use failure::{self, Error};
use super::{Context, Js2Rust};
use descriptor::{Descriptor, Function};
/// Helper struct for manufacturing a shim in JS used to translate Rust types to
/// JS, then invoking an imported JS function.
pub struct Rust2Js<'a, 'b: 'a> {
cx: &'a mut Context<'b>,
/// Arguments of the JS shim that we're generating, aka the variables passed
/// from Rust which are only numbers.
shim_arguments: Vec<String>,
/// Arguments which are forwarded to the imported JS function
js_arguments: Vec<String>,
/// Conversions that happen before we invoke the wasm function, such as
/// converting a string to a ptr/length pair.
prelude: String,
/// "Destructors" or cleanup that must happen after the wasm function
/// finishes. This is scheduled in a `finally` block.
finally: String,
/// Next global index to write to when passing arguments via the single
/// global stack.
global_idx: usize,
/// Index of the next argument for unique name generation purposes.
arg_idx: usize,
/// Expression used to generate the return value. The string "JS" in this
/// expression is replaced with the actual JS invocation eventually.
ret_expr: String,
/// Whether or not we're catching JS exceptions
catch: bool,
/// Whether or not the last argument is a slice representing variadic arguments.
variadic: bool,
}
impl<'a, 'b> Rust2Js<'a, 'b> {
pub fn new(cx: &'a mut Context<'b>) -> Rust2Js<'a, 'b> {
Rust2Js {
cx,
shim_arguments: Vec::new(),
js_arguments: Vec::new(),
prelude: String::new(),
finally: String::new(),
global_idx: 0,
arg_idx: 0,
ret_expr: String::new(),
catch: false,
variadic: false,
}
}
pub fn catch(&mut self, catch: bool) -> &mut Self {
if catch {
self.cx.expose_uint32_memory();
self.cx.expose_add_heap_object();
}
self.catch = catch;
self
}
pub fn variadic(&mut self, variadic: bool) -> &mut Self {
if variadic {
self.cx.expose_uint32_memory();
self.cx.expose_add_heap_object();
}
self.variadic = variadic;
self
}
/// Generates all bindings necessary for the signature in `Function`,
/// creating necessary argument conversions and return value processing.
pub fn process(&mut self, function: &Function) -> Result<&mut Self, Error> {
for arg in function.arguments.iter() {
self.argument(arg)?;
}
self.ret(&function.ret)?;
Ok(self)
}
/// Get a generated name for an argument.
fn shim_argument(&mut self) -> String {
let s = format!("arg{}", self.arg_idx);
self.arg_idx += 1;
self.shim_arguments.push(s.clone());
s
}
fn argument(&mut self, arg: &Descriptor) -> Result<(), Error> {
let abi = self.shim_argument();
let (arg, optional) = match arg {
Descriptor::Option(t) => (&**t, true),
_ => (arg, false),
};
if let Some(ty) = arg.vector_kind() {
let abi2 = self.shim_argument();
let f = self.cx.expose_get_vector_from_wasm(ty);
self.prelude(&format!(
"let v{0} = {prefix}{func}({0}, {1});",
abi,
abi2,
func = f,
prefix = if optional { format!("{} == 0 ? undefined : ", abi) } else { String::new() },
));
if !arg.is_by_ref() && !arg.is_clamped_by_ref() {
self.prelude(&format!(
"\
{start}
v{0} = v{0}.slice();
wasm.__wbindgen_free({0}, {1} * {size});
{end}\
",
abi,
abi2,
size = ty.size(),
start = if optional { format!("if ({} !== 0) {{", abi) } else { String::new() },
end = if optional { "}" } else { "" },
));
self.cx.require_internal_export("__wbindgen_free")?;
}
self.js_arguments.push(format!("v{}", abi));
return Ok(());
}
// No need to special case `optional` here because `takeObject` will
// naturally work.
if arg.is_anyref() {
self.cx.expose_take_object();
self.js_arguments.push(format!("takeObject({})", abi));
return Ok(())
} else if arg.is_ref_anyref() {
self.cx.expose_get_object();
self.js_arguments.push(format!("getObject({})", abi));
return Ok(())
}
if optional {
if arg.is_wasm_native() {
let value = self.shim_argument();
self.js_arguments.push(format!(
"{present} === 0 ? undefined : {value}",
value = value,
present = abi,
));
return Ok(())
}
if arg.is_abi_as_u32() {
self.js_arguments.push(format!("{0} === 0xFFFFFF ? undefined : {0}", abi));
return Ok(())
}
if let Some(signed) = arg.get_64() {
let f = if signed {
self.cx.expose_int64_cvt_shim()
} else {
self.cx.expose_uint64_cvt_shim()
};
self.shim_argument();
let low = self.shim_argument();
let high = self.shim_argument();
let name = format!("n{}", abi);
self.prelude(&format!(
"
u32CvtShim[0] = {present} === 0 ? 0 : {low};
u32CvtShim[1] = {present} === 0 ? 0 : {high};
const {name} = {present} === 0 ? undefined : {f}[0];
",
present = abi,
low = low,
high = high,
f = f,
name = name,
));
self.js_arguments.push(name);
return Ok(());
}
match *arg {
Descriptor::Boolean => {
self.js_arguments.push(format!("{0} === 0xFFFFFF ? undefined : {0} !== 0", abi));
return Ok(())
},
Descriptor::Char => {
let value = self.shim_argument();
self.js_arguments.push(format!(
"{present} === 0 ? undefined : String.fromCodePoint({value})",
value = value,
present = abi,
));
return Ok(())
},
_ => bail!("unsupported optional argument type for calling JS function from Rust: {:?}", arg),
};
}
if let Some(signed) = arg.get_64() {
let f = if signed {
self.cx.expose_int64_cvt_shim()
} else {
self.cx.expose_uint64_cvt_shim()
};
let high = self.shim_argument();
let name = format!("n{}", abi);
self.prelude(&format!(
"\
u32CvtShim[0] = {low};
u32CvtShim[1] = {high};
const {name} = {f}[0];
",
low = abi,
high = high,
f = f,
name = name,
));
self.js_arguments.push(name);
return Ok(());
}
if let Some(class) = arg.rust_struct() {
if arg.is_by_ref() {
bail!("cannot invoke JS functions with custom ref types yet")
}
self.cx.require_class_wrap(class);
let assign = format!("let c{0} = {1}.__wrap({0});", abi, class);
self.prelude(&assign);
self.js_arguments.push(format!("c{}", abi));
return Ok(());
}
if let Some((f, mutable)) = arg.stack_closure() {
let (js, _ts, _js_doc) = {
let mut builder = Js2Rust::new("", self.cx);
if mutable {
builder
.prelude("let a = this.a;\n")
.prelude("this.a = 0;\n")
.rust_argument("a")
.finally("this.a = a;\n");
} else {
builder.rust_argument("this.a");
}
builder
.rust_argument("this.b")
.process(f)?
.finish("function", "this.f")
};
self.cx.expose_get_global_argument()?;
self.cx.function_table_needed = true;
let next_global = self.global_idx();
self.global_idx();
self.prelude(&format!(
"\
let cb{0} = {js};\n\
cb{0}.f = wasm.__wbg_function_table.get({0});\n\
cb{0}.a = getGlobalArgument({next_global});\n\
cb{0}.b = getGlobalArgument({next_global} + 1);\n\
",
abi,
js = js,
next_global = next_global
));
self.finally(&format!("cb{0}.a = cb{0}.b = 0;", abi));
self.js_arguments.push(format!("cb{0}.bind(cb{0})", abi));
return Ok(());
}
let invoc_arg = match *arg {
ref d if d.is_number() => abi,
Descriptor::Boolean => format!("{} !== 0", abi),
Descriptor::Char => format!("String.fromCodePoint({})", abi),
_ => bail!("unsupported argument type for calling JS function from Rust: {:?}", arg),
};
self.js_arguments.push(invoc_arg);
Ok(())
}
fn ret(&mut self, ty: &Descriptor) -> Result<(), Error> {
if let Descriptor::Unit = ty {
self.ret_expr = "JS;".to_string();
return Ok(());
}
let (ty, optional) = match ty {
Descriptor::Option(t) => (&**t, true),
_ => (ty, false),
};
if ty.is_by_ref() {
bail!("cannot return a reference from JS to Rust")
}
if let Some(ty) = ty.vector_kind() {
let f = self.cx.pass_to_wasm_function(ty)?;
self.cx.expose_uint32_memory();
self.shim_arguments.insert(0, "ret".to_string());
let mut prelude = String::new();
let expr = if optional {
prelude.push_str("const val = JS;");
self.cx.expose_is_like_none();
format!("isLikeNone(val) ? [0, 0] : {}(val)", f)
} else {
format!("{}(JS)", f)
};
self.ret_expr = format!(
"\
{}
const [retptr, retlen] = {};
const mem = getUint32Memory();
mem[ret / 4] = retptr;
mem[ret / 4 + 1] = retlen;
",
prelude,
expr
);
return Ok(());
}
if ty.is_anyref() {
self.cx.expose_add_heap_object();
if optional {
self.cx.expose_is_like_none();
self.ret_expr = "
const val = JS;
return isLikeNone(val) ? 0 : addHeapObject(val);
".to_string();
} else {
self.ret_expr = "return addHeapObject(JS);".to_string()
}
return Ok(())
}
if optional {
if ty.is_wasm_native() {
self.cx.expose_is_like_none();
self.cx.expose_uint32_memory();
match ty {
Descriptor::I32 => self.cx.expose_int32_memory(),
Descriptor::U32 => (),
Descriptor::F32 => self.cx.expose_f32_memory(),
Descriptor::F64 => self.cx.expose_f64_memory(),
_ => (),
};
self.shim_arguments.insert(0, "ret".to_string());
self.ret_expr = format!(
"
const val = JS;
getUint32Memory()[ret / 4] = !isLikeNone(val);
{mem}[ret / {size} + 1] = isLikeNone(val) ? 0 : val;
",
size = match ty {
Descriptor::I32 => 4,
Descriptor::U32 => 4,
Descriptor::F32 => 4,
Descriptor::F64 => 8,
_ => unreachable!(),
},
mem = match ty {
Descriptor::I32 => "getInt32Memory()",
Descriptor::U32 => "getUint32Memory()",
Descriptor::F32 => "getFloat32Memory()",
Descriptor::F64 => "getFloat64Memory()",
_ => unreachable!(),
}
);
return Ok(());
}
if ty.is_abi_as_u32() {
self.cx.expose_is_like_none();
self.ret_expr = "
const val = JS;
return isLikeNone(val) ? 0xFFFFFF : val;
".to_string();
return Ok(());
}
if let Some(signed) = ty.get_64() {
self.cx.expose_is_like_none();
self.cx.expose_uint32_memory();
let f = if signed {
self.cx.expose_int64_memory();
"getInt64Memory"
} else {
self.cx.expose_uint64_memory();
"getUint64Memory"
};
self.shim_arguments.insert(0, "ret".to_string());
self.ret_expr = format!(
"
const val = JS;
getUint32Memory()[ret / 4] = !isLikeNone(val);
{}()[ret / 8 + 1] = isLikeNone(val) ? BigInt(0) : val;
",
f
);
return Ok(());
}
match *ty {
Descriptor::Boolean => {
self.cx.expose_is_like_none();
self.ret_expr = "
const val = JS;
return isLikeNone(val) ? 0xFFFFFF : val ? 1 : 0;
".to_string();
return Ok(());
},
Descriptor::Char => {
self.cx.expose_is_like_none();
self.cx.expose_uint32_memory();
self.shim_arguments.insert(0, "ret".to_string());
self.ret_expr = "
const val = JS;
getUint32Memory()[ret / 4] = !isLikeNone(val);
getUint32Memory()[ret / 4 + 1] = isLikeNone(val) ? 0 : val.codePointAt(0);
".to_string();
return Ok(());
},
_ => bail!("unsupported optional return type for calling JS function from Rust: {:?}", ty),
};
}
if ty.is_number() {
self.ret_expr = "return JS;".to_string();
return Ok(());
}
if let Some(signed) = ty.get_64() {
let f = if signed {
self.cx.expose_int64_memory();
"getInt64Memory"
} else {
self.cx.expose_uint64_memory();
"getUint64Memory"
};
self.shim_arguments.insert(0, "ret".to_string());
self.ret_expr = format!(
"\
const val = JS;\n\
{}()[ret / 8] = val;\n\
",
f
);
return Ok(());
}
if let Some(class) = ty.rust_struct() {
if ty.is_by_ref() {
bail!("cannot invoke JS functions returning custom ref types yet")
}
// Insert an assertion to the type of the returned value as
// otherwise this will cause memory unsafety on the Rust side of
// things.
self.ret_expr = format!(
"\
const val = JS;
if (!(val instanceof {0})) {{
throw new Error('expected value of type {0}');
}}
const ret = val.ptr;
val.ptr = 0;
return ret;\
",
class
);
return Ok(());
}
self.ret_expr = match *ty {
Descriptor::Boolean => "return JS ? 1 : 0;".to_string(),
Descriptor::Char => "return JS.codePointAt(0);".to_string(),
_ => bail!("unsupported return type for calling JS function from Rust: {:?}", ty),
};
Ok(())
}
pub fn finish(&self, invoc: &str) -> Result<String, Error> {
let mut ret = String::new();
ret.push_str("function(");
ret.push_str(&self.shim_arguments.join(", "));
if self.catch {
if self.shim_arguments.len() > 0 {
ret.push_str(", ")
}
ret.push_str("exnptr");
}
ret.push_str(") {\n");
ret.push_str(&self.prelude);
let mut invoc = if self.variadic {
if self.js_arguments.is_empty() {
return Err(failure::err_msg("a function with no arguments cannot be variadic"));
}
let last_arg = self.js_arguments.len() - 1; // check implies >= 0
if self.js_arguments.len() != 1 {
self.ret_expr.replace(
"JS",
&format!(
"{}({}, ...{})",
invoc,
self.js_arguments[..last_arg].join(", "),
self.js_arguments[last_arg],
)
)
} else {
self.ret_expr.replace(
"JS",
&format!(
"{}(...{})",
invoc,
self.js_arguments[last_arg],
)
)
}
} else {
self.ret_expr.replace(
"JS",
&format!("{}({})", invoc, self.js_arguments.join(", ")),
)
};
if self.catch {
let catch = "\
const view = getUint32Memory();\n\
view[exnptr / 4] = 1;\n\
view[exnptr / 4 + 1] = addHeapObject(e);\n\
";
invoc = format!(
"\
try {{\n\
{}
}} catch (e) {{\n\
{}
}}\
",
&invoc, catch
);
};
if self.finally.len() > 0 {
invoc = format!(
"\
try {{\n\
{}
}} finally {{\n\
{}
}}\
",
&invoc, &self.finally
);
}
ret.push_str(&invoc);
ret.push_str("\n}\n");
Ok(ret)
}
fn global_idx(&mut self) -> usize {
let ret = self.global_idx;
self.global_idx += 1;
ret
}
fn prelude(&mut self, s: &str) -> &mut Self {
for line in s.lines() {
self.prelude.push_str(line);
self.prelude.push_str("\n");
}
self
}
fn finally(&mut self, s: &str) -> &mut Self {
for line in s.lines() {
self.finally.push_str(line);
self.finally.push_str("\n");
}
self
}
}