This repository implements a interpreter for WebAssembly. It is written for clarity and simplicity, not speed. It is intended as a playground for trying out ideas and a device for nailing down the exact semantics, and as a proxy for the (yet to be produced) formal specification of WebAssembly. For that purpose, the code is written in a fairly declarative, “speccy” way.
The interpreter can
The text format defines modules in S-expression syntax. Moreover, it is generalised to a (very dumb) form of script that can define multiples module and a batch of invocations, assertions, and conversions between them. As such it is richer than the binary format, with the additional functionality purely intended as testing infrastructure. (See below for details.)
You'll need OCaml 4.02 or higher. An easy way to get this on Linux is to download the source tarball from our mirror of the ocaml website and do the configure / make dance. On macOS, with Homebrew installed, simply brew install ocaml ocamlbuild.
Once you have OCaml, simply do
make
You'll get an executable named ./wasm. This is a byte code executable. If you want a (faster) native code executable, do
make opt
To run the test suite,
make test
To do everything:
make all
Before committing changes, you should do
make land
That builds all, plus updates winmake.bat.
We recommend a pre-built installer. With this one you have two options:
winmake.bat
in a Windows shell, which creates a program named wasm. Note that this will be a byte code executable only, i.e., somewhat slower.
make in the Cygwin terminal, as described above.Either way, in order to run the test suite you'll need to have Python installed. If you used Option 1, you can invoke the test runner runtests.py directly instead of doing it through make.
The Makefile also provides a target to compile (parts of) the interpreter into a JavaScript library:
make wast.js
Building this target requires node.js and BuckleScript.
You can call the executable with
wasm [option | file ...]
where file, depending on its extension, either should be a binary (.wasm) or textual (.wat) module file to be loaded, or a script file (.wast, see below) to be run.
By default, the interpreter validates all modules. The -u option selects “unchecked mode”, which skips validation and runs code as is. Runtime type errors will be captured and reported appropriately.
A file prefixed by -o is taken to be an output file. Depending on its extension, this will write out the preceding module definition in either S-expression or binary format. This option can be used to convert between the two in both directions, e.g.:
wasm -d module.wat -o module.wasm wasm -d module.wasm -o module.wat
In the second case, the produced script contains exactly one module definition. The -d option selects “dry mode” and ensures that the input module is not run, even if it has a start section. In addition, the -u option for “unchecked mode” can be used to convert even modules that do not validate.
The interpreter can also convert entire test scripts:
wasm -d script.wast -o script.bin.wast wasm -d script.wast -o script2.wast wasm -d script.wast -o script.js
The first creates a new test scripts where all embedded modules are converted to binary, the second one where all are converted to textual.
The last invocation produces an equivalent, self-contained JavaScript test file. The flag -h can be used to omit the test harness from the converted file; it then is the client's responsibility to provide versions of the necessary functions.
Finally, the option -e allows to provide arbitrary script commands directly on the command line. For example:
wasm module.wasm -e '(invoke "foo")'
If neither a file nor any of the previous options is given, you'll land in the REPL and can enter script commands interactively. You can also get into the REPL by explicitly passing - as a file name. You can do that in combination to giving a module or script file, so that you can then invoke its exports interactively, e.g.:
wasm module.wat -
See wasm -h for (the few) additional options.
The file wast.js generated by the respective Makefile target is a self-contained JavaScript library for making the S-expression syntax available directly within JavaScript. It provides a global object named WebAssemblyText that currently provides two methods,
WebAssemblyText.encode(source)
which turns a module in S-expression syntax into a WebAssembly binary, and
WebAssemblyText.decode(binary, width = 80)
which pretty-prints a binary back into a canonicalised S-expression string.
For example:
let source = '(module (func (export "f") (param i32 i32) (result i32) (i32.add (local.get 0) (local.get 1))))' let binary = WebAssemblyText.encode(source) (new WebAssembly.Instance(new WebAssembly.Module(binary))).exports.f(3, 4) // => 7 WebAssemblyText.decode(binary) // => // (module // (type $0 (func (param i32 i32) (result i32))) // (func $0 (type 0) (local.get 0) (local.get 1) (i32.add)) // (export "f" (func 0)) // )
The implementation consumes a WebAssembly AST given in S-expression syntax. Here is an overview of the grammar of types, expressions, functions, and modules, mirroring what's described in the design doc.
Note: The grammar is shown here for convenience, the definite source is the specification of the text format.
num: <digit> (_? <digit>)*
hexnum: <hexdigit> (_? <hexdigit>)*
nat: <num> | 0x<hexnum>
int: <nat> | +<nat> | -<nat>
float: <num>.<num>?(e|E <num>)? | 0x<hexnum>.<hexnum>?(p|P <num>)?
name: $(<letter> | <digit> | _ | . | + | - | * | / | \ | ^ | ~ | = | < | > | ! | ? | @ | # | $ | % | & | | | : | ' | `)+
string: "(<char> | \n | \t | \\ | \' | \" | \<hex><hex> | \u{<hex>+})*"
value: <int> | <float>
var: <nat> | <name>
unop: ctz | clz | popcnt | ...
binop: add | sub | mul | ...
relop: eq | ne | lt | ...
sign: s|u
offset: offset=<nat>
align: align=(1|2|4|8|...)
cvtop: trunc | extend | wrap | ...
val_type: i32 | i64 | f32 | f64
elem_type: funcref
block_type : ( result <val_type>* )*
func_type: ( type <var> )? <param>* <result>*
global_type: <val_type> | ( mut <val_type> )
table_type: <nat> <nat>? <elem_type>
memory_type: <nat> <nat>?
expr:
( <op> )
( <op> <expr>+ ) ;; = <expr>+ (<op>)
( block <name>? <block_type> <instr>* )
( loop <name>? <block_type> <instr>* )
( if <name>? <block_type> ( then <instr>* ) ( else <instr>* )? )
( if <name>? <block_type> <expr>+ ( then <instr>* ) ( else <instr>* )? ) ;; = <expr>+ (if <name>? <block_type> (then <instr>*) (else <instr>*)?)
instr:
<expr>
<op> ;; = (<op>)
block <name>? <block_type> <instr>* end <name>? ;; = (block <name>? <block_type> <instr>*)
loop <name>? <block_type> <instr>* end <name>? ;; = (loop <name>? <block_type> <instr>*)
if <name>? <block_type> <instr>* end <name>? ;; = (if <name>? <block_type> (then <instr>*))
if <name>? <block_type> <instr>* else <name>? <instr>* end <name>? ;; = (if <name>? <block_type> (then <instr>*) (else <instr>*))
op:
unreachable
nop
br <var>
br_if <var>
br_table <var>+
return
call <var>
call_indirect <func_type>
drop
select
local.get <var>
local.set <var>
local.tee <var>
global.get <var>
global.set <var>
<val_type>.load((8|16|32)_<sign>)? <offset>? <align>?
<val_type>.store(8|16|32)? <offset>? <align>?
memory.size
memory.grow
<val_type>.const <value>
<val_type>.<unop>
<val_type>.<binop>
<val_type>.<testop>
<val_type>.<relop>
<val_type>.<cvtop>_<val_type>(_<sign>)?
func: ( func <name>? <func_type> <local>* <instr>* )
( func <name>? ( export <string> ) <...> ) ;; = (export <string> (func <N>)) (func <name>? <...>)
( func <name>? ( import <string> <string> ) <func_type>) ;; = (import <name>? <string> <string> (func <func_type>))
param: ( param <val_type>* ) | ( param <name> <val_type> )
result: ( result <val_type>* )
local: ( local <val_type>* ) | ( local <name> <val_type> )
global: ( global <name>? <global_type> <instr>* )
( global <name>? ( export <string> ) <...> ) ;; = (export <string> (global <N>)) (global <name>? <...>)
( global <name>? ( import <string> <string> ) <global_type> ) ;; = (import <name>? <string> <string> (global <global_type>))
table: ( table <name>? <table_type> )
( table <name>? ( export <string> ) <...> ) ;; = (export <string> (table <N>)) (table <name>? <...>)
( table <name>? ( import <string> <string> ) <table_type> ) ;; = (import <name>? <string> <string> (table <table_type>))
( table <name>? ( export <string> )* <elem_type> ( elem <var>* ) ) ;; = (table <name>? ( export <string> )* <size> <size> <elem_type>) (elem (i32.const 0) <var>*)
elem: ( elem <var>? (offset <instr>* ) <var>* )
( elem <var>? <expr> <var>* ) ;; = (elem <var>? (offset <expr>) <var>*)
memory: ( memory <name>? <memory_type> )
( memory <name>? ( export <string> ) <...> ) ;; = (export <string> (memory <N>))+ (memory <name>? <...>)
( memory <name>? ( import <string> <string> ) <memory_type> ) ;; = (import <name>? <string> <string> (memory <memory_type>))
( memory <name>? ( export <string> )* ( data <string>* ) ) ;; = (memory <name>? ( export <string> )* <size> <size>) (data (i32.const 0) <string>*)
data: ( data <var>? ( offset <instr>* ) <string>* )
( data <var>? <expr> <string>* ) ;; = (data <var>? (offset <expr>) <string>*)
start: ( start <var> )
typedef: ( type <name>? ( func <param>* <result>* ) )
import: ( import <string> <string> <imkind> )
imkind: ( func <name>? <func_type> )
( global <name>? <global_type> )
( table <name>? <table_type> )
( memory <name>? <memory_type> )
export: ( export <string> <exkind> )
exkind: ( func <var> )
( global <var> )
( table <var> )
( memory <var> )
module: ( module <name>? <typedef>* <func>* <import>* <export>* <table>? <memory>? <global>* <elem>* <data>* <start>? )
<typedef>* <func>* <import>* <export>* <table>? <memory>? <global>* <elem>* <data>* <start>? ;; =
( module <typedef>* <func>* <import>* <export>* <table>? <memory>? <global>* <elem>* <data>* <start>? )
Here, productions marked with respective comments are abbreviation forms for equivalent expansions (see the explanation of the AST below). In particular, WebAssembly is a stack machine, so that all expressions of the form (<op> <expr>+) are merely abbreviations of a corresponding post-order sequence of instructions. For raw instructions, the syntax allows omitting the parentheses around the operator name and its immediate operands. In the case of control operators (block, loop, if), this requires marking the end of the nested sequence with an explicit end keyword.
Any form of naming via <name> and <var> (including expression labels) is merely notational convenience of this text format. The actual AST has no names, and all bindings are referred to via ordered numeric indices; consequently, names are immediately resolved in the parser and replaced by indices. Indices can also be used directly in the text format.
The segment strings in the memory field are used to initialize the consecutive memory at the given offset. The <size> in the expansion of the two short-hand forms for table and memory is the minimal size that can hold the segment: the number of <var>s for tables, and the accumulative length of the strings rounded up to page size for memories.
In addition to the grammar rules above, the fields of a module may appear in any order, except that all imports must occur before the first proper definition of a function, table, memory, or global.
Comments can be written in one of two ways:
comment: ;; <char>* <eol> (; (<char> | <comment>)* ;)
In particular, comments of the latter form nest properly.
In order to be able to check and run modules for testing purposes, the S-expression format is interpreted as a very simple and dumb notion of “script”, with commands as follows:
script: <cmd>* cmd: <module> ;; define, validate, and initialize module ( register <string> <name>? ) ;; register module for imports module with given failure string <action> ;; perform action and print results <assertion> ;; assert result of an action <meta> ;; meta command module: ... ( module <name>? binary <string>* ) ;; module in binary format (may be malformed) ( module <name>? quote <string>* ) ;; module quoted in text (may be malformed) action: ( invoke <name>? <string> <expr>* ) ;; invoke function export ( get <name>? <string> ) ;; get global export assertion: ( assert_return <action> <expr>* ) ;; assert action has expected results ( assert_return_canonical_nan <action> ) ;; assert action results in NaN in a canonical form ( assert_return_arithmetic_nan <action> ) ;; assert action results in NaN with 1 in MSB of fraction field ( assert_trap <action> <failure> ) ;; assert action traps with given failure string ( assert_malformed <module> <failure> ) ;; assert module cannot be decoded with given failure string ( assert_invalid <module> <failure> ) ;; assert module is invalid with given failure string ( assert_unlinkable <module> <failure> ) ;; assert module fails to link ( assert_trap <module> <failure> ) ;; assert module traps on instantiation meta: ( script <name>? <script> ) ;; name a subscript ( input <name>? <string> ) ;; read script or module from file ( output <name>? <string>? ) ;; output module to stout or file
Commands are executed in sequence. Commands taking an optional module name refer to the most recently defined module if no name is given. They are only possible after a module has been defined.
After a module is registered under a string name it is available for importing in other modules.
The script format supports additional syntax for defining modules. A module of the form (module binary <string>*) is given in binary form and will be decoded from the (concatenation of the) strings. A module of the form (module quote <string>*) is given in textual form and will be parsed from the (concatenation of the) strings. In both cases, decoding/parsing happens when the command is executed, not when the script is parsed, so that meta commands like assert_malformed can be used to check expected errors.
There are also a number of meta commands. The script command is a simple mechanism to name sub-scripts themselves. This is mainly useful for converting scripts with the output command. Commands inside a script will be executed normally, but nested meta are expanded in place (input, recursively) or elided (output) in the named script.
The input and output meta commands determine the requested file format from the file name extension. They can handle both .wasm, .wat, and .wast files. In the case of input, a .wast script will be recursively executed. Output additionally handles .js as a target, which will convert the referenced script to an equivalent, self-contained JavaScript runner. It also recognises .bin.wast specially, which creates a script where module definitions are in binary.
The interpreter supports a “dry” mode (flag -d), in which modules are only validated. In this mode, all actions and assertions are ignored. It also supports an “unchecked” mode (flag -u), in which module definitions are not validated before use.
The abstract WebAssembly syntax, as described above and in the design doc, is defined in ast.ml.
However, to simplify the implementation, this AST representation represents some of the inner structure of the operators more explicitly. The mapping from the operators as given in the design doc to their structured form is defined in operators.ml.
The implementation is split into several directories:
syntax: the definition of abstract syntax; corresponds to the “Structure” section of the language specification
valid: validation of code and modules; corresponds to the “Validation” section of the language specification
runtime: the definition of runtime structures; corresponds to the “Execution/Runtime” section of the language specification
exec: execution and module instantiation; corresponds to the “Execution” section of the language specification
binary: encoding and decoding of the binary format; corresponds to the “Binary Format” section of the language specification
text: parsing and printing the S-expressions text format; corresponds to the “Text Format” section of the language specification
script: abstract syntax and execution of the extended script language
host: definition of host environment modules
main: main program
util: utility libraries.
The implementation consists of the following parts:
Abstract Syntax (ast.ml, operators.ml, types.ml, source.ml[i], script.ml). Notably, the phrase wrapper type around each AST node carries the source position information.
Parser (lexer.mll, parser.mly, parse.ml[i]). Generated with ocamllex and ocamlyacc. The lexer does the opcode encoding (non-trivial tokens carry e.g. type information as semantic values, as declared in parser.mly), the parser the actual S-expression parsing.
Pretty Printer (print.ml[i], arrange.ml[i], sexpr.ml[i]). Turns a module or script AST back into the textual S-expression format.
Decoder/Encoder (decode.ml[i], encode.ml[i]). The former parses the binary format and turns it into an AST, the latter does the inverse.
Validator (valid.ml[i]). Does a recursive walk of the AST, passing down the expected type for expressions, and checking each expression against that. An expected empty type can be matched by any result, corresponding to implicit dropping of unused values (e.g. in a block).
Evaluator (eval.ml[i], values.ml, func.ml[i], table.ml[i], memory.ml[i], global.ml[i], instance.ml, eval_numeric.ml[i], int.ml, float.ml, and a few more). Implements evaluation as a small-step semantics that rewrites a program one computation step at a time.
JS Generator (js.ml[i]). Converts a script to equivalent JavaScript.
Driver (main.ml, run.ml[i], import.ml[i], error.ml, flags.ml). Executes scripts, reports results or errors, etc.
The most relevant pieces are probably the validator (valid.ml) and the evaluator (eval.ml). They are written to look as much like a “specification” as possible. Hopefully, the code is fairly self-explanatory, at least for those with a passing familiarity with functional programming.
In typical FP convention (and for better readability), the code tends to use single-character names for local variables where consistent naming conventions are applicable (e.g., e for expressions, v for values, xs for lists of xs, etc.). See ast.ml, eval.ml and eval.ml for more comments.