dagger-rs/crates/dagger-codegen/src/functions.rs

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use std::sync::Arc;
use dagger_core::introspection::{FullType, FullTypeFields, InputValue, TypeRef, __TypeKind};
use eyre::ContextCompat;
use crate::utility::OptionExt;
pub trait FormatTypeFuncs {
fn format_kind_list(&self, representation: &str, input: bool, immutable: bool) -> String;
fn format_kind_scalar_string(&self, representation: &str, input: bool) -> String;
fn format_kind_scalar_int(&self, representation: &str) -> String;
fn format_kind_scalar_float(&self, representation: &str) -> String;
fn format_kind_scalar_boolean(&self, representation: &str) -> String;
fn format_kind_scalar_default(
&self,
representation: &str,
ref_name: &str,
input: bool,
) -> String;
fn format_kind_object(&self, representation: &str, ref_name: &str) -> String;
fn format_kind_input_object(&self, representation: &str, ref_name: &str) -> String;
fn format_kind_enum(&self, representation: &str, ref_name: &str) -> String;
}
pub type DynFormatTypeFuncs = Arc<dyn FormatTypeFuncs + Send + Sync>;
pub struct CommonFunctions {
format_type_funcs: DynFormatTypeFuncs,
}
impl CommonFunctions {
pub fn new(funcs: DynFormatTypeFuncs) -> Self {
Self {
format_type_funcs: funcs,
}
}
pub fn format_input_type(&self, t: &TypeRef) -> String {
self.format_type(t, true, false)
}
pub fn format_output_type(&self, t: &TypeRef) -> String {
self.format_type(t, false, false)
}
pub fn format_immutable_input_type(&self, t: &TypeRef) -> String {
self.format_type(t, true, true)
}
fn format_type(&self, t: &TypeRef, input: bool, immutable: bool) -> String {
let mut representation = String::new();
let mut r = Some(t.clone());
while r.is_some() {
return match r.as_ref() {
Some(rf) => match rf.kind.as_ref() {
Some(k) => match k {
__TypeKind::SCALAR => match Scalar::from(rf) {
Scalar::Int => self
.format_type_funcs
.format_kind_scalar_int(&mut representation),
Scalar::Float => self
.format_type_funcs
.format_kind_scalar_float(&mut representation),
Scalar::String => {
if immutable {
"&'a str".into()
} else {
self.format_type_funcs
.format_kind_scalar_string(&mut representation, input)
}
}
Scalar::Boolean => self
.format_type_funcs
.format_kind_scalar_boolean(&mut representation),
Scalar::Default => self.format_type_funcs.format_kind_scalar_default(
&mut representation,
rf.name.as_ref().unwrap(),
input,
),
},
__TypeKind::OBJECT => self
.format_type_funcs
.format_kind_object(&mut representation, rf.name.as_ref().unwrap()),
__TypeKind::ENUM => self
.format_type_funcs
.format_kind_enum(&mut representation, rf.name.as_ref().unwrap()),
__TypeKind::INPUT_OBJECT => {
self.format_type_funcs.format_kind_input_object(
&mut representation,
&rf.name.as_ref().unwrap(),
)
}
__TypeKind::LIST => {
let mut inner_type = rf
.of_type
.as_ref()
.map(|t| t.clone())
.map(|t| *t)
.map(|t| self.format_type(&t, input, immutable))
.context("could not get inner type of list")
.unwrap();
representation = self.format_type_funcs.format_kind_list(
&mut inner_type,
input,
immutable,
);
return representation;
}
__TypeKind::NON_NULL => {
r = rf.of_type.as_ref().map(|t| t.clone()).map(|t| *t);
continue;
}
__TypeKind::Other(_) => {
r = rf.of_type.as_ref().map(|t| t.clone()).map(|t| *t);
continue;
}
__TypeKind::INTERFACE => break,
__TypeKind::UNION => break,
},
None => break,
},
None => break,
};
}
println!("rep: {}", representation);
println!("{:?}", t);
representation
}
}
pub enum Scalar {
Int,
Float,
String,
Boolean,
Default,
}
impl From<&TypeRef> for Scalar {
fn from(value: &TypeRef) -> Self {
match value.name.as_ref().map(|n| n.as_str()) {
Some("Int") => Scalar::Int,
Some("Float") => Scalar::Float,
Some("String") => Scalar::String,
Some("Boolean") => Scalar::Boolean,
Some(_) => Scalar::Default,
None => Scalar::Default,
}
}
}
pub fn get_type_from_name<'t>(types: &'t [FullType], name: &'t str) -> Option<&'t FullType> {
types
.into_iter()
.find(|t| t.name.as_ref().map(|s| s.as_str()) == Some(name))
}
pub fn type_ref_is_optional(type_ref: &TypeRef) -> bool {
type_ref
.kind
.pipe(|k| *k != __TypeKind::NON_NULL)
.unwrap_or(false)
}
pub fn type_field_has_optional(field: &FullTypeFields) -> bool {
field
.args
.pipe(|a| {
a.iter()
.map(|a| a.pipe(|a| &a.input_value))
.flatten()
.collect::<Vec<_>>()
})
.pipe(|s| input_values_has_optionals(s.as_slice()))
.unwrap_or(false)
}
pub fn type_ref_is_scalar(type_ref: &TypeRef) -> bool {
let mut type_ref = type_ref.clone();
if type_ref
.kind
.pipe(|k| *k == __TypeKind::NON_NULL)
.unwrap_or(false)
{
type_ref = *type_ref.of_type.unwrap().clone();
}
type_ref
.kind
.pipe(|k| *k == __TypeKind::SCALAR)
.unwrap_or(false)
}
pub fn type_ref_is_object(type_ref: &TypeRef) -> bool {
let mut type_ref = type_ref.clone();
if type_ref
.kind
.pipe(|k| *k == __TypeKind::NON_NULL)
.unwrap_or(false)
{
type_ref = *type_ref.of_type.unwrap().clone();
}
type_ref
.kind
.pipe(|k| *k == __TypeKind::OBJECT)
.unwrap_or(false)
}
pub fn type_ref_is_list(type_ref: &TypeRef) -> bool {
let mut type_ref = type_ref.clone();
if type_ref
.kind
.pipe(|k| *k == __TypeKind::NON_NULL)
.unwrap_or(false)
{
type_ref = *type_ref.of_type.unwrap().clone();
}
type_ref
.kind
.pipe(|k| *k == __TypeKind::LIST)
.unwrap_or(false)
}
pub fn type_ref_is_list_of_objects(type_ref: &TypeRef) -> bool {
let mut type_ref = type_ref.clone();
if type_ref
.kind
.pipe(|k| *k == __TypeKind::NON_NULL)
.unwrap_or(false)
{
type_ref = *type_ref.of_type.unwrap().clone();
}
if type_ref
.kind
.pipe(|k| *k == __TypeKind::LIST)
.unwrap_or(false)
{
type_ref = *type_ref.of_type.unwrap().clone();
}
type_ref_is_object(&type_ref)
}
pub fn input_values_has_optionals(input_values: &[&InputValue]) -> bool {
input_values
.into_iter()
.map(|k| type_ref_is_optional(&k.type_))
.filter(|k| *k)
.collect::<Vec<_>>()
.len()
> 0
}
pub fn input_values_is_empty(input_values: &[InputValue]) -> bool {
input_values.len() > 0
}
#[cfg(test)]
mod test {
use dagger_core::introspection::{FullType, InputValue, TypeRef, __TypeKind};
use pretty_assertions::assert_eq;
use crate::functions::{input_values_has_optionals, type_ref_is_optional};
use super::get_type_from_name;
#[test]
fn get_type_from_name_has_no_item() {
let input = vec![];
let output = get_type_from_name(&input, "some-name");
assert_eq!(output.is_none(), true);
}
#[test]
fn get_type_from_name_has_item() {
let name = "some-name";
let input = vec![FullType {
kind: None,
name: Some(name.to_string()),
description: None,
fields: None,
input_fields: None,
interfaces: None,
enum_values: None,
possible_types: None,
}];
let output = get_type_from_name(&input, name);
assert_eq!(output.is_some(), true);
}
#[test]
fn get_type_from_name_has_item_multiple_entries() {
let name = "some-name";
let input = vec![
FullType {
kind: None,
name: Some(name.to_string()),
description: None,
fields: None,
input_fields: None,
interfaces: None,
enum_values: None,
possible_types: None,
},
FullType {
kind: None,
name: Some(name.to_string()),
description: None,
fields: None,
input_fields: None,
interfaces: None,
enum_values: None,
possible_types: None,
},
];
let output = get_type_from_name(&input, name);
assert_eq!(output.is_some(), true);
}
#[test]
fn type_ref_is_optional_has_none() {
let input = TypeRef {
kind: None,
name: None,
of_type: None,
};
let output = type_ref_is_optional(&input);
assert_eq!(output, false);
}
#[test]
fn type_ref_is_optional_is_required() {
let input = TypeRef {
kind: Some(__TypeKind::NON_NULL),
name: None,
of_type: None,
};
let output = type_ref_is_optional(&input);
assert_eq!(output, false);
}
#[test]
fn type_ref_is_optional_is_optional() {
let input = TypeRef {
kind: Some(__TypeKind::OBJECT),
name: None,
of_type: None,
};
let output = type_ref_is_optional(&input);
assert_eq!(output, true);
}
#[test]
fn input_values_has_optionals_none() {
let input = vec![];
let output = input_values_has_optionals(&input);
assert_eq!(output, false);
}
#[test]
fn input_values_has_optionals_has_optional() {
let input = vec![
InputValue {
name: "some-name".to_string(),
description: None,
type_: TypeRef {
kind: Some(__TypeKind::NON_NULL),
name: None,
of_type: None,
},
default_value: None,
},
InputValue {
name: "some-other-name".to_string(),
description: None,
type_: TypeRef {
kind: Some(__TypeKind::OBJECT),
name: None,
of_type: None,
},
default_value: None,
},
];
let output = input_values_has_optionals(input.iter().collect::<Vec<_>>().as_slice());
assert_eq!(output, true);
}
#[test]
fn input_values_has_optionals_is_required() {
let input = vec![
InputValue {
name: "some-name".to_string(),
description: None,
type_: TypeRef {
kind: Some(__TypeKind::NON_NULL),
name: None,
of_type: None,
},
default_value: None,
},
InputValue {
name: "some-other-name".to_string(),
description: None,
type_: TypeRef {
kind: Some(__TypeKind::NON_NULL),
name: None,
of_type: None,
},
default_value: None,
},
];
let output = input_values_has_optionals(input.iter().collect::<Vec<_>>().as_slice());
assert_eq!(output, false);
}
}