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// Package api includes constants and interfaces used by both end-users and internal implementations.
package api
import (
"context"
"fmt"
"math"
"github.com/tetratelabs/wazero/internal/internalapi"
)
// ExternType classifies imports and exports with their respective types.
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#external-types%E2%91%A0
type ExternType = byte
const (
ExternTypeFunc ExternType = 0x00
ExternTypeTable ExternType = 0x01
ExternTypeMemory ExternType = 0x02
ExternTypeGlobal ExternType = 0x03
)
// The below are exported to consolidate parsing behavior for external types.
const (
// ExternTypeFuncName is the name of the WebAssembly 1.0 (20191205) Text Format field for ExternTypeFunc.
ExternTypeFuncName = "func"
// ExternTypeTableName is the name of the WebAssembly 1.0 (20191205) Text Format field for ExternTypeTable.
ExternTypeTableName = "table"
// ExternTypeMemoryName is the name of the WebAssembly 1.0 (20191205) Text Format field for ExternTypeMemory.
ExternTypeMemoryName = "memory"
// ExternTypeGlobalName is the name of the WebAssembly 1.0 (20191205) Text Format field for ExternTypeGlobal.
ExternTypeGlobalName = "global"
)
// ExternTypeName returns the name of the WebAssembly 1.0 (20191205) Text Format field of the given type.
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#exports%E2%91%A4
func ExternTypeName(et ExternType) string {
switch et {
case ExternTypeFunc:
return ExternTypeFuncName
case ExternTypeTable:
return ExternTypeTableName
case ExternTypeMemory:
return ExternTypeMemoryName
case ExternTypeGlobal:
return ExternTypeGlobalName
}
return fmt.Sprintf("%#x", et)
}
// ValueType describes a parameter or result type mapped to a WebAssembly
// function signature.
//
// The following describes how to convert between Wasm and Golang types:
//
// - ValueTypeI32 - EncodeU32 DecodeU32 for uint32 / EncodeI32 DecodeI32 for int32
// - ValueTypeI64 - uint64(int64)
// - ValueTypeF32 - EncodeF32 DecodeF32 from float32
// - ValueTypeF64 - EncodeF64 DecodeF64 from float64
// - ValueTypeExternref - unintptr(unsafe.Pointer(p)) where p is any pointer
// type in Go (e.g. *string)
//
// e.g. Given a Text Format type use (param i64) (result i64), no conversion is
// necessary.
//
// results, _ := fn(ctx, input)
// result := result[0]
//
// e.g. Given a Text Format type use (param f64) (result f64), conversion is
// necessary.
//
// results, _ := fn(ctx, api.EncodeF64(input))
// result := api.DecodeF64(result[0])
//
// Note: This is a type alias as it is easier to encode and decode in the
// binary format.
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#binary-valtype
type ValueType = byte
const (
// ValueTypeI32 is a 32-bit integer.
ValueTypeI32 ValueType = 0x7f
// ValueTypeI64 is a 64-bit integer.
ValueTypeI64 ValueType = 0x7e
// ValueTypeF32 is a 32-bit floating point number.
ValueTypeF32 ValueType = 0x7d
// ValueTypeF64 is a 64-bit floating point number.
ValueTypeF64 ValueType = 0x7c
// ValueTypeExternref is a externref type.
//
// Note: in wazero, externref type value are opaque raw 64-bit pointers,
// and the ValueTypeExternref type in the signature will be translated as
// uintptr in wazero's API level.
//
// For example, given the import function:
// (func (import "env" "f") (param externref) (result externref))
//
// This can be defined in Go as:
// r.NewHostModuleBuilder("env").
// NewFunctionBuilder().
// WithFunc(func(context.Context, _ uintptr) (_ uintptr) { return }).
// Export("f")
//
// Note: The usage of this type is toggled with api.CoreFeatureBulkMemoryOperations.
ValueTypeExternref ValueType = 0x6f
)
// ValueTypeName returns the type name of the given ValueType as a string.
// These type names match the names used in the WebAssembly text format.
//
// Note: This returns "unknown", if an undefined ValueType value is passed.
func ValueTypeName(t ValueType) string {
switch t {
case ValueTypeI32:
return "i32"
case ValueTypeI64:
return "i64"
case ValueTypeF32:
return "f32"
case ValueTypeF64:
return "f64"
case ValueTypeExternref:
return "externref"
}
return "unknown"
}
// Module is a sandboxed, ready to execute Wasm module. This can be used to get exported functions, etc.
//
// In WebAssembly terminology, this corresponds to a "Module Instance", but wazero calls pre-instantiation module as
// "Compiled Module" as in wazero.CompiledModule, therefore we call this post-instantiation module simply "Module".
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#module-instances%E2%91%A0
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
// - Closing the wazero.Runtime closes any Module it instantiated.
type Module interface {
fmt.Stringer
// Name is the name this module was instantiated with. Exported functions can be imported with this name.
Name() string
// Memory returns a memory defined in this module or nil if there are none wasn't.
Memory() Memory
// ExportedFunction returns a function exported from this module or nil if it wasn't.
//
// # Notes
// - The default wazero.ModuleConfig attempts to invoke `_start`, which
// in rare cases can close the module. When in doubt, check IsClosed prior
// to invoking a function export after instantiation.
// - The semantics of host functions assumes the existence of an "importing module" because, for example, the host function needs access to
// the memory of the importing module. Therefore, direct use of ExportedFunction is forbidden for host modules.
// Practically speaking, it is usually meaningless to directly call a host function from Go code as it is already somewhere in Go code.
ExportedFunction(name string) Function
// ExportedFunctionDefinitions returns all the exported function
// definitions in this module, keyed on export name.
ExportedFunctionDefinitions() map[string]FunctionDefinition
// TODO: Table
// ExportedMemory returns a memory exported from this module or nil if it wasn't.
//
// WASI modules require exporting a Memory named "memory". This means that a module successfully initialized
// as a WASI Command or Reactor will never return nil for this name.
//
// See https://github.com/WebAssembly/WASI/blob/snapshot-01/design/application-abi.md#current-unstable-abi
ExportedMemory(name string) Memory
// ExportedMemoryDefinitions returns all the exported memory definitions
// in this module, keyed on export name.
//
// Note: As of WebAssembly Core Specification 2.0, there can be at most one
// memory.
ExportedMemoryDefinitions() map[string]MemoryDefinition
// ExportedGlobal a global exported from this module or nil if it wasn't.
ExportedGlobal(name string) Global
// CloseWithExitCode releases resources allocated for this Module. Use a non-zero exitCode parameter to indicate a
// failure to ExportedFunction callers.
//
// The error returned here, if present, is about resource de-allocation (such as I/O errors). Only the last error is
// returned, so a non-nil return means at least one error happened. Regardless of error, this Module will
// be removed, making its name available again.
//
// Calling this inside a host function is safe, and may cause ExportedFunction callers to receive a sys.ExitError
// with the exitCode.
CloseWithExitCode(ctx context.Context, exitCode uint32) error
// Closer closes this module by delegating to CloseWithExitCode with an exit code of zero.
Closer
// IsClosed returns true if the module is closed, so no longer usable.
//
// This can happen for the following reasons:
// - Closer was called directly.
// - A guest function called Closer indirectly, such as `_start` calling
// `proc_exit`, which internally closed the module.
// - wazero.RuntimeConfig `WithCloseOnContextDone` was enabled and a
// context completion closed the module.
//
// Where any of the above are possible, check this value before calling an
// ExportedFunction, even if you didn't formerly receive a sys.ExitError.
// sys.ExitError is only returned on non-zero code, something that closes
// the module successfully will not result it one.
IsClosed() bool
internalapi.WazeroOnly
}
// Closer closes a resource.
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
type Closer interface {
// Close closes the resource.
//
// Note: The context parameter is used for value lookup, such as for
// logging. A canceled or otherwise done context will not prevent Close
// from succeeding.
Close(context.Context) error
}
// ExportDefinition is a WebAssembly type exported in a module
// (wazero.CompiledModule).
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#exports%E2%91%A0
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
type ExportDefinition interface {
// ModuleName is the possibly empty name of the module defining this
// export.
//
// Note: This may be different from Module.Name, because a compiled module
// can be instantiated multiple times as different names.
ModuleName() string
// Index is the position in the module's index, imports first.
Index() uint32
// Import returns true with the module and name when this was imported.
// Otherwise, it returns false.
//
// Note: Empty string is valid for both names in the WebAssembly Core
// Specification, so "" "" is possible.
Import() (moduleName, name string, isImport bool)
// ExportNames include all exported names.
//
// Note: The empty name is allowed in the WebAssembly Core Specification,
// so "" is possible.
ExportNames() []string
internalapi.WazeroOnly
}
// MemoryDefinition is a WebAssembly memory exported in a module
// (wazero.CompiledModule). Units are in pages (64KB).
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#exports%E2%91%A0
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
type MemoryDefinition interface {
ExportDefinition
// Min returns the possibly zero initial count of 64KB pages.
Min() uint32
// Max returns the possibly zero max count of 64KB pages, or false if
// unbounded.
Max() (uint32, bool)
internalapi.WazeroOnly
}
// FunctionDefinition is a WebAssembly function exported in a module
// (wazero.CompiledModule).
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#exports%E2%91%A0
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
type FunctionDefinition interface {
ExportDefinition
// Name is the module-defined name of the function, which is not necessarily
// the same as its export name.
Name() string
// DebugName identifies this function based on its Index or Name in the
// module. This is used for errors and stack traces. e.g. "env.abort".
//
// When the function name is empty, a substitute name is generated by
// prefixing '$' to its position in the index. Ex ".$0" is the
// first function (possibly imported) in an unnamed module.
//
// The format is dot-delimited module and function name, but there are no
// restrictions on the module and function name. This means either can be
// empty or include dots. e.g. "x.x.x" could mean module "x" and name "x.x",
// or it could mean module "x.x" and name "x".
//
// Note: This name is stable regardless of import or export. For example,
// if Import returns true, the value is still based on the Name or Index
// and not the imported function name.
DebugName() string
// GoFunction is non-nil when implemented by the embedder instead of a wasm
// binary, e.g. via wazero.HostModuleBuilder
//
// The expected results are nil, GoFunction or GoModuleFunction.
GoFunction() interface{}
// ParamTypes are the possibly empty sequence of value types accepted by a
// function with this signature.
//
// See ValueType documentation for encoding rules.
ParamTypes() []ValueType
// ParamNames are index-correlated with ParamTypes or nil if not available
// for one or more parameters.
ParamNames() []string
// ResultTypes are the results of the function.
//
// When WebAssembly 1.0 (20191205), there can be at most one result.
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#result-types%E2%91%A0
//
// See ValueType documentation for encoding rules.
ResultTypes() []ValueType
// ResultNames are index-correlated with ResultTypes or nil if not
// available for one or more results.
ResultNames() []string
internalapi.WazeroOnly
}
// Function is a WebAssembly function exported from an instantiated module
// (wazero.Runtime InstantiateModule).
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#syntax-func
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
type Function interface {
// Definition is metadata about this function from its defining module.
Definition() FunctionDefinition
// Call invokes the function with the given parameters and returns any
// results or an error for any failure looking up or invoking the function.
//
// Encoding is described in Definition, and supplying an incorrect count of
// parameters vs FunctionDefinition.ParamTypes is an error.
//
// If the exporting Module was closed during this call, the error returned
// may be a sys.ExitError. See Module.CloseWithExitCode for details.
//
// Call is not goroutine-safe, therefore it is recommended to create
// another Function if you want to invoke the same function concurrently.
// On the other hand, sequential invocations of Call is allowed.
// However, this should not be called multiple times until the previous Call returns.
//
// To safely encode/decode params/results expressed as uint64, users are encouraged to
// use api.EncodeXXX or DecodeXXX functions. See the docs on api.ValueType.
//
// When RuntimeConfig.WithCloseOnContextDone is toggled, the invocation of this Call method is ensured to be closed
// whenever one of the three conditions is met. In the event of close, sys.ExitError will be returned and
// the api.Module from which this api.Function is derived will be made closed. See the documentation of
// WithCloseOnContextDone on wazero.RuntimeConfig for detail. See examples in context_done_example_test.go for
// the end-to-end demonstrations of how these terminations can be performed.
Call(ctx context.Context, params ...uint64) ([]uint64, error)
// CallWithStack is an optimized variation of Call that saves memory
// allocations when the stack slice is reused across calls.
//
// Stack length must be at least the max of parameter or result length.
// The caller adds parameters in order to the stack, and reads any results
// in order from the stack, except in the error case.
//
// For example, the following reuses the same stack slice to call searchFn
// repeatedly saving one allocation per iteration:
//
// stack := make([]uint64, 4)
// for i, search := range searchParams {
// // copy the next params to the stack
// copy(stack, search)
// if err := searchFn.CallWithStack(ctx, stack); err != nil {
// return err
// } else if stack[0] == 1 { // found
// return i // searchParams[i] matched!
// }
// }
//
// # Notes
//
// - This is similar to GoModuleFunction, except for using calling functions
// instead of implementing them. Moreover, this is used regardless of
// whether the callee is a host or wasm defined function.
CallWithStack(ctx context.Context, stack []uint64) error
internalapi.WazeroOnly
}
// GoModuleFunction is a Function implemented in Go instead of a wasm binary.
// The Module parameter is the calling module, used to access memory or
// exported functions. See GoModuleFunc for an example.
//
// The stack is includes any parameters encoded according to their ValueType.
// Its length is the max of parameter or result length. When there are results,
// write them in order beginning at index zero. Do not use the stack after the
// function returns.
//
// Here's a typical way to read three parameters and write back one.
//
// // read parameters off the stack in index order
// argv, argvBuf := api.DecodeU32(stack[0]), api.DecodeU32(stack[1])
//
// // write results back to the stack in index order
// stack[0] = api.EncodeU32(ErrnoSuccess)
//
// This function can be non-deterministic or cause side effects. It also
// has special properties not defined in the WebAssembly Core specification.
// Notably, this uses the caller's memory (via Module.Memory). See
// https://www.w3.org/TR/wasm-core-1/#host-functions%E2%91%A0
//
// Most end users will not define functions directly with this, as they will
// use reflection or code generators instead. These approaches are more
// idiomatic as they can map go types to ValueType. This type is exposed for
// those willing to trade usability and safety for performance.
//
// To safely decode/encode values from/to the uint64 stack, users are encouraged to use
// api.EncodeXXX or api.DecodeXXX functions. See the docs on api.ValueType.
type GoModuleFunction interface {
Call(ctx context.Context, mod Module, stack []uint64)
}
// GoModuleFunc is a convenience for defining an inlined function.
//
// For example, the following returns an uint32 value read from parameter zero:
//
// api.GoModuleFunc(func(ctx context.Context, mod api.Module, stack []uint64) {
// offset := api.DecodeU32(stack[0]) // read the parameter from the stack
//
// ret, ok := mod.Memory().ReadUint32Le(offset)
// if !ok {
// panic("out of memory")
// }
//
// stack[0] = api.EncodeU32(ret) // add the result back to the stack.
// })
type GoModuleFunc func(ctx context.Context, mod Module, stack []uint64)
// Call implements GoModuleFunction.Call.
func (f GoModuleFunc) Call(ctx context.Context, mod Module, stack []uint64) {
f(ctx, mod, stack)
}
// GoFunction is an optimized form of GoModuleFunction which doesn't require
// the Module parameter. See GoFunc for an example.
//
// For example, this function does not need to use the importing module's
// memory or exported functions.
type GoFunction interface {
Call(ctx context.Context, stack []uint64)
}
// GoFunc is a convenience for defining an inlined function.
//
// For example, the following returns the sum of two uint32 parameters:
//
// api.GoFunc(func(ctx context.Context, stack []uint64) {
// x, y := api.DecodeU32(stack[0]), api.DecodeU32(stack[1])
// stack[0] = api.EncodeU32(x + y)
// })
type GoFunc func(ctx context.Context, stack []uint64)
// Call implements GoFunction.Call.
func (f GoFunc) Call(ctx context.Context, stack []uint64) {
f(ctx, stack)
}
// Global is a WebAssembly 1.0 (20191205) global exported from an instantiated module (wazero.Runtime InstantiateModule).
//
// For example, if the value is not mutable, you can read it once:
//
// offset := module.ExportedGlobal("memory.offset").Get()
//
// Globals are allowed by specification to be mutable. However, this can be disabled by configuration. When in doubt,
// safe cast to find out if the value can change. Here's an example:
//
// offset := module.ExportedGlobal("memory.offset")
// if _, ok := offset.(api.MutableGlobal); ok {
// // value can change
// } else {
// // value is constant
// }
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#globals%E2%91%A0
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
type Global interface {
fmt.Stringer
// Type describes the numeric type of the global.
Type() ValueType
// Get returns the last known value of this global.
//
// See Type for how to decode this value to a Go type.
Get() uint64
}
// MutableGlobal is a Global whose value can be updated at runtime (variable).
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
type MutableGlobal interface {
Global
// Set updates the value of this global.
//
// See Global.Type for how to encode this value from a Go type.
Set(v uint64)
internalapi.WazeroOnly
}
// Memory allows restricted access to a module's memory. Notably, this does not allow growing.
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#storage%E2%91%A0
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
// - This includes all value types available in WebAssembly 1.0 (20191205) and all are encoded little-endian.
type Memory interface {
// Definition is metadata about this memory from its defining module.
Definition() MemoryDefinition
// Size returns the memory size in bytes available.
// e.g. If the underlying memory has 1 page: 65536
//
// # Notes
//
// - This overflows (returns zero) if the memory has the maximum 65536 pages.
// As a workaround until wazero v2 to fix the return type, use Grow(0) to obtain the current pages and
// multiply by 65536.
//
// See https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#-hrefsyntax-instr-memorymathsfmemorysize%E2%91%A0
Size() uint32
// Grow increases memory by the delta in pages (65536 bytes per page).
// The return val is the previous memory size in pages, or false if the
// delta was ignored as it exceeds MemoryDefinition.Max.
//
// # Notes
//
// - This is the same as the "memory.grow" instruction defined in the
// WebAssembly Core Specification, except returns false instead of -1.
// - When this returns true, any shared views via Read must be refreshed.
//
// See MemorySizer Read and https://www.w3.org/TR/2019/REC-wasm-core-1-20191205/#grow-mem
Grow(deltaPages uint32) (previousPages uint32, ok bool)
// ReadByte reads a single byte from the underlying buffer at the offset or returns false if out of range.
ReadByte(offset uint32) (byte, bool)
// ReadUint16Le reads a uint16 in little-endian encoding from the underlying buffer at the offset in or returns
// false if out of range.
ReadUint16Le(offset uint32) (uint16, bool)
// ReadUint32Le reads a uint32 in little-endian encoding from the underlying buffer at the offset in or returns
// false if out of range.
ReadUint32Le(offset uint32) (uint32, bool)
// ReadFloat32Le reads a float32 from 32 IEEE 754 little-endian encoded bits in the underlying buffer at the offset
// or returns false if out of range.
// See math.Float32bits
ReadFloat32Le(offset uint32) (float32, bool)
// ReadUint64Le reads a uint64 in little-endian encoding from the underlying buffer at the offset or returns false
// if out of range.
ReadUint64Le(offset uint32) (uint64, bool)
// ReadFloat64Le reads a float64 from 64 IEEE 754 little-endian encoded bits in the underlying buffer at the offset
// or returns false if out of range.
//
// See math.Float64bits
ReadFloat64Le(offset uint32) (float64, bool)
// Read reads byteCount bytes from the underlying buffer at the offset or
// returns false if out of range.
//
// For example, to search for a NUL-terminated string:
// buf, _ = memory.Read(offset, byteCount)
// n := bytes.IndexByte(buf, 0)
// if n < 0 {
// // Not found!
// }
//
// Write-through
//
// This returns a view of the underlying memory, not a copy. This means any
// writes to the slice returned are visible to Wasm, and any updates from
// Wasm are visible reading the returned slice.
//
// For example:
// buf, _ = memory.Read(offset, byteCount)
// buf[1] = 'a' // writes through to memory, meaning Wasm code see 'a'.
//
// If you don't intend-write through, make a copy of the returned slice.
//
// When to refresh Read
//
// The returned slice disconnects on any capacity change. For example,
// `buf = append(buf, 'a')` might result in a slice that is no longer
// shared. The same exists Wasm side. For example, if Wasm changes its
// memory capacity, ex via "memory.grow"), the host slice is no longer
// shared. Those who need a stable view must set Wasm memory min=max, or
// use wazero.RuntimeConfig WithMemoryCapacityPages to ensure max is always
// allocated.
Read(offset, byteCount uint32) ([]byte, bool)
// WriteByte writes a single byte to the underlying buffer at the offset in or returns false if out of range.
WriteByte(offset uint32, v byte) bool
// WriteUint16Le writes the value in little-endian encoding to the underlying buffer at the offset in or returns
// false if out of range.
WriteUint16Le(offset uint32, v uint16) bool
// WriteUint32Le writes the value in little-endian encoding to the underlying buffer at the offset in or returns
// false if out of range.
WriteUint32Le(offset, v uint32) bool
// WriteFloat32Le writes the value in 32 IEEE 754 little-endian encoded bits to the underlying buffer at the offset
// or returns false if out of range.
//
// See math.Float32bits
WriteFloat32Le(offset uint32, v float32) bool
// WriteUint64Le writes the value in little-endian encoding to the underlying buffer at the offset in or returns
// false if out of range.
WriteUint64Le(offset uint32, v uint64) bool
// WriteFloat64Le writes the value in 64 IEEE 754 little-endian encoded bits to the underlying buffer at the offset
// or returns false if out of range.
//
// See math.Float64bits
WriteFloat64Le(offset uint32, v float64) bool
// Write writes the slice to the underlying buffer at the offset or returns false if out of range.
Write(offset uint32, v []byte) bool
// WriteString writes the string to the underlying buffer at the offset or returns false if out of range.
WriteString(offset uint32, v string) bool
internalapi.WazeroOnly
}
// CustomSection contains the name and raw data of a custom section.
//
// # Notes
//
// - This is an interface for decoupling, not third-party implementations.
// All implementations are in wazero.
type CustomSection interface {
// Name is the name of the custom section
Name() string
// Data is the raw data of the custom section
Data() []byte
internalapi.WazeroOnly
}
// EncodeExternref encodes the input as a ValueTypeExternref.
//
// See DecodeExternref
func EncodeExternref(input uintptr) uint64 {
return uint64(input)
}
// DecodeExternref decodes the input as a ValueTypeExternref.
//
// See EncodeExternref
func DecodeExternref(input uint64) uintptr {
return uintptr(input)
}
// EncodeI32 encodes the input as a ValueTypeI32.
func EncodeI32(input int32) uint64 {
return uint64(uint32(input))
}
// DecodeI32 decodes the input as a ValueTypeI32.
func DecodeI32(input uint64) int32 {
return int32(input)
}
// EncodeU32 encodes the input as a ValueTypeI32.
func EncodeU32(input uint32) uint64 {
return uint64(input)
}
// DecodeU32 decodes the input as a ValueTypeI32.
func DecodeU32(input uint64) uint32 {
return uint32(input)
}
// EncodeI64 encodes the input as a ValueTypeI64.
func EncodeI64(input int64) uint64 {
return uint64(input)
}
// EncodeF32 encodes the input as a ValueTypeF32.
//
// See DecodeF32
func EncodeF32(input float32) uint64 {
return uint64(math.Float32bits(input))
}
// DecodeF32 decodes the input as a ValueTypeF32.
//
// See EncodeF32
func DecodeF32(input uint64) float32 {
return math.Float32frombits(uint32(input))
}
// EncodeF64 encodes the input as a ValueTypeF64.
//
// See EncodeF32
func EncodeF64(input float64) uint64 {
return math.Float64bits(input)
}
// DecodeF64 decodes the input as a ValueTypeF64.
//
// See EncodeF64
func DecodeF64(input uint64) float64 {
return math.Float64frombits(input)
}