BinaryEncoding.md

Binary Encoding

Note: This document is no longer being updated. Please see the normative documentation.

This document describes the portable binary encoding of the WebAssembly modules.

The binary encoding is a dense representation of module information that enables small files, fast decoding, and reduced memory usage. See the rationale document for more detail.

🦄 = Planned future feature

The encoding is split into three layers:

• Layer 0 is a simple binary encoding of the bytecode instructions and related data structures. The encoding is dense and trivial to interact with, making it suitable for scenarios like JIT, instrumentation tools, and debugging.
• Layer 1 🦄 provides structural compression on top of layer 0, exploiting specific knowledge about the nature of the syntax tree and its nodes. The structural compression introduces more efficient encoding of values, rearranges values within the module, and prunes structurally identical tree nodes.
• Layer 2 🦄 Layer 2 applies generic compression algorithms, like gzip and Brotli, that are already available in browsers and other tooling.

Most importantly, the layering approach allows development and standardization to occur incrementally. For example, Layer 1 and Layer 2 encoding techniques can be experimented with by application-level decompressing to the layer below. As compression techniques stabilize, they can be standardized and moved into native implementations.

See proposed layer 1 compression 🦄 for a proposal for layer 1 structural compression.

Data types

Numbers

uintN

An unsigned integer of N bits, represented in N/8 bytes in little endian order. N is either 8, 16, or 32.

varuintN

A LEB128 variable-length integer, limited to N bits (i.e., the values [0, 2^N-1]), represented by at most ceil(N/7) bytes that may contain padding 0x80 bytes.

Note: Currently, the only sizes used are varuint1, varuint7, and varuint32, where the former two are used for compatibility with potential future extensions.

varintN

A Signed LEB128 variable-length integer, limited to N bits (i.e., the values [-2^(N-1), +2^(N-1)-1]), represented by at most ceil(N/7) bytes that may contain padding 0x80 or 0xFF bytes.

Note: Currently, the only sizes used are varint7, varint32 and varint64.

Instruction Opcodes

The opcodes for many common instructions are encoded in a single byte.

The opcodes for some families of instructions are encoded as a prefix byte followed by an LEB128 value. Prefix byte values are allocated starting at 0xfe and counting downwards.

Prefix Bytes

Opcode	Name	Description
0xff	reserved	Reserved for unknown future language evolution 🌌
0xfe	threads	Expected to be used for atomics 🦄
0xfd	simd	Expected to be used for SIMD 🦄
0xfc	misc	Miscellaneous operations 🎳

Language Types

All types are distinguished by a negative varint7 values that is the first byte of their encoding (representing a type constructor):

Opcode	Type constructor
-0x01 (i.e., the byte 0x7f)	i32
-0x02 (i.e., the byte 0x7e)	i64
-0x03 (i.e., the byte 0x7d)	f32
-0x04 (i.e., the byte 0x7c)	f64
-0x10 (i.e., the byte 0x70)	anyfunc
-0x20 (i.e., the byte 0x60)	func
-0x40 (i.e., the byte 0x40)	pseudo type for representing an empty block_type

Some of these will be followed by additional fields, see below.

Note: Gaps are reserved for future 🦄 extensions. The use of a signed scheme is so that types can coexist in a single space with (positive) indices into the type section, which may be relevant for future extensions of the type system.

value_type

A varint7 indicating a value type. One of:

• i32
• i64
• f32
• f64

as encoded above.

block_type

A varint7 indicating a block signature. These types are encoded as:

• either a value_type indicating a signature with a single result
• or -0x40 (i.e., the byte 0x40) indicating a signature with 0 results.

elem_type

A varint7 indicating the types of elements in a table. In the MVP, only one type is available:

• anyfunc

Note: In the future 🦄, other element types may be allowed.

func_type

The description of a function signature. Its type constructor is followed by an additional description:

Field	Type	Description
form	varint7	the value for the func type constructor as defined above
param_count	varuint32	the number of parameters to the function
param_types	value_type*	the parameter types of the function
return_count	varuint1	the number of results from the function
return_type	value_type?	the result type of the function (if return_count is 1)

Note: In the future 🦄, return_count and return_type might be generalised to allow multiple values.

Other Types

global_type

The description of a global variable.

Field	Type	Description
content_type	value_type	type of the value
mutability	varuint1	0 if immutable, 1 if mutable

table_type

The description of a table.

Field	Type	Description
element_type	elem_type	the type of elements
limits	resizable_limits	see below

memory_type

The description of a memory.

Field	Type	Description
limits	resizable_limits	see below

external_kind

A single-byte unsigned integer indicating the kind of definition being imported or defined:

• 0 indicating a Function import or definition
• 1 indicating a Table import or definition
• 2 indicating a Memory import or definition
• 3 indicating a Global import or definition

resizable_limits

A packed tuple that describes the limits of a table or memory:

Field	Type	Description
flags	varuint1	1 if the maximum field is present, 0 otherwise
initial	varuint32	initial length (in units of table elements or wasm pages)
maximum	varuint32?	only present if specified by flags

Note: In the future 🦄, the "flags" field may be changed to varuint32, e.g., to include a flag for sharing between threads.

init_expr

The encoding of an initializer expression is the normal encoding of the expression followed by the end opcode as a delimiter.

Note that get_global in an initializer expression can only refer to immutable imported globals and all uses of init_expr can only appear after the Imports section.

Module structure

The following documents the current prototype format. This format is based on and supersedes the v8-native prototype format, originally in a public design doc.

High-level structure

The module starts with a preamble of two fields:

Field	Type	Description
magic number	uint32	Magic number 0x6d736100 (i.e., '\0asm')
version	uint32	Version number, 0x1

The module preamble is followed by a sequence of sections. Each section is identified by a 1-byte section code that encodes either a known section or a custom section. The section length and payload data then follow. Known sections have non-zero ids, while custom sections have a 0 id followed by an identifying string as part of the payload.

Field	Type	Description
id	varuint7	section code
payload_len	varuint32	size of this section in bytes
name_len	varuint32 ?	length of name in bytes, present if id == 0
name	bytes ?	section name: valid UTF-8 byte sequence, present if id == 0
payload_data	bytes	content of this section, of length payload_len - sizeof(name) - sizeof(name_len)

Each known section is optional and may appear at most once. Custom sections all have the same id (0), and can be named non-uniquely (all bytes composing their names may be identical).

Custom sections are intended to be used for debugging information, future evolution, or third party extensions. For MVP, we use a specific custom section (the Name Section) for debugging information.

If a WebAssembly implementation interprets the payload of any custom section during module validation or compilation, errors in that payload must not invalidate the module.

Known sections from the list below may not appear out of order, while custom sections may be interspersed before, between, as well as after any of the elements of the list, in any order. Certain custom sections may have their own ordering and cardinality requirements. For example, the Name section is expected to appear at most once, immediately after the Data section. Violation of such requirements may at most cause an implementation to ignore the section, while not invalidating the module.

The content of each section is encoded in its payload_data.

Section Name	Code	Description
Type	1	Function signature declarations
Import	2	Import declarations
Function	3	Function declarations
Table	4	Indirect function table and other tables
Memory	5	Memory attributes
Global	6	Global declarations
Export	7	Exports
Start	8	Start function declaration
Element	9	Elements section
Code	10	Function bodies (code)
Data	11	Data segments

The end of the last present section must coincide with the last byte of the module. The shortest valid module is 8 bytes (magic number, version, followed by zero sections).

Type section

The type section declares all function signatures that will be used in the module.

Field	Type	Description
count	varuint32	count of type entries to follow
entries	func_type*	repeated type entries as described above

Note: In the future 🦄, this section may contain other forms of type entries as well, which can be distinguished by the form field of the type encoding.

Import section

The import section declares all imports that will be used in the module.

Field	Type	Description
count	varuint32	count of import entries to follow
entries	import_entry*	repeated import entries as described below

Import entry

Field	Type	Description
module_len	varuint32	length of module_str in bytes
module_str	bytes	module name: valid UTF-8 byte sequence
field_len	varuint32	length of field_str in bytes
field_str	bytes	field name: valid UTF-8 byte sequence
kind	external_kind	the kind of definition being imported

Followed by, if the kind is Function:

Field	Type	Description
type	varuint32	type index of the function signature

or, if the kind is Table:

Field	Type	Description
type	table_type	type of the imported table

or, if the kind is Memory:

Field	Type	Description
type	memory_type	type of the imported memory

or, if the kind is Global:

Field	Type	Description
type	global_type	type of the imported global

Note that, in the MVP, only immutable global variables can be imported.

Function section

The function section declares the signatures of all functions in the module (their definitions appear in the code section).

Field	Type	Description
count	varuint32	count of signature indices to follow
types	varuint32*	sequence of indices into the type section

Table section

The encoding of a Table section:

Field	Type	Description
count	varuint32	indicating the number of tables defined by the module
entries	table_type*	repeated table_type entries as described above

In the MVP, the number of tables must be no more than 1.

Memory section

ID: memory

The encoding of a Memory section:

Field	Type	Description
count	varuint32	indicating the number of memories defined by the module
entries	memory_type*	repeated memory_type entries as described above

Note that the initial/maximum fields are specified in units of WebAssembly pages.

In the MVP, the number of memories must be no more than 1.

Global section

The encoding of the Global section:

Field	Type	Description
count	varuint32	count of global variable entries
globals	global_variable*	global variables, as described below

Global Entry

Each global_variable declares a single global variable of a given type, mutability and with the given initializer.

Field	Type	Description
type	global_type	type of the variables
init	init_expr	the initial value of the global

Note that, in the MVP, only immutable global variables can be exported.

Export section

The encoding of the Export section:

Field	Type	Description
count	varuint32	count of export entries to follow
entries	export_entry*	repeated export entries as described below

Export entry

Field	Type	Description
field_len	varuint32	length of field_str in bytes
field_str	bytes	field name: valid UTF-8 byte sequence
kind	external_kind	the kind of definition being exported
index	varuint32	the index into the corresponding index space

For example, if the "kind" is Function, then "index" is a function index. Note that, in the MVP, the only valid index value for a memory or table export is 0.

Start section

The start section declares the start function.

Field	Type	Description
index	varuint32	start function index

Element section

The encoding of the Elements section:

Field	Type	Description
count	varuint32	count of element segments to follow
entries	elem_segment*	repeated element segments as described below

a elem_segment is:

Field	Type	Description
index	varuint32	the table index (0 in the MVP)
offset	init_expr	an i32 initializer expression that computes the offset at which to place the elements
num_elem	varuint32	number of elements to follow
elems	varuint32*	sequence of function indices

Code section

ID: code

The code section contains a body for every function in the module. The count of function declared in the function section and function bodies defined in this section must be the same and the ith declaration corresponds to the ith function body.

Field	Type	Description
count	varuint32	count of function bodies to follow
bodies	function_body*	sequence of Function Bodies

Data section

The data section declares the initialized data that is loaded into the linear memory.

Field	Type	Description
count	varuint32	count of data segments to follow
entries	data_segment*	repeated data segments as described below

a data_segment is:

Field	Type	Description
index	varuint32	the linear memory index (0 in the MVP)
offset	init_expr	an i32 initializer expression that computes the offset at which to place the data
size	varuint32	size of data (in bytes)
data	bytes	sequence of size bytes

Name section

Custom section name field: "name"

The name section is a custom section. It is therefore encoded with id 0 followed by the name string "name". Like all custom sections, this section being malformed does not cause the validation of the module to fail. It is up to the implementation how it handles a malformed or partially malformed name section. The WebAssembly implementation is also free to choose to read and process this section lazily, after the module has been instantiated, should debugging be required.

The name section may appear only once, and only after the Data section. The expectation is that, when a binary WebAssembly module is viewed in a browser or other development environment, the data in this section will be used as the names of functions and locals in the text format.

The name section contains a sequence of name subsections:

Field	Type	Description
name_type	varuint7	code identifying type of name contained in this subsection
name_payload_len	varuint32	size of this subsection in bytes
name_payload_data	bytes	content of this section, of length name_payload_len

Since name subsections have a given length, unknown or unwanted subsections can be skipped over by an engine. The current list of valid name_type codes are:

Name Type	Code	Description
Module	0	Assigns a name to the module
Function	1	Assigns names to functions
Local	2	Assigns names to locals in functions

When present, subsections must appear in this order and at most once. The end of the last subsection must coincide with the last byte of the name section to be a well-formed name section.

Module name

The module name subsection assigns a name to the module itself. It simply consists of a single string:

Field	Type	Description
name_len	varuint32	length of name_str in bytes
name_str	bytes	UTF-8 encoding of the name

Name Map

In the following subsections, a name_map is encoded as:

Field	Type	Description
count	varuint32	number of naming in names
names	naming*	sequence of naming sorted by index

where a naming is encoded as:

Field	Type	Description
index	varuint32	the index which is being named
name_len	varuint32	length of name_str in bytes
name_str	bytes	UTF-8 encoding of the name

Function names

The function names subsection is a name_map which assigns names to a subset of the function index space (both imports and module-defined).

Each function may be named at most once. Naming a function more than once results in the section being malformed.

However, names need not be unique. The same name may be given for multiple functions. This is common for C++ programs where the multiple compilation units that comprise a binary can contain local functions with the same name.

Local names

The local names subsection assigns name_maps to a subset of functions in the function index space (both imports and module-defined). The name_map for a given function assigns names to a subset of local variable indices.

Field	Type	Description
count	varuint32	count of local_names in funcs
funcs	local_names*	sequence of local_names sorted by index

where a local_name is encoded as:

Field	Type	Description
index	varuint32	the index of the function whose locals are being named
local_map	name_map	assignment of names to local indices

Function Bodies

Function bodies consist of a sequence of local variable declarations followed by bytecode instructions. Instructions are encoded as an opcode followed by zero or more immediates as defined by the tables below. Each function body must end with the end opcode.

Field	Type	Description
body_size	varuint32	size of function body to follow, in bytes, including local fields
local_count	varuint32	number of local entries
locals	local_entry*	local variables
code	byte*	bytecode of the function
end	byte	0x0b, indicating the end of the body

Local Entry

Each local entry declares a number of local variables of a given type. It is legal to have several entries with the same type.

Field	Type	Description
count	varuint32	number of local variables of the following type
type	value_type	type of the variables

Control flow operators (described here)

Name	Opcode	Immediates	Description
unreachable	0x00		trap immediately
nop	0x01		no operation
block	0x02	sig : block_type	begin a sequence of expressions, yielding 0 or 1 values
loop	0x03	sig : block_type	begin a block which can also form control flow loops
if	0x04	sig : block_type	begin if expression
else	0x05		begin else expression of if
end	0x0b		end a block, loop, or if
br	0x0c	relative_depth : varuint32	break that targets an outer nested block
br_if	0x0d	relative_depth : varuint32	conditional break that targets an outer nested block
br_table	0x0e	see below	branch table control flow construct
return	0x0f		return zero or one value from this function

The sig fields of block and if operators specify function signatures which describe their use of the operand stack.

The br_table operator has an immediate operand which is encoded as follows:

Field	Type	Description
target_count	varuint32	number of entries in the target_table
target_table	varuint32*	target entries that indicate an outer block or loop to which to break
default_target	varuint32	an outer block or loop to which to break in the default case

The br_table operator implements an indirect branch. It accepts an optional value argument (like other branches) and an additional i32 expression as input, and branches to the block or loop at the given offset within the target_table. If the input value is out of range, br_table branches to the default target.

Note: Gaps in the opcode space, here and elsewhere, are reserved for future 🦄 extensions.

Call operators (described here)

Name	Opcode	Immediates	Description
call	0x10	function_index : varuint32	call a function by its index
call_indirect	0x11	type_index : varuint32, reserved : varuint1	call a function indirect with an expected signature

The call_indirect operator takes a list of function arguments and as the last operand the index into the table. Its reserved immediate is for future 🦄 use and must be 0 in the MVP.

Parametric operators (described here)

Name	Opcode	Immediates	Description
drop	0x1a		ignore value
select	0x1b		select one of two values based on condition

Variable access (described here)

Name	Opcode	Immediates	Description
get_local	0x20	local_index : varuint32	read a local variable or parameter
set_local	0x21	local_index : varuint32	write a local variable or parameter
tee_local	0x22	local_index : varuint32	write a local variable or parameter and return the same value
get_global	0x23	global_index : varuint32	read a global variable
set_global	0x24	global_index : varuint32	write a global variable

Memory-related operators (described here)

Name	Opcode	Immediate	Description
i32.load	0x28	memory_immediate	load from memory
i64.load	0x29	memory_immediate	load from memory
f32.load	0x2a	memory_immediate	load from memory
f64.load	0x2b	memory_immediate	load from memory
i32.load8_s	0x2c	memory_immediate	load from memory
i32.load8_u	0x2d	memory_immediate	load from memory
i32.load16_s	0x2e	memory_immediate	load from memory
i32.load16_u	0x2f	memory_immediate	load from memory
i64.load8_s	0x30	memory_immediate	load from memory
i64.load8_u	0x31	memory_immediate	load from memory
i64.load16_s	0x32	memory_immediate	load from memory
i64.load16_u	0x33	memory_immediate	load from memory
i64.load32_s	0x34	memory_immediate	load from memory
i64.load32_u	0x35	memory_immediate	load from memory
i32.store	0x36	memory_immediate	store to memory
i64.store	0x37	memory_immediate	store to memory
f32.store	0x38	memory_immediate	store to memory
f64.store	0x39	memory_immediate	store to memory
i32.store8	0x3a	memory_immediate	store to memory
i32.store16	0x3b	memory_immediate	store to memory
i64.store8	0x3c	memory_immediate	store to memory
i64.store16	0x3d	memory_immediate	store to memory
i64.store32	0x3e	memory_immediate	store to memory
current_memory	0x3f	reserved : varuint1	query the size of memory
grow_memory	0x40	reserved : varuint1	grow the size of memory

The memory_immediate type is encoded as follows:

Name	Type	Description
flags	varuint32	a bitfield which currently contains the alignment in the least significant bits, encoded as log2(alignment)
offset	varuint32	the value of the offset

As implied by the log2(alignment) encoding, the alignment must be a power of 2. As an additional validation criteria, the alignment must be less or equal to natural alignment. The bits after the log(memory-access-size) least-significant bits must be set to 0. These bits are reserved for future 🦄 use (e.g., for shared memory ordering requirements).

The reserved immediate to the current_memory and grow_memory operators is for future 🦄 use and must be 0 in the MVP.

Constants (described here)

Name	Opcode	Immediates	Description
i32.const	0x41	value : varint32	a constant value interpreted as i32
i64.const	0x42	value : varint64	a constant value interpreted as i64
f32.const	0x43	value : uint32	a constant value interpreted as f32
f64.const	0x44	value : uint64	a constant value interpreted as f64

Comparison operators (described here)

Name	Opcode	Immediate	Description
i32.eqz	0x45
i32.eq	0x46
i32.ne	0x47
i32.lt_s	0x48
i32.lt_u	0x49
i32.gt_s	0x4a
i32.gt_u	0x4b
i32.le_s	0x4c
i32.le_u	0x4d
i32.ge_s	0x4e
i32.ge_u	0x4f
i64.eqz	0x50
i64.eq	0x51
i64.ne	0x52
i64.lt_s	0x53
i64.lt_u	0x54
i64.gt_s	0x55
i64.gt_u	0x56
i64.le_s	0x57
i64.le_u	0x58
i64.ge_s	0x59
i64.ge_u	0x5a
f32.eq	0x5b
f32.ne	0x5c
f32.lt	0x5d
f32.gt	0x5e
f32.le	0x5f
f32.ge	0x60
f64.eq	0x61
f64.ne	0x62
f64.lt	0x63
f64.gt	0x64
f64.le	0x65
f64.ge	0x66

Numeric operators (described here)

Name	Opcode	Immediate	Description
i32.clz	0x67
i32.ctz	0x68
i32.popcnt	0x69
i32.add	0x6a
i32.sub	0x6b
i32.mul	0x6c
i32.div_s	0x6d
i32.div_u	0x6e
i32.rem_s	0x6f
i32.rem_u	0x70
i32.and	0x71
i32.or	0x72
i32.xor	0x73
i32.shl	0x74
i32.shr_s	0x75
i32.shr_u	0x76
i32.rotl	0x77
i32.rotr	0x78
i64.clz	0x79
i64.ctz	0x7a
i64.popcnt	0x7b
i64.add	0x7c
i64.sub	0x7d
i64.mul	0x7e
i64.div_s	0x7f
i64.div_u	0x80
i64.rem_s	0x81
i64.rem_u	0x82
i64.and	0x83
i64.or	0x84
i64.xor	0x85
i64.shl	0x86
i64.shr_s	0x87
i64.shr_u	0x88
i64.rotl	0x89
i64.rotr	0x8a
f32.abs	0x8b
f32.neg	0x8c
f32.ceil	0x8d
f32.floor	0x8e
f32.trunc	0x8f
f32.nearest	0x90
f32.sqrt	0x91
f32.add	0x92
f32.sub	0x93
f32.mul	0x94
f32.div	0x95
f32.min	0x96
f32.max	0x97
f32.copysign	0x98
f64.abs	0x99
f64.neg	0x9a
f64.ceil	0x9b
f64.floor	0x9c
f64.trunc	0x9d
f64.nearest	0x9e
f64.sqrt	0x9f
f64.add	0xa0
f64.sub	0xa1
f64.mul	0xa2
f64.div	0xa3
f64.min	0xa4
f64.max	0xa5
f64.copysign	0xa6

Conversions (described here)

Name	Opcode	Immediate	Description
i32.wrap/i64	0xa7
i32.trunc_s/f32	0xa8
i32.trunc_u/f32	0xa9
i32.trunc_s/f64	0xaa
i32.trunc_u/f64	0xab
i64.extend_s/i32	0xac
i64.extend_u/i32	0xad
i64.trunc_s/f32	0xae
i64.trunc_u/f32	0xaf
i64.trunc_s/f64	0xb0
i64.trunc_u/f64	0xb1
f32.convert_s/i32	0xb2
f32.convert_u/i32	0xb3
f32.convert_s/i64	0xb4
f32.convert_u/i64	0xb5
f32.demote/f64	0xb6
f64.convert_s/i32	0xb7
f64.convert_u/i32	0xb8
f64.convert_s/i64	0xb9
f64.convert_u/i64	0xba
f64.promote/f32	0xbb
i32.trunc_sat_f32_s	0xfc 0x00		🎳 saturating form of i32.trunc_f32_s
i32.trunc_sat_f32_u	0xfc 0x01		🎳 saturating form of i32.trunc_f32_u
i32.trunc_sat_f64_s	0xfc 0x02		🎳 saturating form of i32.trunc_f64_s
i32.trunc_sat_f64_u	0xfc 0x03		🎳 saturating form of i32.trunc_f64_u
i64.trunc_sat_f32_s	0xfc 0x04		🎳 saturating form of i64.trunc_f32_s
i64.trunc_sat_f32_u	0xfc 0x05		🎳 saturating form of i64.trunc_f32_u
i64.trunc_sat_f64_s	0xfc 0x06		🎳 saturating form of i64.trunc_f64_s
i64.trunc_sat_f64_u	0xfc 0x07		🎳 saturating form of i64.trunc_f64_u

Reinterpretations (described here)

Name	Opcode	Immediate	Description
i32.reinterpret/f32	0xbc
i64.reinterpret/f64	0xbd
f32.reinterpret/i32	0xbe
f64.reinterpret/i64	0xbf