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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
use anyhow::{Context, Result};
use askama::Template;
use heck::{ToShoutySnakeCase, ToSnakeCase, ToUpperCamelCase};
use once_cell::sync::Lazy;
use serde::{Deserialize, Serialize};
use std::borrow::Borrow;
use std::cell::RefCell;
use std::collections::{BTreeSet, HashMap, HashSet};
use std::fmt::Debug;
use crate::backend::TemplateExpression;
use crate::interface::*;
use crate::VisitMut;
mod callback_interface;
mod compounds;
mod custom;
mod enum_;
mod external;
mod miscellany;
mod object;
mod primitives;
mod record;
/// A trait tor the implementation.
trait CodeType: Debug {
/// The language specific label used to reference this type. This will be used in
/// method signatures and property declarations.
fn type_label(&self) -> String;
/// A representation of this type label that can be used as part of another
/// identifier. e.g. `read_foo()`, or `FooInternals`.
///
/// This is especially useful when creating specialized objects or methods to deal
/// with this type only.
fn canonical_name(&self) -> String {
self.type_label()
}
fn literal(&self, _literal: &Literal) -> String {
unimplemented!("Unimplemented for {}", self.type_label())
}
/// Name of the FfiConverter
///
/// This is the object that contains the lower, write, lift, and read methods for this type.
fn ffi_converter_name(&self) -> String {
format!("FfiConverter{}", self.canonical_name())
}
/// A list of imports that are needed if this type is in use.
/// Classes are imported exactly once.
fn imports(&self) -> Option<Vec<String>> {
None
}
/// Function to run at startup
fn initialization_fn(&self) -> Option<String> {
None
}
}
// Taken from Python's `keyword.py` module.
static KEYWORDS: Lazy<HashSet<String>> = Lazy::new(|| {
let kwlist = vec![
"False",
"None",
"True",
"__peg_parser__",
"and",
"as",
"assert",
"async",
"await",
"break",
"class",
"continue",
"def",
"del",
"elif",
"else",
"except",
"finally",
"for",
"from",
"global",
"if",
"import",
"in",
"is",
"lambda",
"nonlocal",
"not",
"or",
"pass",
"raise",
"return",
"try",
"while",
"with",
"yield",
];
HashSet::from_iter(kwlist.into_iter().map(|s| s.to_string()))
});
// Config options to customize the generated python.
#[derive(Debug, Clone, Default, Serialize, Deserialize)]
pub struct Config {
pub(super) cdylib_name: Option<String>,
#[serde(default)]
custom_types: HashMap<String, CustomTypeConfig>,
#[serde(default)]
external_packages: HashMap<String, String>,
}
#[derive(Debug, Clone, Default, Serialize, Deserialize)]
pub struct CustomTypeConfig {
// This `CustomTypeConfig` doesn't have a `type_name` like the others -- which is why we have
// separate structs rather than a shared one.
imports: Option<Vec<String>>,
into_custom: TemplateExpression,
from_custom: TemplateExpression,
}
impl Config {
pub fn cdylib_name(&self) -> String {
if let Some(cdylib_name) = &self.cdylib_name {
cdylib_name.clone()
} else {
"uniffi".into()
}
}
/// Get the package name for a given external namespace.
pub fn module_for_namespace(&self, ns: &str) -> String {
let ns = ns.to_string().to_snake_case();
match self.external_packages.get(&ns) {
None => format!(".{ns}"),
Some(value) if value.is_empty() => ns,
Some(value) => format!("{value}.{ns}"),
}
}
}
// Generate python bindings for the given ComponentInterface, as a string.
pub fn generate_python_bindings(config: &Config, ci: &mut ComponentInterface) -> Result<String> {
PythonWrapper::new(config.clone(), ci)
.render()
.context("failed to render python bindings")
}
/// A struct to record a Python import statement.
#[derive(Clone, Debug, Eq, Ord, PartialEq, PartialOrd)]
pub enum ImportRequirement {
/// A simple module import.
Module { mod_name: String },
/// A single symbol from a module.
Symbol {
mod_name: String,
symbol_name: String,
},
/// A single symbol from a module with the specified local name.
SymbolAs {
mod_name: String,
symbol_name: String,
as_name: String,
},
}
impl ImportRequirement {
/// Render the Python import statement.
fn render(&self) -> String {
match &self {
ImportRequirement::Module { mod_name } => format!("import {mod_name}"),
ImportRequirement::Symbol {
mod_name,
symbol_name,
} => format!("from {mod_name} import {symbol_name}"),
ImportRequirement::SymbolAs {
mod_name,
symbol_name,
as_name,
} => format!("from {mod_name} import {symbol_name} as {as_name}"),
}
}
}
/// Renders Python helper code for all types
///
/// This template is a bit different than others in that it stores internal state from the render
/// process. Make sure to only call `render()` once.
#[derive(Template)]
#[template(syntax = "py", escape = "none", path = "Types.py")]
pub struct TypeRenderer<'a> {
python_config: &'a Config,
ci: &'a ComponentInterface,
// Track included modules for the `include_once()` macro
include_once_names: RefCell<HashSet<String>>,
// Track imports added with the `add_import()` macro
imports: RefCell<BTreeSet<ImportRequirement>>,
}
impl<'a> TypeRenderer<'a> {
fn new(python_config: &'a Config, ci: &'a ComponentInterface) -> Self {
Self {
python_config,
ci,
include_once_names: RefCell::new(HashSet::new()),
imports: RefCell::new(BTreeSet::new()),
}
}
// The following methods are used by the `Types.py` macros.
// Helper for the including a template, but only once.
//
// The first time this is called with a name it will return true, indicating that we should
// include the template. Subsequent calls will return false.
fn include_once_check(&self, name: &str) -> bool {
self.include_once_names
.borrow_mut()
.insert(name.to_string())
}
// Helper to add an import statement
//
// Call this inside your template to cause an import statement to be added at the top of the
// file. Imports will be sorted and de-deuped.
//
// Returns an empty string so that it can be used inside an askama `{{ }}` block.
fn add_import(&self, name: &str) -> &str {
self.imports.borrow_mut().insert(ImportRequirement::Module {
mod_name: name.to_owned(),
});
""
}
// Like add_import, but arranges for `from module import name`.
fn add_import_of(&self, mod_name: &str, name: &str) -> &str {
self.imports.borrow_mut().insert(ImportRequirement::Symbol {
mod_name: mod_name.to_owned(),
symbol_name: name.to_owned(),
});
""
}
// Like add_import, but arranges for `from module import name as other`.
fn add_import_of_as(&self, mod_name: &str, symbol_name: &str, as_name: &str) -> &str {
self.imports
.borrow_mut()
.insert(ImportRequirement::SymbolAs {
mod_name: mod_name.to_owned(),
symbol_name: symbol_name.to_owned(),
as_name: as_name.to_owned(),
});
""
}
// An inefficient algo to return type aliases needed for custom types
// in an order such that dependencies are in the correct order.
// Eg, if there's a custom type `Guid` -> `str` and another `GuidWrapper` -> `Guid`,
// it's important the type alias for `Guid` appears first. Fails to handle
// another level of indirection (eg, `A { builtin: C}, B { }, C { builtin: B })`)
// but that's pathological :)
fn get_custom_type_aliases(&self) -> Vec<(String, &Type)> {
let mut ordered = vec![];
for type_ in self.ci.iter_types() {
if let Type::Custom { name, builtin, .. } = type_ {
match ordered.iter().position(|x: &(&str, &Type)| {
x.1.iter_types()
.any(|nested_type| *name == nested_type.as_codetype().type_label())
}) {
// This 'name' appears as a builtin, so we must insert our type first.
Some(pos) => ordered.insert(pos, (name, builtin)),
// Otherwise at the end.
None => ordered.push((name, builtin)),
}
}
}
ordered
.into_iter()
.map(|(n, t)| (PythonCodeOracle.class_name(n), t))
.collect()
}
}
#[derive(Template)]
#[template(syntax = "py", escape = "none", path = "wrapper.py")]
pub struct PythonWrapper<'a> {
ci: &'a ComponentInterface,
config: Config,
type_helper_code: String,
type_imports: BTreeSet<ImportRequirement>,
}
impl<'a> PythonWrapper<'a> {
pub fn new(config: Config, ci: &'a mut ComponentInterface) -> Self {
ci.visit_mut(&PythonCodeOracle);
let type_renderer = TypeRenderer::new(&config, ci);
let type_helper_code = type_renderer.render().unwrap();
let type_imports = type_renderer.imports.into_inner();
Self {
config,
ci,
type_helper_code,
type_imports,
}
}
pub fn imports(&self) -> Vec<ImportRequirement> {
self.type_imports.iter().cloned().collect()
}
}
fn fixup_keyword(name: String) -> String {
if KEYWORDS.contains(&name) {
format!("_{name}")
} else {
name
}
}
#[derive(Clone, Default)]
pub struct PythonCodeOracle;
impl PythonCodeOracle {
fn find(&self, type_: &Type) -> Box<dyn CodeType> {
type_.clone().as_type().as_codetype()
}
/// Get the idiomatic Python rendering of a class name (for enums, records, errors, etc).
fn class_name(&self, nm: &str) -> String {
fixup_keyword(nm.to_string().to_upper_camel_case())
}
/// Get the idiomatic Python rendering of a function name.
fn fn_name(&self, nm: &str) -> String {
fixup_keyword(nm.to_string().to_snake_case())
}
/// Get the idiomatic Python rendering of a variable name.
fn var_name(&self, nm: &str) -> String {
fixup_keyword(nm.to_string().to_snake_case())
}
/// Get the idiomatic Python rendering of an individual enum variant.
fn enum_variant_name(&self, nm: &str) -> String {
fixup_keyword(nm.to_string().to_shouty_snake_case())
}
/// Get the idiomatic Python rendering of an FFI callback function name
fn ffi_callback_name(&self, nm: &str) -> String {
format!("_UNIFFI_{}", nm.to_shouty_snake_case())
}
/// Get the idiomatic Python rendering of an FFI struct name
fn ffi_struct_name(&self, nm: &str) -> String {
// The ctypes docs use both SHOUTY_SNAKE_CASE AND UpperCamelCase for structs. Let's use
// UpperCamelCase and reserve shouting for global variables
format!("_Uniffi{}", nm.to_upper_camel_case())
}
fn ffi_type_label(&self, ffi_type: &FfiType) -> String {
match ffi_type {
FfiType::Int8 => "ctypes.c_int8".to_string(),
FfiType::UInt8 => "ctypes.c_uint8".to_string(),
FfiType::Int16 => "ctypes.c_int16".to_string(),
FfiType::UInt16 => "ctypes.c_uint16".to_string(),
FfiType::Int32 => "ctypes.c_int32".to_string(),
FfiType::UInt32 => "ctypes.c_uint32".to_string(),
FfiType::Int64 => "ctypes.c_int64".to_string(),
FfiType::UInt64 => "ctypes.c_uint64".to_string(),
FfiType::Float32 => "ctypes.c_float".to_string(),
FfiType::Float64 => "ctypes.c_double".to_string(),
FfiType::Handle => "ctypes.c_uint64".to_string(),
FfiType::RustArcPtr(_) => "ctypes.c_void_p".to_string(),
FfiType::RustBuffer(maybe_external) => match maybe_external {
Some(external_meta) => format!("_UniffiRustBuffer{}", external_meta.name),
None => "_UniffiRustBuffer".to_string(),
},
FfiType::RustCallStatus => "_UniffiRustCallStatus".to_string(),
FfiType::ForeignBytes => "_UniffiForeignBytes".to_string(),
FfiType::Callback(name) => self.ffi_callback_name(name),
FfiType::Struct(name) => self.ffi_struct_name(name),
// Pointer to an `asyncio.EventLoop` instance
FfiType::Reference(inner) => format!("ctypes.POINTER({})", self.ffi_type_label(inner)),
FfiType::VoidPointer => "ctypes.c_void_p".to_string(),
}
}
/// Default values for FFI types
///
/// Used to set a default return value when returning an error
fn ffi_default_value(&self, return_type: Option<&FfiType>) -> String {
match return_type {
Some(t) => match t {
FfiType::UInt8
| FfiType::Int8
| FfiType::UInt16
| FfiType::Int16
| FfiType::UInt32
| FfiType::Int32
| FfiType::UInt64
| FfiType::Int64 => "0".to_owned(),
FfiType::Float32 | FfiType::Float64 => "0.0".to_owned(),
FfiType::RustArcPtr(_) => "ctypes.c_void_p()".to_owned(),
FfiType::RustBuffer(maybe_external) => match maybe_external {
Some(external_meta) => {
format!("_UniffiRustBuffer{}.default()", external_meta.name)
}
None => "_UniffiRustBuffer.default()".to_owned(),
},
_ => unimplemented!("FFI return type: {t:?}"),
},
// When we need to use a value for void returns, we use a `u8` placeholder
None => "0".to_owned(),
}
}
/// Get the name of the protocol and class name for an object.
///
/// If we support callback interfaces, the protocol name is the object name, and the class name is derived from that.
/// Otherwise, the class name is the object name and the protocol name is derived from that.
///
/// This split determines what types `FfiConverter.lower()` inputs. If we support callback
/// interfaces, `lower` must lower anything that implements the protocol. If not, then lower
/// only lowers the concrete class.
fn object_names(&self, obj: &Object) -> (String, String) {
let class_name = self.class_name(obj.name());
if obj.has_callback_interface() {
let impl_name = format!("{class_name}Impl");
(class_name, impl_name)
} else {
(format!("{class_name}Protocol"), class_name)
}
}
}
impl VisitMut for PythonCodeOracle {
fn visit_record(&self, record: &mut Record) {
record.rename(self.class_name(record.name()));
}
fn visit_object(&self, object: &mut Object) {
object.rename(self.class_name(object.name()));
}
fn visit_field(&self, field: &mut Field) {
field.rename(self.var_name(field.name()));
}
fn visit_ffi_field(&self, ffi_field: &mut FfiField) {
ffi_field.rename(self.var_name(ffi_field.name()));
}
fn visit_ffi_argument(&self, ffi_argument: &mut FfiArgument) {
ffi_argument.rename(self.class_name(ffi_argument.name()));
}
fn visit_enum(&self, is_error: bool, enum_: &mut Enum) {
if is_error {
enum_.rename(self.class_name(enum_.name()));
} else {
enum_.rename(self.enum_variant_name(enum_.name()));
}
}
fn visit_enum_key(&self, key: &mut String) -> String {
self.class_name(key)
}
fn visit_variant(&self, is_error: bool, variant: &mut Variant) {
//TODO: If we want to remove the last var_name filter
// in the template, this is it. We need an additional
// attribute for the `Variant` so we can
// display Python is_NAME functions
// variant.set_is_name(self.var_name(variant.name()));
if is_error {
variant.rename(self.class_name(variant.name()));
} else {
variant.rename(self.enum_variant_name(variant.name()));
}
}
fn visit_type(&self, type_: &mut Type) {
// Renaming Types is a special case. We have simple types with names like
// an Object, but we also have types which have inner_types and builtin types.
// Which in turn have a different name. Therefore we pass the patterns as a
// function down to the renaming operation of the type itself, which can apply it
// to all its nested names if needed.
let name_transformer = |name: &str| self.class_name(name);
type_.rename_recursive(&name_transformer);
}
fn visit_method(&self, method: &mut Method) {
method.rename(self.fn_name(method.name()));
}
fn visit_argument(&self, argument: &mut Argument) {
argument.rename(self.var_name(argument.name()));
}
fn visit_constructor(&self, constructor: &mut Constructor) {
if !constructor.is_primary_constructor() {
constructor.rename(self.fn_name(constructor.name()));
}
}
fn visit_function(&self, function: &mut Function) {
// Conversions for wrapper.py
//TODO: Renaming the function name in wrapper.py is not currently tested
function.rename(self.fn_name(function.name()));
}
fn visit_error_name(&self, name: &mut String) {
*name = self.class_name(name);
}
}
trait AsCodeType {
fn as_codetype(&self) -> Box<dyn CodeType>;
}
impl<T: AsType> AsCodeType for T {
fn as_codetype(&self) -> Box<dyn CodeType> {
// Map `Type` instances to a `Box<dyn CodeType>` for that type.
//
// There is a companion match in `templates/Types.py` which performs a similar function for the
// template code.
//
// - When adding additional types here, make sure to also add a match arm to the `Types.py` template.
// - To keep things manageable, let's try to limit ourselves to these 2 mega-matches
match self.as_type() {
Type::UInt8 => Box::new(primitives::UInt8CodeType),
Type::Int8 => Box::new(primitives::Int8CodeType),
Type::UInt16 => Box::new(primitives::UInt16CodeType),
Type::Int16 => Box::new(primitives::Int16CodeType),
Type::UInt32 => Box::new(primitives::UInt32CodeType),
Type::Int32 => Box::new(primitives::Int32CodeType),
Type::UInt64 => Box::new(primitives::UInt64CodeType),
Type::Int64 => Box::new(primitives::Int64CodeType),
Type::Float32 => Box::new(primitives::Float32CodeType),
Type::Float64 => Box::new(primitives::Float64CodeType),
Type::Boolean => Box::new(primitives::BooleanCodeType),
Type::String => Box::new(primitives::StringCodeType),
Type::Bytes => Box::new(primitives::BytesCodeType),
Type::Timestamp => Box::new(miscellany::TimestampCodeType),
Type::Duration => Box::new(miscellany::DurationCodeType),
Type::Enum { name, .. } => Box::new(enum_::EnumCodeType::new(name)),
Type::Object { name, .. } => Box::new(object::ObjectCodeType::new(name)),
Type::Record { name, .. } => Box::new(record::RecordCodeType::new(name)),
Type::CallbackInterface { name, .. } => {
Box::new(callback_interface::CallbackInterfaceCodeType::new(name))
}
Type::Optional { inner_type } => {
Box::new(compounds::OptionalCodeType::new(*inner_type))
}
Type::Sequence { inner_type } => {
Box::new(compounds::SequenceCodeType::new(*inner_type))
}
Type::Map {
key_type,
value_type,
} => Box::new(compounds::MapCodeType::new(*key_type, *value_type)),
Type::External { name, .. } => Box::new(external::ExternalCodeType::new(name)),
Type::Custom { name, .. } => Box::new(custom::CustomCodeType::new(name)),
}
}
}
pub mod filters {
use super::*;
pub use crate::backend::filters::*;
pub(super) fn type_name(as_ct: &impl AsCodeType) -> Result<String, askama::Error> {
Ok(as_ct.as_codetype().type_label())
}
//TODO: Remove. Currently just being used by EnumTemplate.py to
// display is_NAME_OF_ENUM.
/// Get the idiomatic Python rendering of a variable name.
pub fn var_name(nm: &str) -> Result<String, askama::Error> {
Ok(PythonCodeOracle.var_name(nm))
}
//TODO: Remove. Currently just being used by wrapper.py to display the
// callback_interface function names.
/// Get the idiomatic Python rendering of a class name (for enums, records, errors, etc).
pub fn class_name(nm: &str) -> Result<String, askama::Error> {
Ok(PythonCodeOracle.class_name(nm))
}
pub(super) fn ffi_converter_name(as_ct: &impl AsCodeType) -> Result<String, askama::Error> {
Ok(String::from("_Uniffi") + &as_ct.as_codetype().ffi_converter_name()[3..])
}
pub(super) fn canonical_name(as_ct: &impl AsCodeType) -> Result<String, askama::Error> {
Ok(as_ct.as_codetype().canonical_name())
}
pub(super) fn lift_fn(as_ct: &impl AsCodeType) -> Result<String, askama::Error> {
Ok(format!("{}.lift", ffi_converter_name(as_ct)?))
}
pub(super) fn check_lower_fn(as_ct: &impl AsCodeType) -> Result<String, askama::Error> {
Ok(format!("{}.check_lower", ffi_converter_name(as_ct)?))
}
pub(super) fn lower_fn(as_ct: &impl AsCodeType) -> Result<String, askama::Error> {
Ok(format!("{}.lower", ffi_converter_name(as_ct)?))
}
pub(super) fn read_fn(as_ct: &impl AsCodeType) -> Result<String, askama::Error> {
Ok(format!("{}.read", ffi_converter_name(as_ct)?))
}
pub(super) fn write_fn(as_ct: &impl AsCodeType) -> Result<String, askama::Error> {
Ok(format!("{}.write", ffi_converter_name(as_ct)?))
}
pub(super) fn literal_py(
literal: &Literal,
as_ct: &impl AsCodeType,
) -> Result<String, askama::Error> {
Ok(as_ct.as_codetype().literal(literal))
}
// Get the idiomatic Python rendering of an individual enum variant's discriminant
pub fn variant_discr_literal(e: &Enum, index: &usize) -> Result<String, askama::Error> {
let literal = e.variant_discr(*index).expect("invalid index");
Ok(Type::UInt64.as_codetype().literal(&literal))
}
pub fn ffi_type_name(type_: &FfiType) -> Result<String, askama::Error> {
Ok(PythonCodeOracle.ffi_type_label(type_))
}
pub fn ffi_default_value(return_type: Option<FfiType>) -> Result<String, askama::Error> {
Ok(PythonCodeOracle.ffi_default_value(return_type.as_ref()))
}
/// Get the idiomatic Python rendering of an FFI callback function name
pub fn ffi_callback_name(nm: &str) -> Result<String, askama::Error> {
Ok(PythonCodeOracle.ffi_callback_name(nm))
}
/// Get the idiomatic Python rendering of an FFI struct name
pub fn ffi_struct_name(nm: &str) -> Result<String, askama::Error> {
Ok(PythonCodeOracle.ffi_struct_name(nm))
}
/// Get the idiomatic Python rendering of an individual enum variant.
pub fn object_names(obj: &Object) -> Result<(String, String), askama::Error> {
Ok(PythonCodeOracle.object_names(obj))
}
/// Get the idiomatic Python rendering of docstring
pub fn docstring(docstring: &str, spaces: &i32) -> Result<String, askama::Error> {
let docstring = textwrap::dedent(docstring);
// Escape triple quotes to avoid syntax error
let escaped = docstring.replace(r#"""""#, r#"\"\"\""#);
let wrapped = format!("\"\"\"\n{escaped}\n\"\"\"");
let spaces = usize::try_from(*spaces).unwrap_or_default();
Ok(textwrap::indent(&wrapped, &" ".repeat(spaces)))
}
}
#[cfg(test)]
mod tests {
#[test]
fn test_docstring_escape() {
let docstring = r#""""This is a docstring beginning with triple quotes.
Contains "quotes" in it.
It also has a triple quote: """
And a even longer quote: """"""#;
let expected = r#""""
\"\"\"This is a docstring beginning with triple quotes.
Contains "quotes" in it.
It also has a triple quote: \"\"\"
And a even longer quote: \"\"\"""
""""#;
assert_eq!(super::filters::docstring(docstring, &0).unwrap(), expected);
}
}