Newer
Older
Guanqun Lu
committed
// This file is part of Substrate.
// Copyright (C) 2017-2021 Parity Technologies (UK) Ltd.
// SPDX-License-Identifier: Apache-2.0
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#![cfg_attr(not(feature = "std"), no_std)]
/// Export ourself as `frame_support` to make tests happy.
extern crate self as frame_support;
#[doc(hidden)]
#[cfg(feature = "std")]
#[doc(hidden)]
pub use once_cell;
#[doc(hidden)]
pub use paste;
#[cfg(feature = "std")]
#[doc(hidden)]
pub use sp_state_machine::BasicExternalities;
pub use sp_io::{storage::root as storage_root, self};
#[doc(hidden)]
pub use log;
pub mod event;
pub mod metadata;
#[macro_use]
pub mod genesis_config;
#[macro_use]
#[macro_use]
pub mod unsigned;
pub mod weights;
pub use self::hash::{
Twox256, Twox128, Blake2_256, Blake2_128, Identity, Twox64Concat, Blake2_128Concat, Hashable,
pub use self::storage::{
StorageValue, StorageMap, StorageDoubleMap, StoragePrefixedMap, IterableStorageMap,
pub use self::dispatch::{Parameter, Callable};
pub use sp_runtime::{self, ConsensusEngineId, print, traits::Printable};
use codec::{Encode, Decode};
use sp_runtime::TypeId;
/// A unified log target for support operations.
pub const LOG_TARGET: &'static str = "runtime::frame-support";
/// A type that cannot be instantiated.
#[derive(Debug, PartialEq, Eq, Clone)]
pub enum Never {}
/// A pallet identifier. These are per pallet and should be stored in a registry somewhere.
#[derive(Clone, Copy, Eq, PartialEq, Encode, Decode)]
pub struct PalletId(pub [u8; 8]);
impl TypeId for PalletId {
const TYPE_ID: [u8; 4] = *b"modl";
}
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
/// Generate a new type alias for [`storage::types::value::StorageValue`],
/// [`storage::types::value::StorageMap`] and [`storage::types::value::StorageDoubleMap`].
///
/// Useful for creating a *storage-like* struct for test and migrations.
///
///```
/// # use frame_support::generate_storage_alias;
/// use frame_support::codec;
/// use frame_support::Twox64Concat;
/// // generate a storage value with type u32.
/// generate_storage_alias!(Prefix, StorageName => Value<u32>);
///
/// // generate a double map from `(u32, u32)` (with hasher `Twox64Concat`) to `Vec<u8>`
/// generate_storage_alias!(
/// OtherPrefix, OtherStorageName => DoubleMap<
/// (u32, u32),
/// (u32, u32),
/// Vec<u8>
/// >
/// );
///
/// // generate a map from `Config::AccountId` (with hasher `Twox64Concat`) to `Vec<u8>`
/// trait Config { type AccountId: codec::FullCodec; }
/// generate_storage_alias!(
/// Prefix, GenericStorage<T: Config> => Map<(Twox64Concat, T::AccountId), Vec<u8>>
/// );
/// # fn main() {}
///```
#[macro_export]
macro_rules! generate_storage_alias {
// without generic for $name.
($pallet:ident, $name:ident => Map<($key:ty, $hasher:ty), $value:ty>) => {
$crate::paste::paste! {
$crate::generate_storage_alias!(@GENERATE_INSTANCE_STRUCT $pallet, $name);
type $name = $crate::storage::types::StorageMap<
[<$name Instance>],
$hasher,
$key,
$value,
>;
}
};
($pallet:ident, $name:ident => DoubleMap<($key1:ty, $hasher1:ty), ($key2:ty, $hasher2:ty), $value:ty>) => {
$crate::paste::paste! {
$crate::generate_storage_alias!(@GENERATE_INSTANCE_STRUCT $pallet, $name);
type $name = $crate::storage::types::StorageMap<
[<$name Instance>],
$hasher1,
$key1,
$hasher2,
$key2,
$value,
>;
}
};
($pallet:ident, $name:ident => Value<$value:ty>) => {
$crate::paste::paste! {
$crate::generate_storage_alias!(@GENERATE_INSTANCE_STRUCT $pallet, $name);
type $name = $crate::storage::types::StorageValue<
[<$name Instance>],
$value,
>;
}
};
// with generic for $name.
($pallet:ident, $name:ident<$t:ident : $bounds:tt> => Map<($key:ty, $hasher:ty), $value:ty>) => {
$crate::paste::paste! {
$crate::generate_storage_alias!(@GENERATE_INSTANCE_STRUCT $pallet, $name);
#[allow(type_alias_bounds)]
type $name<$t : $bounds> = $crate::storage::types::StorageMap<
[<$name Instance>],
$key,
$hasher,
$value,
>;
}
};
(
$pallet:ident,
$name:ident<$t:ident : $bounds:tt>
=> DoubleMap<($key1:ty, $hasher1:ty), ($key2:ty, $hasher2:ty), $value:ty>)
=> {
$crate::paste::paste! {
$crate::generate_storage_alias!(@GENERATE_INSTANCE_STRUCT $pallet, $name);
#[allow(type_alias_bounds)]
type $name<$t : $bounds> = $crate::storage::types::StorageMap<
[<$name Instance>],
$key1,
$hasher1,
$key2,
$hasher2,
$value,
>;
}
};
($pallet:ident, $name:ident<$t:ident : $bounds:tt> => Value<$value:ty>) => {
$crate::paste::paste! {
$crate::generate_storage_alias!(@GENERATE_INSTANCE_STRUCT $pallet, $name);
#[allow(type_alias_bounds)]
type $name<$t : $bounds> = $crate::storage::types::StorageValue<
[<$name Instance>],
$value,
$crate::storage::types::ValueQuery,
>;
}
};
// helper used in all arms.
(@GENERATE_INSTANCE_STRUCT $pallet:ident, $name:ident) => {
$crate::paste::paste! {
struct [<$name Instance>];
impl $crate::traits::StorageInstance for [<$name Instance>] {
fn pallet_prefix() -> &'static str { stringify!($pallet) }
const STORAGE_PREFIX: &'static str = stringify!($name);
}
}
}
}
/// Create new implementations of the [`Get`](crate::traits::Get) trait.
///
/// The so-called parameter type can be created in four different ways:
/// - Using `const` to create a parameter type that provides a `const` getter. It is required that
/// the `value` is const.
///
/// - Declare the parameter type without `const` to have more freedom when creating the value.
///
/// - Using `storage` to create a storage parameter type. This type is special as it tries to load
/// the value from the storage under a fixed key. If the value could not be found in the storage,
/// the given default value will be returned. It is required that the value implements
/// [`Encode`](codec::Encode) and [`Decode`](codec::Decode). The key for looking up the value in
/// the storage is built using the following formula:
///
/// `twox_128(":" ++ NAME ++ ":")` where `NAME` is the name that is passed as type name.
///
/// - Using `static` to create a static parameter type. Its value is
/// being provided by a static variable with the equivalent name in `UPPER_SNAKE_CASE`. An
/// additional `set` function is provided in this case to alter the static variable.
/// **This is intended for testing ONLY and is ONLY available when `std` is enabled.**
/// ```
/// # use frame_support::traits::Get;
/// # use frame_support::parameter_types;
/// // This function cannot be used in a const context.
/// fn non_const_expression() -> u64 { 99 }
///
/// const FIXED_VALUE: u64 = 10;
/// pub const Argument: u64 = 42 + FIXED_VALUE;
/// /// Visibility of the type is optional
/// OtherArgument: u64 = non_const_expression();
/// pub storage StorageArgument: u64 = 5;
/// pub static StaticArgument: u32 = 7;
/// type Parameter: Get<u64>;
/// type OtherParameter: Get<u64>;
/// type StorageParameter: Get<u64>;
/// type StaticParameter: Get<u32>;
/// struct Runtime;
/// impl Config for Runtime {
/// type Parameter = Argument;
/// type OtherParameter = OtherArgument;
/// type StorageParameter = StorageArgument;
/// type StaticParameter = StaticArgument;
/// }
///
/// // In testing, `StaticArgument` can be altered later: `StaticArgument::set(8)`.
/// ```
///
/// # Invalid example:
///
/// ```compile_fail
/// # use frame_support::traits::Get;
/// # use frame_support::parameter_types;
/// // This function cannot be used in a const context.
/// fn non_const_expression() -> u64 { 99 }
///
/// parameter_types! {
/// pub const Argument: u64 = non_const_expression();
/// }
/// ```
#[macro_export]
macro_rules! parameter_types {
(
$( #[ $attr:meta ] )*
$vis:vis const $name:ident: $type:ty = $value:expr;
$( $rest:tt )*
) => (
$( #[ $attr ] )*
$vis struct $name;
$crate::parameter_types!(IMPL_CONST $name , $type , $value);
$crate::parameter_types!( $( $rest )* );
);
(
$( #[ $attr:meta ] )*
$vis:vis $name:ident: $type:ty = $value:expr;
$( $rest:tt )*
) => (
$( #[ $attr ] )*
$vis struct $name;
$crate::parameter_types!(IMPL $name, $type, $value);
$crate::parameter_types!( $( $rest )* );
);
(
$( #[ $attr:meta ] )*
$vis:vis storage $name:ident: $type:ty = $value:expr;
$( $rest:tt )*
) => (
$( #[ $attr ] )*
$vis struct $name;
$crate::parameter_types!(IMPL_STORAGE $name, $type, $value);
$crate::parameter_types!( $( $rest )* );
(IMPL_CONST $name:ident, $type:ty, $value:expr) => {
impl $name {
/// Returns the value of this parameter type.
pub const fn get() -> $type {
$value
}
}
impl<I: From<$type>> $crate::traits::Get<I> for $name {
fn get() -> I {
I::from($value)
}
}
};
(IMPL $name:ident, $type:ty, $value:expr) => {
/// Returns the value of this parameter type.
pub fn get() -> $type {
$value
}
}
impl<I: From<$type>> $crate::traits::Get<I> for $name {
fn get() -> I {
I::from($value)
}
}
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
};
(IMPL_STORAGE $name:ident, $type:ty, $value:expr) => {
impl $name {
/// Returns the key for this parameter type.
pub fn key() -> [u8; 16] {
$crate::sp_io::hashing::twox_128(
concat!(":", stringify!($name), ":").as_bytes()
)
}
/// Set the value of this parameter type in the storage.
///
/// This needs to be executed in an externalities provided
/// environment.
pub fn set(value: &$type) {
$crate::storage::unhashed::put(&Self::key(), value);
}
/// Returns the value of this parameter type.
///
/// This needs to be executed in an externalities provided
/// environment.
pub fn get() -> $type {
$crate::storage::unhashed::get(&Self::key()).unwrap_or_else(|| $value)
}
}
impl<I: From<$type>> $crate::traits::Get<I> for $name {
fn get() -> I {
I::from(Self::get())
}
}
$( #[ $attr:meta ] )*
$vis:vis static $name:ident: $type:ty = $value:expr;
$( $rest:tt )*
) => (
$crate::parameter_types_impl_thread_local!(
$( #[ $attr ] )*
$vis static $name: $type = $value;
$crate::parameter_types!( $( $rest )* );
);
}
#[cfg(not(feature = "std"))]
#[macro_export]
macro_rules! parameter_types_impl_thread_local {
( $( $any:tt )* ) => {
compile_error!("static parameter types is only available in std and for testing.");
};
}
#[cfg(feature = "std")]
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
#[macro_export]
macro_rules! parameter_types_impl_thread_local {
(
$(
$( #[ $attr:meta ] )*
$vis:vis static $name:ident: $type:ty = $value:expr;
)*
) => {
$crate::parameter_types_impl_thread_local!(
IMPL_THREAD_LOCAL $( $vis, $name, $type, $value, )*
);
$crate::paste::item! {
$crate::parameter_types!(
$(
$( #[ $attr ] )*
$vis $name: $type = [<$name:snake:upper>].with(|v| v.borrow().clone());
)*
);
$(
impl $name {
/// Set the internal value.
pub fn set(t: $type) {
[<$name:snake:upper>].with(|v| *v.borrow_mut() = t);
}
}
)*
}
};
(IMPL_THREAD_LOCAL $( $vis:vis, $name:ident, $type:ty, $value:expr, )* ) => {
$crate::paste::item! {
thread_local! {
$(
pub static [<$name:snake:upper>]: std::cell::RefCell<$type> =
std::cell::RefCell::new($value);
)*
}
}
};
/// Macro for easily creating a new implementation of both the `Get` and `Contains` traits. Use
/// exactly as with `parameter_types`, only the type must be `Ord`.
#[macro_export]
macro_rules! ord_parameter_types {
(
$( #[ $attr:meta ] )*
$vis:vis const $name:ident: $type:ty = $value:expr;
$( $rest:tt )*
) => (
$( #[ $attr ] )*
$vis struct $name;
$crate::parameter_types!{IMPL $name , $type , $value}
$crate::ord_parameter_types!{IMPL $name , $type , $value}
$crate::ord_parameter_types!{ $( $rest )* }
);
() => ();
(IMPL $name:ident , $type:ty , $value:expr) => {
impl $crate::traits::SortedMembers<$type> for $name {
fn contains(t: &$type) -> bool { &$value == t }
fn sorted_members() -> $crate::sp_std::prelude::Vec<$type> { vec![$value] }
fn count() -> usize { 1 }
#[cfg(feature = "runtime-benchmarks")]
fn add(_: &$type) {}
impl $crate::traits::Contains<$type> for $name {
fn contains(t: &$type) -> bool { &$value == t }
}
/// Print out a formatted message.
///
/// # Example
///
/// ```
/// frame_support::runtime_print!("my value is {}", 3);
/// ```
#[macro_export]
macro_rules! runtime_print {
($($arg:tt)+) => {
{
use core::fmt::Write;
let mut w = $crate::sp_std::Writer::default();
let _ = core::write!(&mut w, $($arg)+);
$crate::sp_io::misc::print_utf8(&w.inner())
}
}
}
/// Print out the debuggable type.
pub fn debug(data: &impl sp_std::fmt::Debug) {
runtime_print!("{:?}", data);
}
pub use frame_support_procedural::{
decl_storage, construct_runtime, transactional, RuntimeDebugNoBound
/// Derive [`Clone`] but do not bound any generic.
///
/// This is useful for type generic over runtime:
/// ```
/// # use frame_support::CloneNoBound;
/// type C: Clone;
/// }
///
/// // Foo implements [`Clone`] because `C` bounds [`Clone`].
/// // Otherwise compilation will fail with an output telling `c` doesn't implement [`Clone`].
/// #[derive(CloneNoBound)]
/// struct Foo<T: Config> {
/// c: T::C,
/// }
/// ```
pub use frame_support_procedural::CloneNoBound;
/// Derive [`Eq`] but do not bound any generic.
///
/// This is useful for type generic over runtime:
/// ```
/// # use frame_support::{EqNoBound, PartialEqNoBound};
/// type C: Eq;
/// }
///
/// // Foo implements [`Eq`] because `C` bounds [`Eq`].
/// // Otherwise compilation will fail with an output telling `c` doesn't implement [`Eq`].
/// #[derive(PartialEqNoBound, EqNoBound)]
/// struct Foo<T: Config> {
/// c: T::C,
/// }
/// ```
pub use frame_support_procedural::EqNoBound;
/// Derive [`PartialEq`] but do not bound any generic.
///
/// This is useful for type generic over runtime:
/// ```
/// # use frame_support::PartialEqNoBound;
/// type C: PartialEq;
/// }
///
/// // Foo implements [`PartialEq`] because `C` bounds [`PartialEq`].
/// // Otherwise compilation will fail with an output telling `c` doesn't implement [`PartialEq`].
/// #[derive(PartialEqNoBound)]
/// struct Foo<T: Config> {
/// c: T::C,
/// }
/// ```
pub use frame_support_procedural::PartialEqNoBound;
/// Derive [`Debug`] but do not bound any generic.
///
/// This is useful for type generic over runtime:
/// ```
/// # use frame_support::DebugNoBound;
/// # use core::fmt::Debug;
/// type C: Debug;
/// }
///
/// // Foo implements [`Debug`] because `C` bounds [`Debug`].
/// // Otherwise compilation will fail with an output telling `c` doesn't implement [`Debug`].
/// #[derive(DebugNoBound)]
/// struct Foo<T: Config> {
/// c: T::C,
/// }
/// ```
pub use frame_support_procedural::DebugNoBound;
/// Derive [`Default`] but do not bound any generic.
///
/// This is useful for type generic over runtime:
/// ```
/// # use frame_support::DefaultNoBound;
/// # use core::default::Default;
/// trait Config {
/// type C: Default;
/// }
///
/// // Foo implements [`Default`] because `C` bounds [`Default`].
/// // Otherwise compilation will fail with an output telling `c` doesn't implement [`Default`].
/// #[derive(DefaultNoBound)]
/// struct Foo<T: Config> {
/// c: T::C,
/// }
/// ```
pub use frame_support_procedural::DefaultNoBound;
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
/// Assert the annotated function is executed within a storage transaction.
///
/// The assertion is enabled for native execution and when `debug_assertions` are enabled.
///
/// # Example
///
/// ```
/// # use frame_support::{
/// # require_transactional, transactional, dispatch::DispatchResult
/// # };
///
/// #[require_transactional]
/// fn update_all(value: u32) -> DispatchResult {
/// // Update multiple storages.
/// // Return `Err` to indicate should revert.
/// Ok(())
/// }
///
/// #[transactional]
/// fn safe_update(value: u32) -> DispatchResult {
/// // This is safe
/// update_all(value)
/// }
///
/// fn unsafe_update(value: u32) -> DispatchResult {
/// // this may panic if unsafe_update is not called within a storage transaction
/// update_all(value)
/// }
/// ```
pub use frame_support_procedural::require_transactional;
/// Convert the current crate version into a [`PalletVersion`](crate::traits::PalletVersion).
///
/// It uses the `CARGO_PKG_VERSION_MAJOR`, `CARGO_PKG_VERSION_MINOR` and
/// `CARGO_PKG_VERSION_PATCH` environment variables to fetch the crate version.
/// This means that the [`PalletVersion`](crate::traits::PalletVersion)
/// object will correspond to the version of the crate the macro is called in!
///
/// # Example
///
/// ```
/// # use frame_support::{traits::PalletVersion, crate_to_pallet_version};
/// const Version: PalletVersion = crate_to_pallet_version!();
/// ```
pub use frame_support_procedural::crate_to_pallet_version;
/// Return Err of the expression: `return Err($expression);`.
///
/// Used as `fail!(expression)`.
#[macro_export]
macro_rules! fail {
( $y:expr ) => {{
/// Evaluate `$x:expr` and if not true return `Err($y:expr)`.
///
/// Used as `ensure!(expression_to_ensure, expression_to_return_on_false)`.
#[macro_export]
macro_rules! ensure {
$crate::fail!($y);
/// Evaluate an expression, assert it returns an expected `Err` value and that
/// runtime storage has not been mutated (i.e. expression is a no-operation).
///
/// Used as `assert_noop(expression_to_assert, expected_error_expression)`.
(
$x:expr,
$y:expr $(,)?
) => {
let h = $crate::storage_root();
$crate::assert_err!($x, $y);
assert_eq!(h, $crate::storage_root());
/// Evaluate any expression and assert that runtime storage has not been mutated
/// (i.e. expression is a storage no-operation).
///
/// Used as `assert_storage_noop(expression_to_assert)`.
#[macro_export]
macro_rules! assert_storage_noop {
(
$x:expr
) => {
let h = $crate::storage_root();
$x;
assert_eq!(h, $crate::storage_root());
}
}
/// Assert an expression returns an error specified.
///
/// Used as `assert_err!(expression_to_assert, expected_error_expression)`
assert_eq!($x, Err($y.into()));
/// Assert an expression returns an error specified.
///
/// This can be used on`DispatchResultWithPostInfo` when the post info should
/// be ignored.
#[macro_export]
macro_rules! assert_err_ignore_postinfo {
( $x:expr , $y:expr $(,)? ) => {
$crate::assert_err!($x.map(|_| ()).map_err(|e| e.error), $y);
}
}
/// Assert an expression returns error with the given weight.
#[macro_export]
macro_rules! assert_err_with_weight {
($call:expr, $err:expr, $weight:expr $(,)? ) => {
if let Err(dispatch_err_with_post) = $call {
$crate::assert_err!($call.map(|_| ()).map_err(|e| e.error), $err);
assert_eq!(dispatch_err_with_post.post_info.actual_weight, $weight.into());
} else {
panic!("expected Err(_), got Ok(_).")
}
}
}
/// Panic if an expression doesn't evaluate to `Ok`.
///
/// Used as `assert_ok!(expression_to_assert, expected_ok_expression)`,
/// or `assert_ok!(expression_to_assert)` which would assert against `Ok(())`.
( $x:expr $(,)? ) => {
let is = $x;
match is {
Ok(_) => (),
_ => assert!(false, "Expected Ok(_). Got {:#?}", is),
}
( $x:expr, $y:expr $(,)? ) => {
Bastian Köcher
committed
#[doc(hidden)]
pub use serde::{Serialize, Deserialize};
Drew Stone
committed
pub mod tests {
DecodeDifferent, StorageEntryMetadata, StorageMetadata, StorageEntryType,
StorageEntryModifier, DefaultByteGetter, StorageHasher,
use sp_std::{marker::PhantomData, result};
use sp_io::TestExternalities;
/// A PalletInfo implementation which just panics.
pub struct PanicPalletInfo;
impl crate::traits::PalletInfo for PanicPalletInfo {
fn index<P: 'static>() -> Option<usize> {
unimplemented!("PanicPalletInfo mustn't be triggered by tests");
}
fn name<P: 'static>() -> Option<&'static str> {
unimplemented!("PanicPalletInfo mustn't be triggered by tests");
}
}
pub trait Config: 'static {
type BlockNumber: Codec + EncodeLike + Default;
type PalletInfo: crate::traits::PalletInfo;
type DbWeight: crate::traits::Get<crate::weights::RuntimeDbWeight>;
}
mod module {
#![allow(dead_code)]
pub struct Module<T: Config> for enum Call where origin: T::Origin, system=self {}
}
}
use self::module::Module;
decl_storage! {
trait Store for Module<T: Config> as Test {
pub Data get(fn data) build(|_| vec![(15u32, 42u64)]):
map hasher(twox_64_concat) u32 => u64;
pub OptionLinkedMap: map hasher(blake2_128_concat) u32 => Option<u32>;
pub GenericData get(fn generic_data):
map hasher(identity) T::BlockNumber => T::BlockNumber;
pub GenericData2 get(fn generic_data2):
map hasher(blake2_128_concat) T::BlockNumber => Option<T::BlockNumber>;
pub DataDM config(test_config) build(|_| vec![(15u32, 16u32, 42u64)]):
double_map hasher(twox_64_concat) u32, hasher(blake2_128_concat) u32 => u64;
double_map hasher(blake2_128_concat) T::BlockNumber, hasher(identity) T::BlockNumber
double_map hasher(blake2_128_concat) T::BlockNumber, hasher(twox_64_concat) T::BlockNumber
=> Option<T::BlockNumber>;
pub AppendableDM:
double_map hasher(blake2_128_concat) u32, hasher(blake2_128_concat) T::BlockNumber => Vec<u32>;
type BlockNumber = u32;
type Origin = u32;
type PalletInfo = PanicPalletInfo;
fn new_test_ext() -> TestExternalities {
GenesisConfig::default().build_storage().unwrap().into()
type Map = Data;
trait Sorted { fn sorted(self) -> Self; }
impl<T: Ord> Sorted for Vec<T> {
fn sorted(mut self) -> Self {
self.sort();
self
}
}
new_test_ext().execute_with(|| {
OptionLinkedMap::insert(1, 1);
assert_eq!(OptionLinkedMap::get(1), Some(1));
OptionLinkedMap::insert(1, 2);
assert_eq!(OptionLinkedMap::get(1), Some(2));
});
}
new_test_ext().execute_with(|| {
OptionLinkedMap::insert(0, 0);
OptionLinkedMap::insert(1, 1);
OptionLinkedMap::insert(2, 2);
OptionLinkedMap::insert(3, 3);
let collect = || OptionLinkedMap::iter().collect::<Vec<_>>().sorted();
assert_eq!(collect(), vec![(0, 0), (1, 1), (2, 2), (3, 3)]);
// Two existing
OptionLinkedMap::swap(1, 2);
assert_eq!(collect(), vec![(0, 0), (1, 2), (2, 1), (3, 3)]);
// Back to normal
OptionLinkedMap::swap(2, 1);
assert_eq!(collect(), vec![(0, 0), (1, 1), (2, 2), (3, 3)]);
// Left existing
OptionLinkedMap::swap(2, 5);
assert_eq!(collect(), vec![(0, 0), (1, 1), (3, 3), (5, 2)]);
// Right existing
OptionLinkedMap::swap(5, 2);
assert_eq!(collect(), vec![(0, 0), (1, 1), (2, 2), (3, 3)]);
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
#[test]
fn double_map_swap_works() {
new_test_ext().execute_with(|| {
DataDM::insert(0, 1, 1);
DataDM::insert(1, 0, 2);
DataDM::insert(1, 1, 3);
let get_all = || vec![
DataDM::get(0, 1),
DataDM::get(1, 0),
DataDM::get(1, 1),
DataDM::get(2, 0),
DataDM::get(2, 1),
];
assert_eq!(get_all(), vec![1, 2, 3, 0, 0]);
// Two existing
DataDM::swap(0, 1, 1, 0);
assert_eq!(get_all(), vec![2, 1, 3, 0, 0]);
// Left existing
DataDM::swap(1, 0, 2, 0);
assert_eq!(get_all(), vec![2, 0, 3, 1, 0]);
// Right existing
DataDM::swap(2, 1, 1, 1);
assert_eq!(get_all(), vec![2, 0, 0, 1, 3]);
});
}
fn map_basic_insert_remove_should_work() {
new_test_ext().execute_with(|| {
assert_eq!(Map::get(&15u32), 42u64);
// get / insert / take
let key = 17u32;
assert_eq!(Map::get(&key), 0u64);
Map::insert(key, 4u64);
assert_eq!(Map::get(&key), 4u64);
assert_eq!(Map::take(&key), 4u64);
assert_eq!(Map::get(&key), 0u64);
// mutate
Map::mutate(&key, |val| {
*val = 15;
});
assert_eq!(Map::get(&key), 15u64);
// remove
Map::remove(&key);
assert_eq!(Map::get(&key), 0u64);
});
}
#[test]
new_test_ext().execute_with(|| {
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![(15, 42)]);
// insert / remove
let key = 17u32;
Map::insert(key, 4u64);
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![(15, 42), (key, 4)]);
assert_eq!(Map::take(&15), 42u64);
assert_eq!(Map::take(&key), 4u64);
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![]);
// Add couple of more elements
Map::insert(key, 42u64);
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![(key, 42)]);
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![(key, 42), (key + 1, 43)]);
// mutate
let key = key + 2;
Map::mutate(&key, |val| {
*val = 15;
});
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![(key - 2, 42), (key - 1, 43), (key, 15)]);
Map::mutate(&key, |val| {
*val = 17;
});
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![(key - 2, 42), (key - 1, 43), (key, 17)]);
// remove first
Map::remove(&key);
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![(key - 2, 42), (key - 1, 43)]);
// remove last from the list
Map::remove(&(key - 2));
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![(key - 1, 43)]);
// remove the last element
Map::remove(&(key - 1));
assert_eq!(Map::iter().collect::<Vec<_>>().sorted(), vec![]);
#[test]
fn double_map_basic_insert_remove_remove_prefix_should_work() {
new_test_ext().execute_with(|| {
type DoubleMap = DataDM;
assert_eq!(DoubleMap::get(&15u32, &16u32), 42u64);
// get / insert / take
let key1 = 17u32;
let key2 = 18u32;
assert_eq!(DoubleMap::get(&key1, &key2), 0u64);
DoubleMap::insert(&key1, &key2, &4u64);
assert_eq!(DoubleMap::get(&key1, &key2), 4u64);
assert_eq!(DoubleMap::take(&key1, &key2), 4u64);
assert_eq!(DoubleMap::get(&key1, &key2), 0u64);
DoubleMap::mutate(&key1, &key2, |val| {
assert_eq!(DoubleMap::get(&key1, &key2), 15u64);
DoubleMap::remove(&key1, &key2);
assert_eq!(DoubleMap::get(&key1, &key2), 0u64);