tuple, the components of which are
// accessed via Extract.
//
// See CallCommon for generic function call documentation.
//
// Pos() returns the ast.CallExpr.Lparen, if explicit in the source.
//
// Example printed form:
// t3 = Call <()> println t1 t2
// t4 = Call <()> foo$1
// t6 = Invoke <string> t5.String
//
type Call struct {
register
Call CallCommon
}
// The BinOp instruction yields the result of binary operation X Op Y.
//
// Pos() returns the ast.BinaryExpr.OpPos, if explicit in the source.
//
// Example printed form:
// t3 = BinOp <int> {+} t2 t1
//
type BinOp struct {
register
// One of:
// ADD SUB MUL QUO REM + - * / %
// AND OR XOR SHL SHR AND_NOT & | ^ << >> &^
// EQL NEQ LSS LEQ GTR GEQ == != < <= < >=
Op token.Token
X, Y Value
}
// The UnOp instruction yields the result of Op X.
// XOR is bitwise complement.
// SUB is negation.
// NOT is logical negation.
//
//
// Example printed form:
// t2 = UnOp <int> {^} t1
//
type UnOp struct {
register
Op token.Token // One of: NOT SUB XOR ! - ^
X Value
}
// The Load instruction loads a value from a memory address.
//
// For implicit memory loads, Pos() returns the position of the
// most closely associated source-level construct; the details are not
// specified.
//
// Example printed form:
// t2 = Load <int> t1
//
type Load struct {
register
X Value
}
// The ChangeType instruction applies to X a value-preserving type
// change to Type().
//
// Type changes are permitted:
// - between a named type and its underlying type.
// - between two named types of the same underlying type.
// - between (possibly named) pointers to identical base types.
// - from a bidirectional channel to a read- or write-channel,
// optionally adding/removing a name.
//
// This operation cannot fail dynamically.
//
// Pos() returns the ast.CallExpr.Lparen, if the instruction arose
// from an explicit conversion in the source.
//
// Example printed form:
// t2 = ChangeType <*T> t1
//
type ChangeType struct {
register
X Value
}
// The Convert instruction yields the conversion of value X to type
// Type(). One or both of those types is basic (but possibly named).
//
// A conversion may change the value and representation of its operand.
// Conversions are permitted:
// - between real numeric types.
// - between complex numeric types.
// - between string and []byte or []rune.
// - between pointers and unsafe.Pointer.
// - between unsafe.Pointer and uintptr.
// - from (Unicode) integer to (UTF-8) string.
// A conversion may imply a type name change also.
//
// This operation cannot fail dynamically.
//
// Conversions of untyped string/number/bool constants to a specific
// representation are eliminated during IR construction.
//
// Pos() returns the ast.CallExpr.Lparen, if the instruction arose
// from an explicit conversion in the source.
//
// Example printed form:
// t2 = Convert <[]byte> t1
//
type Convert struct {
register
X Value
}
// ChangeInterface constructs a value of one interface type from a
// value of another interface type known to be assignable to it.
// This operation cannot fail.
//
// Pos() returns the ast.CallExpr.Lparen if the instruction arose from
// an explicit T(e) conversion; the ast.TypeAssertExpr.Lparen if the
// instruction arose from an explicit e.(T) operation; or token.NoPos
// otherwise.
//
// Example printed form:
// t2 = ChangeInterface <I1> t1
//
type ChangeInterface struct {
register
X Value
}
// MakeInterface constructs an instance of an interface type from a
// value of a concrete type.
//
// Use Program.MethodSets.MethodSet(X.Type()) to find the method-set
// of X, and Program.MethodValue(m) to find the implementation of a method.
//
// To construct the zero value of an interface type T, use:
// NewConst(constant.MakeNil(), T, pos)
//
// Pos() returns the ast.CallExpr.Lparen, if the instruction arose
// from an explicit conversion in the source.
//
// Example printed form:
// t2 = MakeInterface <interface{}> t1
//
type MakeInterface struct {
register
X Value
}
// The MakeClosure instruction yields a closure value whose code is
// Fn and whose free variables' values are supplied by Bindings.
//
// Type() returns a (possibly named) *types.Signature.
//
// Pos() returns the ast.FuncLit.Type.Func for a function literal
// closure or the ast.SelectorExpr.Sel for a bound method closure.
//
// Example printed form:
// t1 = MakeClosure <func()> foo$1 t1 t2
// t5 = MakeClosure <func(int)> (T).foo$bound t4
//
type MakeClosure struct {
register
Fn Value // always a *Function
Bindings []Value // values for each free variable in Fn.FreeVars
}
// The MakeMap instruction creates a new hash-table-based map object
// and yields a value of kind map.
//
// Type() returns a (possibly named) *types.Map.
//
// Pos() returns the ast.CallExpr.Lparen, if created by make(map), or
// the ast.CompositeLit.Lbrack if created by a literal.
//
// Example printed form:
// t1 = MakeMap <map[string]int>
// t2 = MakeMap <StringIntMap> t1
//
type MakeMap struct {
register
Reserve Value // initial space reservation; nil => default
}
// The MakeChan instruction creates a new channel object and yields a
// value of kind chan.
//
// Type() returns a (possibly named) *types.Chan.
//
// Pos() returns the ast.CallExpr.Lparen for the make(chan) that
// created it.
//
// Example printed form:
// t3 = MakeChan <chan int> t1
// t4 = MakeChan <chan IntChan> t2
//
type MakeChan struct {
register
Size Value // int; size of buffer; zero => synchronous.
}
// The MakeSlice instruction yields a slice of length Len backed by a
// newly allocated array of length Cap.
//
// Both Len and Cap must be non-nil Values of integer type.
//
// (Alloc(types.Array) followed by Slice will not suffice because
// Alloc can only create arrays of constant length.)
//
// Type() returns a (possibly named) *types.Slice.
//
// Pos() returns the ast.CallExpr.Lparen for the make([]T) that
// created it.
//
// Example printed form:
// t3 = MakeSlice <[]string> t1 t2
// t4 = MakeSlice <StringSlice> t1 t2
//
type MakeSlice struct {
register
Len Value
Cap Value
}
// The Slice instruction yields a slice of an existing string, slice
// or *array X between optional integer bounds Low and High.
//
// Dynamically, this instruction panics if X evaluates to a nil *array
// pointer.
//
// Type() returns string if the type of X was string, otherwise a
// *types.Slice with the same element type as X.
//
// Pos() returns the ast.SliceExpr.Lbrack if created by a x[:] slice
// operation, the ast.CompositeLit.Lbrace if created by a literal, or
// NoPos if not explicit in the source (e.g. a variadic argument slice).
//
// Example printed form:
// t4 = Slice <[]int> t3 t2 t1 <nil>
//
type Slice struct {
register
X Value // slice, string, or *array
Low, High, Max Value // each may be nil
}
// The FieldAddr instruction yields the address of Field of *struct X.
//
// The field is identified by its index within the field list of the
// struct type of X.
//
// Dynamically, this instruction panics if X evaluates to a nil
// pointer.
//
// Type() returns a (possibly named) *types.Pointer.
//
// Pos() returns the position of the ast.SelectorExpr.Sel for the
// field, if explicit in the source.
//
// Example printed form:
// t2 = FieldAddr <*int> [0] (X) t1
//
type FieldAddr struct {
register
X Value // *struct
Field int // field is X.Type().Underlying().(*types.Pointer).Elem().Underlying().(*types.Struct).Field(Field)
}
// The Field instruction yields the Field of struct X.
//
// The field is identified by its index within the field list of the
// struct type of X; by using numeric indices we avoid ambiguity of
// package-local identifiers and permit compact representations.
//
// Pos() returns the position of the ast.SelectorExpr.Sel for the
// field, if explicit in the source.
//
// Example printed form:
// t2 = FieldAddr <int> [0] (X) t1
//
type Field struct {
register
X Value // struct
Field int // index into X.Type().(*types.Struct).Fields
}
// The IndexAddr instruction yields the address of the element at
// index Index of collection X. Index is an integer expression.
//
// The elements of maps and strings are not addressable; use StringLookup, MapLookup or
// MapUpdate instead.
//
// Dynamically, this instruction panics if X evaluates to a nil *array
// pointer.
//
// Type() returns a (possibly named) *types.Pointer.
//
// Pos() returns the ast.IndexExpr.Lbrack for the index operation, if
// explicit in the source.
//
// Example printed form:
// t3 = IndexAddr <*int> t2 t1
//
type IndexAddr struct {
register
X Value // slice or *array,
Index Value // numeric index
}
// The Index instruction yields element Index of array X.
//
// Pos() returns the ast.IndexExpr.Lbrack for the index operation, if
// explicit in the source.
//
// Example printed form:
// t3 = Index <int> t2 t1
//
type Index struct {
register
X Value // array
Index Value // integer index
}
// The MapLookup instruction yields element Index of collection X, a map.
//
// If CommaOk, the result is a 2-tuple of the value above and a
// boolean indicating the result of a map membership test for the key.
// The components of the tuple are accessed using Extract.
//
// Pos() returns the ast.IndexExpr.Lbrack, if explicit in the source.
//
// Example printed form:
// t4 = MapLookup <string> t3 t1
// t6 = MapLookup <(string, bool)> t3 t2
//
type MapLookup struct {
register
X Value // map
Index Value // key-typed index
CommaOk bool // return a value,ok pair
}
// The StringLookup instruction yields element Index of collection X, a string.
// Index is an integer expression.
//
// Pos() returns the ast.IndexExpr.Lbrack, if explicit in the source.
//
// Example printed form:
// t3 = StringLookup <uint8> t2 t1
//
type StringLookup struct {
register
X Value // string
Index Value // numeric index
}
// SelectState is a helper for Select.
// It represents one goal state and its corresponding communication.
//
type SelectState struct {
Dir types.ChanDir // direction of case (SendOnly or RecvOnly)
Chan Value // channel to use (for send or receive)
Send Value // value to send (for send)
Pos token.Pos // position of token.ARROW
DebugNode ast.Node // ast.SendStmt or ast.UnaryExpr(<-) [debug mode]
}
// The Select instruction tests whether (or blocks until) one
// of the specified sent or received states is entered.
//
// Let n be the number of States for which Dir==RECV and Tᵢ (0 ≤ i < n)
// be the element type of each such state's Chan.
// Select returns an n+2-tuple
// (index int, recvOk bool, r₀ T₀, ... rₙ-1 Tₙ-1)
// The tuple's components, described below, must be accessed via the
// Extract instruction.
//
// If Blocking, select waits until exactly one state holds, i.e. a
// channel becomes ready for the designated operation of sending or
// receiving; select chooses one among the ready states
// pseudorandomly, performs the send or receive operation, and sets
// 'index' to the index of the chosen channel.
//
// If !Blocking, select doesn't block if no states hold; instead it
// returns immediately with index equal to -1.
//
// If the chosen channel was used for a receive, the rᵢ component is
// set to the received value, where i is the index of that state among
// all n receive states; otherwise rᵢ has the zero value of type Tᵢ.
// Note that the receive index i is not the same as the state
// index index.
//
// The second component of the triple, recvOk, is a boolean whose value
// is true iff the selected operation was a receive and the receive
// successfully yielded a value.
//
// Pos() returns the ast.SelectStmt.Select.
//
// Example printed form:
// t6 = SelectNonBlocking <(index int, ok bool, int)> [<-t4, t5<-t1]
// t11 = SelectBlocking <(index int, ok bool)> []
//
type Select struct {
register
States []*SelectState
Blocking bool
}
// The Range instruction yields an iterator over the domain and range
// of X, which must be a string or map.
//
// Elements are accessed via Next.
//
// Type() returns an opaque and degenerate "rangeIter" type.
//
// Pos() returns the ast.RangeStmt.For.
//
// Example printed form:
// t2 = Range <iter> t1
//
type Range struct {
register
X Value // string or map
}
// The Next instruction reads and advances the (map or string)
// iterator Iter and returns a 3-tuple value (ok, k, v). If the
// iterator is not exhausted, ok is true and k and v are the next
// elements of the domain and range, respectively. Otherwise ok is
// false and k and v are undefined.
//
// Components of the tuple are accessed using Extract.
//
// The IsString field distinguishes iterators over strings from those
// over maps, as the Type() alone is insufficient: consider
// map[int]rune.
//
// Type() returns a *types.Tuple for the triple (ok, k, v).
// The types of k and/or v may be types.Invalid.
//
// Example printed form:
// t5 = Next <(ok bool, k int, v rune)> t2
// t5 = Next <(ok bool, k invalid type, v invalid type)> t2
//
type Next struct {
register
Iter Value
IsString bool // true => string iterator; false => map iterator.
}
// The TypeAssert instruction tests whether interface value X has type
// AssertedType.
//
// If !CommaOk, on success it returns v, the result of the conversion
// (defined below); on failure it panics.
//
// If CommaOk: on success it returns a pair (v, true) where v is the
// result of the conversion; on failure it returns (z, false) where z
// is AssertedType's zero value. The components of the pair must be
// accessed using the Extract instruction.
//
// If AssertedType is a concrete type, TypeAssert checks whether the
// dynamic type in interface X is equal to it, and if so, the result
// of the conversion is a copy of the value in the interface.
//
// If AssertedType is an interface, TypeAssert checks whether the
// dynamic type of the interface is assignable to it, and if so, the
// result of the conversion is a copy of the interface value X.
// If AssertedType is a superinterface of X.Type(), the operation will
// fail iff the operand is nil. (Contrast with ChangeInterface, which
// performs no nil-check.)
//
// Type() reflects the actual type of the result, possibly a
// 2-types.Tuple; AssertedType is the asserted type.
//
// Pos() returns the ast.CallExpr.Lparen if the instruction arose from
// an explicit T(e) conversion; the ast.TypeAssertExpr.Lparen if the
// instruction arose from an explicit e.(T) operation; or the
// ast.CaseClause.Case if the instruction arose from a case of a
// type-switch statement.
//
// Example printed form:
// t2 = TypeAssert <int> t1
// t4 = TypeAssert <(value fmt.Stringer, ok bool)> t1
//
type TypeAssert struct {
register
X Value
AssertedType types.Type
CommaOk bool
}
// The Extract instruction yields component Index of Tuple.
//
// This is used to access the results of instructions with multiple
// return values, such as Call, TypeAssert, Next, Recv,
// MapLookup and others.
//
// Example printed form:
// t7 = Extract <bool> [1] (ok) t4
//
type Extract struct {
register
Tuple Value
Index int
}
// Instructions executed for effect. They do not yield a value. --------------------
// The Jump instruction transfers control to the sole successor of its
// owning block.
//
// A Jump must be the last instruction of its containing BasicBlock.
//
// Pos() returns NoPos.
//
// Example printed form:
// Jump → b1
//
type Jump struct {
anInstruction
Comment string
}
// The Unreachable pseudo-instruction signals that execution cannot
// continue after the preceding function call because it terminates
// the process.
//
// The instruction acts as a control instruction, jumping to the exit
// block. However, this jump will never execute.
//
// An Unreachable instruction must be the last instruction of its
// containing BasicBlock.
//
// Example printed form:
// Unreachable → b1
//
type Unreachable struct {
anInstruction
}
// The If instruction transfers control to one of the two successors
// of its owning block, depending on the boolean Cond: the first if
// true, the second if false.
//
// An If instruction must be the last instruction of its containing
// BasicBlock.
//
// Pos() returns the *ast.IfStmt, if explicit in the source.
//
// Example printed form:
// If t2 → b1 b2
//
type If struct {
anInstruction
Cond Value
}
type ConstantSwitch struct {
anInstruction
Tag Value
// Constant branch conditions. A nil Value denotes the (implicit
// or explicit) default branch.
Conds []Value
}
type TypeSwitch struct {
register
Tag Value
Conds []types.Type
}
// The Return instruction returns values and control back to the calling
// function.
//
// len(Results) is always equal to the number of results in the
// function's signature.
//
// If len(Results) > 1, Return returns a tuple value with the specified
// components which the caller must access using Extract instructions.
//
// There is no instruction to return a ready-made tuple like those
// returned by a "value,ok"-mode TypeAssert, MapLookup or Recv or
// a tail-call to a function with multiple result parameters.
//
// Return must be the last instruction of its containing BasicBlock.
// Such a block has no successors.
//
// Pos() returns the ast.ReturnStmt.Return, if explicit in the source.
//
// Example printed form:
// Return
// Return t1 t2
//
type Return struct {
anInstruction
Results []Value
}
// The RunDefers instruction pops and invokes the entire stack of
// procedure calls pushed by Defer instructions in this function.
//
// It is legal to encounter multiple 'rundefers' instructions in a
// single control-flow path through a function; this is useful in
// the combined init() function, for example.
//
// Pos() returns NoPos.
//
// Example printed form:
// RunDefers
//
type RunDefers struct {
anInstruction
}
// The Panic instruction initiates a panic with value X.
//
// A Panic instruction must be the last instruction of its containing
// BasicBlock, which must have one successor, the exit block.
//
// NB: 'go panic(x)' and 'defer panic(x)' do not use this instruction;
// they are treated as calls to a built-in function.
//
// Pos() returns the ast.CallExpr.Lparen if this panic was explicit
// in the source.
//
// Example printed form:
// Panic t1
//
type Panic struct {
anInstruction
X Value // an interface{}
}
// The Go instruction creates a new goroutine and calls the specified
// function within it.
//
// See CallCommon for generic function call documentation.
//
// Pos() returns the ast.GoStmt.Go.
//
// Example printed form:
// Go println t1
// Go t3
// GoInvoke t4.Bar t2
//
type Go struct {
anInstruction
Call CallCommon
}
// The Defer instruction pushes the specified call onto a stack of
// functions to be called by a RunDefers instruction or by a panic.
//
// See CallCommon for generic function call documentation.
//
// Pos() returns the ast.DeferStmt.Defer.
//
// Example printed form:
// Defer println t1
// Defer t3
// DeferInvoke t4.Bar t2
//
type Defer struct {
anInstruction
Call CallCommon
}
// The Send instruction sends X on channel Chan.
//
// Pos() returns the ast.SendStmt.Arrow, if explicit in the source.
//
// Example printed form:
// Send t2 t1
//
type Send struct {
anInstruction
Chan, X Value
}
// The Recv instruction receives from channel Chan.
//
// If CommaOk, the result is a 2-tuple of the value above
// and a boolean indicating the success of the receive. The
// components of the tuple are accessed using Extract.
//
// Pos() returns the ast.UnaryExpr.OpPos, if explicit in the source.
// For receive operations implicit in ranging over a channel,
// Pos() returns the ast.RangeStmt.For.
//
// Example printed form:
// t2 = Recv <int> t1
// t3 = Recv <(int, bool)> t1
type Recv struct {
register
Chan Value
CommaOk bool
}
// The Store instruction stores Val at address Addr.
// Stores can be of arbitrary types.
//
// Pos() returns the position of the source-level construct most closely
// associated with the memory store operation.
// Since implicit memory stores are numerous and varied and depend upon
// implementation choices, the details are not specified.
//
// Example printed form:
// Store {int} t2 t1
//
type Store struct {
anInstruction
Addr Value
Val Value
}
// The BlankStore instruction is emitted for assignments to the blank
// identifier.
//
// BlankStore is a pseudo-instruction: it has no dynamic effect.
//
// Pos() returns NoPos.
//
// Example printed form:
// BlankStore t1
//
type BlankStore struct {
anInstruction
Val Value
}
// The MapUpdate instruction updates the association of Map[Key] to
// Value.
//
// Pos() returns the ast.KeyValueExpr.Colon or ast.IndexExpr.Lbrack,
// if explicit in the source.
//
// Example printed form:
// MapUpdate t3 t1 t2
//
type MapUpdate struct {
anInstruction
Map Value
Key Value
Value Value
}
// A DebugRef instruction maps a source-level expression Expr to the
// IR value X that represents the value (!IsAddr) or address (IsAddr)
// of that expression.
//
// DebugRef is a pseudo-instruction: it has no dynamic effect.
//
// Pos() returns Expr.Pos(), the start position of the source-level
// expression. This is not the same as the "designated" token as
// documented at Value.Pos(). e.g. CallExpr.Pos() does not return the
// position of the ("designated") Lparen token.
//
// DebugRefs are generated only for functions built with debugging
// enabled; see Package.SetDebugMode() and the GlobalDebug builder
// mode flag.
//
// DebugRefs are not emitted for ast.Idents referring to constants or
// predeclared identifiers, since they are trivial and numerous.
// Nor are they emitted for ast.ParenExprs.
//
// (By representing these as instructions, rather than out-of-band,
// consistency is maintained during transformation passes by the
// ordinary SSA renaming machinery.)
//
// Example printed form:
// ; *ast.CallExpr @ 102:9 is t5
// ; var x float64 @ 109:72 is x
// ; address of *ast.CompositeLit @ 216:10 is t0
//
type DebugRef struct {
anInstruction
Expr ast.Expr // the referring expression (never *ast.ParenExpr)
object types.Object // the identity of the source var/func
IsAddr bool // Expr is addressable and X is the address it denotes
X Value // the value or address of Expr
}
// Embeddable mix-ins and helpers for common parts of other structs. -----------
// register is a mix-in embedded by all IR values that are also
// instructions, i.e. virtual registers, and provides a uniform
// implementation of most of the Value interface: Value.Name() is a
// numbered register (e.g. "t0"); the other methods are field accessors.
//
// Temporary names are automatically assigned to each register on
// completion of building a function in IR form.
//
type register struct {
anInstruction
typ types.Type // type of virtual register
referrers []Instruction
}
type node struct {
source ast.Node
id ID
}
func (n *node) setID(id ID) { n.id = id }
func (n node) ID() ID { return n.id }
func (n *node) setSource(source ast.Node) { n.source = source }
func (n *node) Source() ast.Node { return n.source }
func (n *node) Pos() token.Pos {
if n.source != nil {
return n.source.Pos()
}
return token.NoPos
}
// anInstruction is a mix-in embedded by all Instructions.
// It provides the implementations of the Block and setBlock methods.
type anInstruction struct {
node
block *BasicBlock // the basic block of this instruction
}
// CallCommon is contained by Go, Defer and Call to hold the
// common parts of a function or method call.
//
// Each CallCommon exists in one of two modes, function call and
// interface method invocation, or "call" and "invoke" for short.
//
// 1. "call" mode: when Method is nil (!IsInvoke), a CallCommon
// represents an ordinary function call of the value in Value,
// which may be a *Builtin, a *Function or any other value of kind
// 'func'.
//
// Value may be one of:
// (a) a *Function, indicating a statically dispatched call
// to a package-level function, an anonymous function, or
// a method of a named type.
// (b) a *MakeClosure, indicating an immediately applied
// function literal with free variables.
// (c) a *Builtin, indicating a statically dispatched call
// to a built-in function.
// (d) any other value, indicating a dynamically dispatched
// function call.
// StaticCallee returns the identity of the callee in cases
// (a) and (b), nil otherwise.
//
// Args contains the arguments to the call. If Value is a method,
// Args[0] contains the receiver parameter.
//
// Example printed form:
// t3 = Call <()> println t1 t2
// Go t3
// Defer t3
//
// 2. "invoke" mode: when Method is non-nil (IsInvoke), a CallCommon
// represents a dynamically dispatched call to an interface method.
// In this mode, Value is the interface value and Method is the
// interface's abstract method. Note: an abstract method may be
// shared by multiple interfaces due to embedding; Value.Type()
// provides the specific interface used for this call.
//
// Value is implicitly supplied to the concrete method implementation
// as the receiver parameter; in other words, Args[0] holds not the
// receiver but the first true argument.
//
// Example printed form:
// t6 = Invoke <string> t5.String
// GoInvoke t4.Bar t2
// DeferInvoke t4.Bar t2
//
// For all calls to variadic functions (Signature().Variadic()),
// the last element of Args is a slice.
//
type CallCommon struct {
Value Value // receiver (invoke mode) or func value (call mode)
Method *types.Func // abstract method (invoke mode)
Args []Value // actual parameters (in static method call, includes receiver)
Results Value
}
// IsInvoke returns true if this call has "invoke" (not "call") mode.
func (c *CallCommon) IsInvoke() bool {
return c.Method != nil
}
// Signature returns the signature of the called function.
//
// For an "invoke"-mode call, the signature of the interface method is
// returned.
//
// In either "call" or "invoke" mode, if the callee is a method, its
// receiver is represented by sig.Recv, not sig.Params().At(0).
//
func (c *CallCommon) Signature() *types.Signature {
if c.Method != nil {
return c.Method.Type().(*types.Signature)
}
return c.Value.Type().Underlying().(*types.Signature)
}
// StaticCallee returns the callee if this is a trivially static
// "call"-mode call to a function.
func (c *CallCommon) StaticCallee() *Function {
switch fn := c.Value.(type) {
case *Function:
return fn
case *MakeClosure:
return fn.Fn.(*Function)
}
return nil
}
// Description returns a description of the mode of this call suitable
// for a user interface, e.g., "static method call".
func (c *CallCommon) Description() string {
switch fn := c.Value.(type) {
case *Builtin:
return "built-in function call"
case *MakeClosure:
return "static function closure call"
case *Function:
if fn.Signature.Recv() != nil {
return "static method call"
}
return "static function call"
}
if c.IsInvoke() {
return "dynamic method call" // ("invoke" mode)
}
return "dynamic function call"
}
// The CallInstruction interface, implemented by *Go, *Defer and *Call,
// exposes the common parts of function-calling instructions,
// yet provides a way back to the Value defined by *Call alone.
//
type CallInstruction interface {
Instruction
Common() *CallCommon // returns the common parts of the call
Value() *Call
}
func (s *Call) Common() *CallCommon { return &s.Call }
func (s *Defer) Common() *CallCommon { return &s.Call }
func (s *Go) Common() *CallCommon { return &s.Call }
func (s *Call) Value() *Call { return s }
func (s *Defer) Value() *Call { return nil }
func (s *Go) Value() *Call { return nil }
func (v *Builtin) Type() types.Type { return v.sig }
func (v *Builtin) Name() string { return v.name }
func (*Builtin) Referrers() *[]Instruction { return nil }
func (v *Builtin) Pos() token.Pos { return token.NoPos }
func (v *Builtin) Object() types.Object { return types.Universe.Lookup(v.name) }
func (v *Builtin) Parent() *Function { return nil }
func (v *FreeVar) Type() types.Type { return v.typ }
func (v *FreeVar) Name() string { return v.name }
func (v *FreeVar) Referrers() *[]Instruction { return &v.referrers }
func (v *FreeVar) Parent() *Function { return v.parent }
func (v *Global) Type() types.Type { return v.typ }
func (v *Global) Name() string { return v.name }
func (v *Global) Parent() *Function { return nil }
func (v *Global) Referrers() *[]Instruction { return nil }
func (v *Global) Token() token.Token { return token.VAR }
func (v *Global) Object() types.Object { return v.object }
func (v *Global) String() string { return v.RelString(nil) }
func (v *Global) Package() *Package { return v.Pkg }
func (v *Global) RelString(from *types.Package) string { return relString(v, from) }
func (v *Function) Name() string { return v.name }
func (v *Function) Type() types.Type { return v.Signature }
func (v *Function) Token() token.Token { return token.FUNC }
func (v *Function) Object() types.Object { return v.object }
func (v *Function) String() string { return v.RelString(nil) }
func (v *Function) Package() *Package { return v.Pkg }
func (v *Function) Parent() *Function { return v.parent }
func (v *Function) Referrers() *[]Instruction {
if v.parent != nil {
return &v.referrers
}
return nil
}
func (v *Parameter) Object() types.Object { return v.object }
func (v *Alloc) Type() types.Type { return v.typ }
func (v *Alloc) Referrers() *[]Instruction { return &v.referrers }
func (v *register) Type() types.Type { return v.typ }
func (v *register) setType(typ types.Type) { v.typ = typ }
func (v *register) Name() string { return fmt.Sprintf("t%d", v.id) }
func (v *register) Referrers() *[]Instruction { return &v.referrers }
func (v *anInstruction) Parent() *Function { return v.block.parent }
func (v *anInstruction) Block() *BasicBlock { return v.block }
func (v *anInstruction) setBlock(block *BasicBlock) { v.block = block }
func (v *anInstruction) Referrers() *[]Instruction { return nil }
func (t *Type) Name() string { return t.object.Name() }
func (t *Type) Pos() token.Pos { return t.object.Pos() }
func (t *Type) Type() types.Type { return t.object.Type() }
func (t *Type) Token() token.Token { return token.TYPE }
func (t *Type) Object() types.Object { return t.object }
func (t *Type) String() string { return t.RelString(nil) }
func (t *Type) Package() *Package { return t.pkg }
func (t *Type) RelString(from *types.Package) string { return relString(t, from) }
func (c *NamedConst) Name() string { return c.object.Name() }
func (c *NamedConst) Pos() token.Pos { return c.object.Pos() }
func (c *NamedConst) String() string { return c.RelString(nil) }
func (c *NamedConst) Type() types.Type { return c.object.Type() }
func (c *NamedConst) Token() token.Token { return token.CONST }
func (c *NamedConst) Object() types.Object { return c.object }
func (c *NamedConst) Package() *Package { return c.pkg }
func (c *NamedConst) RelString(from *types.Package) string { return relString(c, from) }
// Func returns the package-level function of the specified name,
// or nil if not found.
//
func (p *Package) Func(name string) (f *Function) {
f, _ = p.Members[name].(*Function)
return
}
// Var returns the package-level variable of the specified name,
// or nil if not found.
//
func (p *Package) Var(name string) (g *Global) {
g, _ = p.Members[name].(*Global)
return
}
// Const returns the package-level constant of the specified name,
// or nil if not found.
//
func (p *Package) Const(name string) (c *NamedConst) {
c, _ = p.Members[name].(*NamedConst)
return
}
// Type returns the package-level type of the specified name,
// or nil if not found.
//
func (p *Package) Type(name string) (t *Type) {
t, _ = p.Members[name].(*Type)
return
}
func (s *DebugRef) Pos() token.Pos { return s.Expr.Pos() }
// Operands.
func (v *Alloc) Operands(rands []*Value) []*Value {
return rands
}
func (v *BinOp) Operands(rands []*Value) []*Value {
return append(rands, &v.X, &v.Y)
}
func (c *CallCommon) Operands(rands []*Value) []*Value {
rands = append(rands, &c.Value)
for i := range c.Args {
rands = append(rands, &c.Args[i])
}
return rands
}
func (s *Go) Operands(rands []*Value) []*Value {
return s.Call.Operands(rands)
}
func (s *Call) Operands(rands []*Value) []*Value {
return s.Call.Operands(rands)
}
func (s *Defer) Operands(rands []*Value) []*Value {
return s.Call.Operands(rands)
}
func (v *ChangeInterface) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (v *ChangeType) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (v *Convert) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (s *DebugRef) Operands(rands []*Value) []*Value {
return append(rands, &s.X)
}
func (v *Extract) Operands(rands []*Value) []*Value {
return append(rands, &v.Tuple)
}
func (v *Field) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (v *FieldAddr) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (s *If) Operands(rands []*Value) []*Value {
return append(rands, &s.Cond)
}
func (s *ConstantSwitch) Operands(rands []*Value) []*Value {
rands = append(rands, &s.Tag)
for i := range s.Conds {
rands = append(rands, &s.Conds[i])
}
return rands
}
func (s *TypeSwitch) Operands(rands []*Value) []*Value {
rands = append(rands, &s.Tag)
return rands
}
func (v *Index) Operands(rands []*Value) []*Value {
return append(rands, &v.X, &v.Index)
}
func (v *IndexAddr) Operands(rands []*Value) []*Value {
return append(rands, &v.X, &v.Index)
}
func (*Jump) Operands(rands []*Value) []*Value {
return rands
}
func (*Unreachable) Operands(rands []*Value) []*Value {
return rands
}
func (v *MapLookup) Operands(rands []*Value) []*Value {
return append(rands, &v.X, &v.Index)
}
func (v *StringLookup) Operands(rands []*Value) []*Value {
return append(rands, &v.X, &v.Index)
}
func (v *MakeChan) Operands(rands []*Value) []*Value {
return append(rands, &v.Size)
}
func (v *MakeClosure) Operands(rands []*Value) []*Value {
rands = append(rands, &v.Fn)
for i := range v.Bindings {
rands = append(rands, &v.Bindings[i])
}
return rands
}
func (v *MakeInterface) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (v *MakeMap) Operands(rands []*Value) []*Value {
return append(rands, &v.Reserve)
}
func (v *MakeSlice) Operands(rands []*Value) []*Value {
return append(rands, &v.Len, &v.Cap)
}
func (v *MapUpdate) Operands(rands []*Value) []*Value {
return append(rands, &v.Map, &v.Key, &v.Value)
}
func (v *Next) Operands(rands []*Value) []*Value {
return append(rands, &v.Iter)
}
func (s *Panic) Operands(rands []*Value) []*Value {
return append(rands, &s.X)
}
func (v *Sigma) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (v *Phi) Operands(rands []*Value) []*Value {
for i := range v.Edges {
rands = append(rands, &v.Edges[i])
}
return rands
}
func (v *Range) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (s *Return) Operands(rands []*Value) []*Value {
for i := range s.Results {
rands = append(rands, &s.Results[i])
}
return rands
}
func (*RunDefers) Operands(rands []*Value) []*Value {
return rands
}
func (v *Select) Operands(rands []*Value) []*Value {
for i := range v.States {
rands = append(rands, &v.States[i].Chan, &v.States[i].Send)
}
return rands
}
func (s *Send) Operands(rands []*Value) []*Value {
return append(rands, &s.Chan, &s.X)
}
func (recv *Recv) Operands(rands []*Value) []*Value {
return append(rands, &recv.Chan)
}
func (v *Slice) Operands(rands []*Value) []*Value {
return append(rands, &v.X, &v.Low, &v.High, &v.Max)
}
func (s *Store) Operands(rands []*Value) []*Value {
return append(rands, &s.Addr, &s.Val)
}
func (s *BlankStore) Operands(rands []*Value) []*Value {
return append(rands, &s.Val)
}
func (v *TypeAssert) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (v *UnOp) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
func (v *Load) Operands(rands []*Value) []*Value {
return append(rands, &v.X)
}
// Non-Instruction Values:
func (v *Builtin) Operands(rands []*Value) []*Value { return rands }
func (v *FreeVar) Operands(rands []*Value) []*Value { return rands }
func (v *Const) Operands(rands []*Value) []*Value { return rands }
func (v *Function) Operands(rands []*Value) []*Value { return rands }
func (v *Global) Operands(rands []*Value) []*Value { return rands }
func (v *Parameter) Operands(rands []*Value) []*Value { return rands }