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pulumi/sdk/nodejs/output.ts

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// Copyright 2016-2018, Pulumi Corporation.
//
// 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.
import { Resource } from "./resource";
import * as settings from "./runtime/settings";
import * as utils from "./utils";
/* eslint-disable no-shadow, @typescript-eslint/no-shadow */
/**
* Output helps encode the relationship between Resources in a Pulumi application. Specifically an
* Output holds onto a piece of Data and the Resource it was generated from. An Output value can
* then be provided when constructing new Resources, allowing that new Resource to know both the
* value as well as the Resource the value came from. This allows for a precise 'Resource
* dependency graph' to be created, which properly tracks the relationship between resources.
*/
class OutputImpl<T> implements OutputInstance<T> {
/**
* A private field to help with RTTI that works in SxS scenarios.
*
* This is internal instead of being truly private, to support mixins and our serialization model.
* @internal
*/
// eslint-disable-next-line @typescript-eslint/naming-convention,no-underscore-dangle,id-blacklist,id-match
public readonly __pulumiOutput: boolean = true;
/**
* Whether or not this 'Output' wraps a secret value. Values which are marked as secret are stored in an
* encrypted format when they are persisted as part of a state file. When`true` this "taints" any
* additional resources created from it via an [all] or [apply], such that they are also treated as
* secrets.
* @internal
*/
public readonly isSecret: Promise<boolean>;
/**
* Whether or not this 'Output' should actually perform .apply calls. During a preview,
* an Output value may not be known (because it would have to actually be computed by doing an
* 'update'). In that case, we don't want to perform any .apply calls as the callbacks
* may not expect an undefined value. So, instead, we just transition to another Output
* value that itself knows it should not perform .apply calls.
* @internal
*/
public readonly isKnown: Promise<boolean>;
/**
* Method that actually produces the concrete value of this output, as well as the total
* deployment-time set of resources this output depends on. If the value of the output is not
* known (i.e. isKnown resolves to false), this promise should resolve to undefined unless the
* `withUnknowns` flag is passed, in which case it will resolve to `unknown`.
*
* Only callable on the outside.
* @internal
*/
public readonly promise: (withUnknowns?: boolean) => Promise<T>;
/**
* The list of resources that this output value depends on.
*
* Only callable on the outside.
*
* This only returns the set of dependent resources that were known at Output construction time.
* It represents the `@pulumi/pulumi` api prior to the addition of 'async resource'
* dependencies. Code inside @pulumi/pulumi should use `.allResources` instead.
* @internal
*/
public readonly resources: () => Set<Resource>;
/**
* The entire list of resources that this output depends on.
*
* This includes both the dependent resources that were known when the Output was explicitly
* instantiated, along with any dependent resources produced asynchronously and returned from
* the function passed to `Output.apply`.
*
* This should be used whenever available inside this package. However, code that uses this
* should be resilient to it being absent and should fall back to using `.resources()` instead.
*
* Note: it is fine to use this property if it is guaranteed that it is on an output produced by
* this SDK (and not another sxs version).
* @internal
*/
// Marked as optional for sxs scenarios.
public readonly allResources?: () => Promise<Set<Resource>>;
/**
* [toString] on an [Output<T>] is not supported. This is because the value an [Output] points
* to is asynchronously computed (and thus, this is akin to calling [toString] on a [Promise]).
*
* Calling this will simply return useful text about the issue, and will log a warning. In a
* future version of `@pulumi/pulumi` this will be changed to throw an error when this occurs.
*
* To get the value of an Output<T> as an Output<string> consider either:
* 1. `o.apply(v => ``prefix${v}suffix``)` or
* 2. `pulumi.interpolate ``prefix${v}suffix`` `
*
* This will return an Output with the inner computed value and all resources still tracked. See
* https://www.pulumi.com/docs/concepts/inputs-outputs for more details
* @internal
*/
public toString: () => string;
/**
* [toJSON] on an [Output<T>] is not supported. This is because the value an [Output] points
* to is asynchronously computed (and thus, this is akin to calling [toJSON] on a [Promise]).
*
* Calling this will simply return useful text about the issue, and will log a warning. In a
* future version of `@pulumi/pulumi` this will be changed to throw an error when this occurs.
*
* To get the value of an Output as a JSON value or JSON string consider either:
* 1. `o.apply(v => v.toJSON())` or
* 2. `o.apply(v => JSON.stringify(v))`
*
* This will return an Output with the inner computed value and all resources still tracked.
* See https://www.pulumi.com/docs/concepts/inputs-outputs for more details
* @internal
*/
public toJSON: () => any;
// Statics
/**
* create takes any Input value and converts it into an Output, deeply unwrapping nested Input
* values as necessary.
*/
public static create<T>(val: Input<T>): Output<Unwrap<T>>;
public static create<T>(val: Input<T> | undefined): Output<Unwrap<T | undefined>>;
public static create<T>(val: Input<T | undefined>): Output<Unwrap<T | undefined>> {
return output(val);
}
/**
* Returns true if the given object is an instance of Output<T>. This is designed to work even when
* multiple copies of the Pulumi SDK have been loaded into the same process.
*/
public static isInstance<T>(obj: any): obj is Output<T> {
return utils.isInstance(obj, "__pulumiOutput");
}
/** @internal */
static async getPromisedValue<T>(promise: Promise<T>, withUnknowns?: boolean): Promise<T> {
// If the caller did not explicitly ask to see unknown values and val contains unknowns, return undefined. This
// preserves compatibility with earlier versions of the Pulumi SDK.
const val = await promise;
if (!withUnknowns && containsUnknowns(val)) {
return <T>(<any>undefined);
}
return val;
}
/** @internal */
public constructor(
resources: Set<Resource> | Resource[] | Resource,
promise: Promise<T>,
isKnown: Promise<boolean>,
isSecret: Promise<boolean>,
allResources: Promise<Set<Resource> | Resource[] | Resource> | undefined,
) {
// Always create a copy so that no one accidentally modifies our Resource list.
const resourcesCopy = copyResources(resources);
// Create a copy of the async resources. Populate this with the sync-resources if that's
// all we have. That way this is always ensured to be a superset of the list of sync resources.
allResources = allResources || Promise.resolve([]);
const allResourcesCopy = allResources.then((r) => utils.union(copyResources(r), resourcesCopy));
// We are only known if we are not explicitly unknown and the resolved value of the output
// contains no distinguished unknown values.
isKnown = Promise.all([isKnown, promise]).then(([known, val]) => known && !containsUnknowns(val));
const lifted = Promise.all([allResourcesCopy, promise, isKnown, isSecret]).then(
([liftedResources, value, liftedIsKnown, liftedIsSecret]) =>
liftInnerOutput(liftedResources, value, liftedIsKnown, liftedIsSecret),
);
this.resources = () => resourcesCopy;
this.allResources = () => lifted.then((l) => l.allResources);
this.isKnown = lifted.then((l) => l.isKnown);
this.isSecret = lifted.then((l) => l.isSecret);
this.promise = (withUnknowns?: boolean) =>
OutputImpl.getPromisedValue(
lifted.then((l) => l.value),
withUnknowns,
);
this.toString = () => {
let message = `Calling [toString] on an [Output<T>] is not supported.
To get the value of an Output<T> as an Output<string> consider either:
1: o.apply(v => \`prefix\${v}suffix\`)
2: pulumi.interpolate \`prefix\${v}suffix\`
See https://www.pulumi.com/docs/concepts/inputs-outputs for more details.`;
if (utils.errorOutputString) {
throw new Error(message);
}
message += `\nThis function may throw in a future version of @pulumi/pulumi.`;
return message;
};
this.toJSON = () => {
let message = `Calling [toJSON] on an [Output<T>] is not supported.
To get the value of an Output as a JSON value or JSON string consider either:
1: o.apply(v => v.toJSON())
2: o.apply(v => JSON.stringify(v))
See https://www.pulumi.com/docs/concepts/inputs-outputs for more details.`;
if (utils.errorOutputString) {
throw new Error(message);
}
message += `\nThis function may throw in a future version of @pulumi/pulumi.`;
return message;
};
return new Proxy(this, {
get: (obj, prop: keyof T) => {
// Recreate the prototype walk to ensure we find any actual members defined directly
// on `Output<T>`.
for (let o = obj; o; o = Object.getPrototypeOf(o)) {
if (o.hasOwnProperty(prop)) {
return (<any>o)[prop];
}
}
// Always explicitly fail on a member called 'then'. It is used by other systems to
// determine if this is a Promise, and we do not want to indicate that that's what
// we are.
if (prop === "then") {
return undefined;
}
// Do not lift members that start with __. Technically, if all libraries were
// using this version of pulumi/pulumi we would not need this. However, this is
// so that downstream consumers can use this version of pulumi/pulumi while also
// passing these new Outputs to older versions of pulumi/pulumi. The reason this
// can be a problem is that older versions do an RTTI check that simply asks questions
// like:
//
// Is there a member on this object called '__pulumiResource'
//
// If we automatically lift such a member (even if it eventually points to 'undefined'),
// then those RTTI checks will succeed.
//
// Note: this should be safe to not lift as, in general, properties with this prefix
// are not at all common (and in general are used to represent private things anyway
// that likely should not be exposed).
//
// Similarly, do not respond to the 'doNotCapture' member name. It serves a similar
// RTTI purpose.
if (typeof prop === "string") {
if (prop.startsWith("__") || prop === "doNotCapture" || prop === "deploymentOnlyModule") {
return undefined;
}
}
// Fail out if we are being accessed using a symbol. Many APIs will access with a
// well known symbol (like 'Symbol.toPrimitive') to check for the presence of something.
// They will only check for the existence of that member, and we don't want to make it
// appear that have those.
//
// Another way of putting this is that we only forward 'string/number' members to our
// underlying value.
if (typeof prop === "symbol") {
return undefined;
}
// Else for *any other* property lookup, succeed the lookup and return a lifted
// `apply` on the underlying `Output`.
return (<any>obj.apply)((ob: any) => {
if (ob === undefined || ob === null) {
return undefined;
} else if (isUnknown(ob)) {
// If the value of this output is unknown, the result of the access should also be unknown.
// This is conceptually consistent, and also prevents us from returning a "known undefined"
// value from the `ob[prop]` expression below.
return unknown;
}
return ob[prop];
}, /*runWithUnknowns:*/ true);
},
});
}
public get(): T {
throw new Error(`Cannot call '.get' during update or preview.
To manipulate the value of this Output, use '.apply' instead.`);
}
// runWithUnknowns requests that `func` is run even if `isKnown` resolves to `false`. This is used to allow
// callers to process fully- or partially-unknown values and return a known result. the output proxy takes
// advantage of this to allow proxied property accesses to return known values even if other properties of
// the containing object are unknown.
public apply<U>(func: (t: T) => Input<U>, runWithUnknowns?: boolean): Output<U> {
// we're inside the modern `output` code, so it's safe to call `.allResources!` here.
const applied = Promise.all([
this.allResources!(),
this.promise(/*withUnknowns*/ true),
this.isKnown,
this.isSecret,
]).then(([allResources, value, isKnown, isSecret]) =>
applyHelperAsync<T, U>(allResources, value, isKnown, isSecret, func, !!runWithUnknowns),
);
const result = new OutputImpl<U>(
this.resources(),
applied.then((a) => a.value),
applied.then((a) => a.isKnown),
applied.then((a) => a.isSecret),
applied.then((a) => a.allResources),
);
return <Output<U>>(<any>result);
}
}
/** @internal */
export function getAllResources<T>(op: OutputInstance<T>): Promise<Set<Resource>> {
return op.allResources instanceof Function ? op.allResources() : Promise.resolve(op.resources());
}
function copyResources(resources: Set<Resource> | Resource[] | Resource) {
const copy = Array.isArray(resources)
? new Set(resources)
: resources instanceof Set
? new Set(resources)
: new Set([resources]);
return copy;
}
async function liftInnerOutput(allResources: Set<Resource>, value: any, isKnown: boolean, isSecret: boolean) {
if (!Output.isInstance(value)) {
// 'value' itself wasn't an output, no need to transform any of the data we got.
return { allResources, value, isKnown, isSecret };
}
// 'value' was an Output. So we unwrap that to get the inner value/isKnown/isSecret/resources
// returned by that Output and merge with the state passed in to get the state of the final Output.
// Note: we intentionally await all the promises of the inner output. This way we properly
// propagate any rejections of any of these promises through the outer output as well.
const innerValue = await value.promise(/*withUnknowns*/ true);
const innerIsKnown = await value.isKnown;
const innerIsSecret = await (value.isSecret || Promise.resolve(false));
// If we're working with a new-style output, grab all its resources and merge into ours.
// Otherwise, if this is an old-style output, just grab the resources it was known to have
// at construction time.
const innerResources = await getAllResources(value);
const totalResources = utils.union(allResources, innerResources);
return {
allResources: totalResources,
value: innerValue,
isKnown: innerIsKnown,
isSecret: isSecret || innerIsSecret,
};
}
/* eslint-disable max-len */
async function applyHelperAsync<T, U>(
allResources: Set<Resource>,
value: T,
isKnown: boolean,
isSecret: boolean,
func: (t: T) => Input<U>,
runWithUnknowns: boolean,
) {
// Only perform the apply if the engine was able to give us an actual value
// for this Output.
const doApply = isKnown || runWithUnknowns;
if (!doApply) {
// We didn't actually run the function, our new Output is definitely **not** known.
return {
allResources,
value: <U>(<any>undefined),
isKnown: false,
isSecret,
};
}
// If we are running with unknown values and the value is explicitly unknown but does not actually
// contain any unknown values, collapse its value to the unknown value. This ensures that callbacks
// that expect to see unknowns during preview in outputs that are not known will always do so.
if (!isKnown && runWithUnknowns && !containsUnknowns(value)) {
value = <T>(<any>unknown);
}
const transformed = await func(value);
// We successfully ran the inner function. Our new Output should be considered known. We
// preserve secretness from our original Output to the new one we're creating.
return liftInnerOutput(allResources, transformed, /*isKnown*/ true, isSecret);
}
/**
* Returns a promise denoting if the output is a secret or not. This is not the same as just calling `.isSecret`
* because in cases where the output does not have a `isSecret` property and it is a Proxy, we need to ignore
* the isSecret member that the proxy reports back.
*
* This calls the public implementation so that we only make any calculations in a single place.
*
* @internal
*/
export function isSecretOutput<T>(o: Output<T>): Promise<boolean> {
return isSecret(o);
}
/**
* Helper function for `output`. This function trivially recurses through an object, copying it,
* while also lifting any inner Outputs (with all their respective state) to a top-level Output at
* the end. If there are no inner outputs, this will not affect the data (except by producing a new
* copy of it).
*
* Importantly:
*
* 1. Resources encountered while recursing are not touched. This helps ensure they stay Resources
* (with an appropriate prototype chain).
* 2. Primitive values (string, number, etc.) are returned as is.
* 3. Arrays and Record are recursed into. An Array<...> that contains any Outputs wil become an
* Output<Array<Unwrapped>>. A Record<string, ...> that contains any Output values will be an
* Output<Record<string, Unwrap<...>>. In both cases of recursion, the outer Output's
* known/secret/resources will be computed from the nested Outputs.
*/
function outputRec(val: any): any {
if (val === null || typeof val !== "object") {
// strings, numbers, booleans, functions, symbols, undefineds, nulls are all returned as
// themselves. They are always 'known' (i.e. we can safely 'apply' off of them even during
// preview).
return val;
} else if (Resource.isInstance(val)) {
// Don't unwrap Resources, there are existing codepaths that return Resources through
// Outputs and we want to preserve them as is when flattening.
return val;
} else if (isUnknown(val)) {
return val;
} else if (val instanceof Promise) {
// Recurse into the value the Promise points to. This may end up producing a
// Promise<Output>. Wrap this in another Output as the final result. This Output's
// construction will be able to merge the inner Output's data with its own. See
// liftInnerOutput for more details.
return createSimpleOutput(val.then((v) => outputRec(v)));
} else if (Output.isInstance(val)) {
// We create a new output here from the raw pieces of the original output in order to
// accommodate outputs from downlevel SxS SDKs. This ensures that within this package it is
// safe to assume the implementation of any Output returned by the `output` function.
//
// This includes:
// 1. that first-class unknowns are properly represented in the system: if this was a
// downlevel output where val.isKnown resolves to false, this guarantees that the
// returned output's promise resolves to unknown.
// 2. That the `isSecret` property is available.
// 3. That the `.allResources` is available.
const allResources = getAllResources(val);
const newOutput = new OutputImpl(
val.resources(),
val.promise(/*withUnknowns*/ true),
val.isKnown,
val.isSecret,
allResources,
);
return newOutput.apply(outputRec, /*runWithUnknowns*/ true);
} else if (val instanceof Array) {
const allValues = [];
let hasOutputs = false;
for (const v of val) {
const ev = outputRec(v);
allValues.push(ev);
if (Output.isInstance(ev)) {
hasOutputs = true;
}
}
// If we didn't encounter any nested Outputs, we don't need to do anything. We can just
// return this value as is.
if (!hasOutputs) {
// Note: we intentionally return 'allValues' here and not 'val'. This ensures we get a
// copy. This has been behavior we've had since the beginning and there may be subtle
// logic out there that depends on this that we would not want ot break.
return allValues;
}
// Otherwise, combine the data from all the outputs/non-outputs to one final output.
const promisedArray = Promise.all(allValues.map((v) => getAwaitableValue(v)));
const [syncResources, isKnown, isSecret, allResources] = getResourcesAndDetails(allValues);
return new Output(syncResources, promisedArray, isKnown, isSecret, allResources);
} else {
const promisedValues: { key: string; value: any }[] = [];
let hasOutputs = false;
for (const k of Object.keys(val)) {
const ev = outputRec(val[k]);
promisedValues.push({ key: k, value: ev });
if (Output.isInstance(ev)) {
hasOutputs = true;
}
}
if (!hasOutputs) {
// Note: we intentionally return a new value here and not 'val'. This ensures we get a
// copy. This has been behavior we've had since the beginning and there may be subtle
// logic out there that depends on this that we would not want ot break.
return promisedValues.reduce((o, kvp) => {
o[kvp.key] = kvp.value;
return o;
}, <any>{});
}
const promisedObject = getPromisedObject(promisedValues);
const [syncResources, isKnown, isSecret, allResources] = getResourcesAndDetails(
promisedValues.map((kvp) => kvp.value),
);
return new Output(syncResources, promisedObject, isKnown, isSecret, allResources);
}
}
/**
* [output] takes any Input value and converts it into an Output, deeply unwrapping nested Input
* values as necessary.
*
* The expected way to use this function is like so:
*
* ```ts
* var transformed = pulumi.output(someVal).apply(unwrapped => {
* // Do whatever you want now. 'unwrapped' will contain no outputs/promises inside
* // here, so you can easily do whatever sort of transformation is most convenient.
* });
*
* // the result can be passed to another Resource. The dependency information will be
* // properly maintained.
* var someResource = new SomeResource(name, { data: transformed ... });
* ```
*/
export function output<T>(val: Input<T>): Output<Unwrap<T>>;
export function output<T>(val: Input<T> | undefined): Output<Unwrap<T | undefined>>;
export function output<T>(val: Input<T | undefined>): Output<Unwrap<T | undefined>> {
const ov = outputRec(val);
return Output.isInstance<Unwrap<T>>(ov) ? ov : createSimpleOutput(ov);
}
/**
* [secret] behaves the same as [output] except the returned output is marked as containing sensitive data.
*/
export function secret<T>(val: Input<T>): Output<Unwrap<T>>;
export function secret<T>(val: Input<T> | undefined): Output<Unwrap<T | undefined>>;
export function secret<T>(val: Input<T | undefined>): Output<Unwrap<T | undefined>> {
const o = output(val);
// we called `output` right above this, so it's safe to call `.allResources` on the result.
return new Output(
o.resources(),
o.promise(/*withUnknowns*/ true),
o.isKnown,
Promise.resolve(true),
o.allResources!(),
);
}
/**
* [unsecret] behaves the same as [output] except the returned output takes the existing output and unwraps the secret
*/
export function unsecret<T>(val: Output<T>): Output<T> {
return new Output(
val.resources(),
val.promise(/*withUnknowns*/ true),
val.isKnown,
Promise.resolve(false),
val.allResources!(),
);
}
/**
* [isSecret] returns `true` if and only if the provided [Output] is a secret.
*/
export function isSecret<T>(val: Output<T>): Promise<boolean> {
return Output.isInstance(val.isSecret) ? Promise.resolve(false) : val.isSecret;
}
function createSimpleOutput(val: any) {
return new Output(
new Set(),
val instanceof Promise ? val : Promise.resolve(val),
/*isKnown*/ Promise.resolve(true),
/*isSecret */ Promise.resolve(false),
Promise.resolve(new Set()),
);
}
/**
* Allows for multiple Output objects to be combined into a single Output object. The single Output
* will depend on the union of Resources that the individual dependencies depend on.
*
* This can be used in the following manner:
*
* ```ts
* var d1: Output<string>;
* var d2: Output<number>;
*
* var d3: Output<ResultType> = Output.all([d1, d2]).apply(([s, n]) => ...);
* ```
*
* In this example, taking a dependency on d3 means a resource will depend on all the resources of
* d1 and d2.
*/
/* eslint-disable max-len */
export function all<T>(val: Record<string, Input<T>>): Output<Record<string, Unwrap<T>>>;
export function all<T1, T2, T3, T4, T5, T6, T7, T8>(
values: [Input<T1>, Input<T2>, Input<T3>, Input<T4>, Input<T5>, Input<T6>, Input<T7>, Input<T8>],
): Output<[Unwrap<T1>, Unwrap<T2>, Unwrap<T3>, Unwrap<T4>, Unwrap<T5>, Unwrap<T6>, Unwrap<T7>, Unwrap<T8>]>;
export function all<T1, T2, T3, T4, T5, T6, T7>(
values: [Input<T1>, Input<T2>, Input<T3>, Input<T4>, Input<T5>, Input<T6>, Input<T7>],
): Output<[Unwrap<T1>, Unwrap<T2>, Unwrap<T3>, Unwrap<T4>, Unwrap<T5>, Unwrap<T6>, Unwrap<T7>]>;
export function all<T1, T2, T3, T4, T5, T6>(
values: [Input<T1>, Input<T2>, Input<T3>, Input<T4>, Input<T5>, Input<T6>],
): Output<[Unwrap<T1>, Unwrap<T2>, Unwrap<T3>, Unwrap<T4>, Unwrap<T5>, Unwrap<T6>]>;
export function all<T1, T2, T3, T4, T5>(
values: [Input<T1>, Input<T2>, Input<T3>, Input<T4>, Input<T5>],
): Output<[Unwrap<T1>, Unwrap<T2>, Unwrap<T3>, Unwrap<T4>, Unwrap<T5>]>;
export function all<T1, T2, T3, T4>(
values: [Input<T1>, Input<T2>, Input<T3>, Input<T4>],
): Output<[Unwrap<T1>, Unwrap<T2>, Unwrap<T3>, Unwrap<T4>]>;
export function all<T1, T2, T3>(
values: [Input<T1>, Input<T2>, Input<T3>],
): Output<[Unwrap<T1>, Unwrap<T2>, Unwrap<T3>]>;
export function all<T1, T2>(values: [Input<T1>, Input<T2>]): Output<[Unwrap<T1>, Unwrap<T2>]>;
export function all<T>(ds: Input<T>[]): Output<Unwrap<T>[]>;
export function all<T>(val: Input<T>[] | Record<string, Input<T>>): Output<any> {
// Our recursive `output` helper already does exactly what `all` needs to do in terms of the
// implementation. Why have both `output` and `all` then? Currently, to the best of our
// abilities, we haven't been able to make a single signature for both that can unify tuples and
// arrays for TypeScript. So `all` is much better when dealing with a tuple of heterogenous
// values, while `output` is good for everything else.
//
// Specifically ``all` can take an `[Output<string>, Output<number>]` and produce an
// `Output<[string, number]>` However, `output` for that same type will produce an
// `Output<(string|number)[]>` which is definitely suboptimal.
return output(val);
}
function getAwaitableValue(v: any): any {
if (Output.isInstance(v)) {
return v.promise(/* withUnknowns */ true);
} else {
return v;
}
}
async function getPromisedObject<T>(keysAndOutputs: { key: string; value: any }[]): Promise<Record<string, Unwrap<T>>> {
const result: Record<string, Unwrap<T>> = {};
for (const kvp of keysAndOutputs) {
result[kvp.key] = await getAwaitableValue(kvp.value);
}
return result;
}
function getResourcesAndDetails(
allValues: any[],
): [Set<Resource>, Promise<boolean>, Promise<boolean>, Promise<Set<Resource>>] {
const syncResources = new Set<Resource>();
const allOutputs = [];
for (const v of allValues) {
if (Output.isInstance(v)) {
allOutputs.push(v);
for (const res of v.resources()) {
syncResources.add(res);
}
}
}
// All the outputs were generated in `function all` using `output(v)`. So it's safe
// to call `.allResources!` here.
const allResources = Promise.all(allOutputs.map((o) => o.allResources!())).then((arr) => {
const result = new Set<Resource>();
for (const set of arr) {
for (const res of set) {
result.add(res);
}
}
return result;
});
// A merged output is known if all of its inputs are known.
const isKnown = Promise.all(allOutputs.map((o) => o.isKnown)).then((ps) => ps.every((b) => b));
// A merged output is secret if any of its inputs are secret.
const isSecret = Promise.all(allOutputs.map((o) => isSecretOutput(o))).then((ps) => ps.some((b) => b));
return [syncResources, isKnown, isSecret, allResources];
}
/**
* Unknown represents a value that is unknown. These values correspond to unknown property values received from the
* Pulumi engine as part of the result of a resource registration (see runtime/rpc.ts). User code is not typically
* exposed to these values: any Output<> that contains an Unknown will itself be unknown, so any user callbacks
* passed to `apply` will not be run. Internal callers of `apply` can request that they are run even with unknown
* values; the output proxy takes advantage of this to allow proxied property accesses to return known values even
* if other properties of the containing object are unknown.
*/
class Unknown {
/**
* A private field to help with RTTI that works in SxS scenarios.
*
* This is internal instead of being truly private, to support mixins and our serialization model.
* @internal
*/
// eslint-disable-next-line @typescript-eslint/naming-convention,no-underscore-dangle,id-blacklist,id-match
public readonly __pulumiUnknown: boolean = true;
/**
* Returns true if the given object is an instance of Unknown. This is designed to work even when
* multiple copies of the Pulumi SDK have been loaded into the same process.
*/
public static isInstance(obj: any): obj is Unknown {
return utils.isInstance<Unknown>(obj, "__pulumiUnknown");
}
}
/**
* unknown is the singleton unknown value.
* @internal
*/
export const unknown = new Unknown();
/**
* isUnknown returns true if the given value is unknown.
*/
export function isUnknown(val: any): boolean {
return Unknown.isInstance(val);
}
/**
* containsUnknowns returns true if the given value is or contains unknown values.
*/
export function containsUnknowns(value: any): boolean {
return impl(value, new Set<any>());
function impl(val: any, seen: Set<any>): boolean {
if (val === null || typeof val !== "object") {
return false;
} else if (isUnknown(val)) {
return true;
} else if (seen.has(val)) {
return false;
}
seen.add(val);
if (val instanceof Array) {
return val.some((e) => impl(e, seen));
} else {
return Object.keys(val).some((k) => impl(val[k], seen));
}
}
}
/**
* [Input] is a property input for a resource. It may be a promptly available T, a promise for one,
* or the output from a existing Resource.
*/
// Note: we accept an OutputInstance (and not an Output) here to be *more* flexible in terms of
// what an Input is. OutputInstance has *less* members than Output (because it doesn't lift anything).
export type Input<T> = T | Promise<T> | OutputInstance<T>;
/**
* [Inputs] is a map of property name to property input, one for each resource property value.
*/
export type Inputs = Record<string, Input<any>>;
/**
* The 'Unwrap' type allows us to express the operation of taking a type, with potentially deeply
* nested Promises and Outputs and to then get that same type with all the Promises and Outputs
* replaced with their wrapped type. Note that this Unwrapping is 'deep'. So if you had:
*
* `type X = { A: Promise<{ B: Output<{ c: Input<boolean> }> }> }`
*
* Then `Unwrap<X>` would be equivalent to:
*
* `... = { A: { B: { C: boolean } } }`
*
* Unwrapping sees through Promises, Outputs, Arrays and Objects.
*
* Note: due to TypeScript limitations there are some things that cannot be expressed. Specifically,
* if you had a `Promise<Output<T>>` then the Unwrap type would not be able to undo both of those
* wraps. In practice that should be ok. Values in an object graph should not wrap Outputs in
* Promises. Instead, any code that needs to work Outputs and also be async should either create
* the Output with the Promise (which will collapse into just an Output). Or, it should start with
* an Output and call [apply] on it, passing in an async function. This will also collapse and just
* produce an Output.
*
* In other words, this should not be used as the shape of an object: `{ a: Promise<Output<...>> }`.
* It should always either be `{ a: Promise<NonOutput> }` or just `{ a: Output<...> }`.
*/
export type Unwrap<T> =
// 1. If we have a promise, just get the type it itself is wrapping and recursively unwrap that.
// 2. Otherwise, if we have an output, do the same as a promise and just unwrap the inner type.
// 3. Otherwise, we have a basic type. Just unwrap that.
T extends Promise<infer U1>
? UnwrapSimple<U1>
: T extends OutputInstance<infer U2>
? UnwrapSimple<U2>
: UnwrapSimple<T>;
type primitive = Function | string | number | boolean | undefined | null;
/**
* Handles encountering basic types when unwrapping.
*/
export type UnwrapSimple<T> =
// 1. Any of the primitive types just unwrap to themselves.
// 2. An array of some types unwraps to an array of that type itself unwrapped. Note, due to a
// TS limitation we cannot express that as Array<Unwrap<U>> due to how it handles recursive
// types. We work around that by introducing an structurally equivalent interface that then
// helps make typescript defer type-evaluation instead of doing it eagerly.
// 3. An object unwraps to an object with properties of the same name, but where the property
// types have been unwrapped.
// 4. return 'never' at the end so that if we've missed something we'll discover it.
T extends primitive
? T
: T extends Resource
? T
: T extends Array<infer U>
? UnwrappedArray<U>
: T extends object
? UnwrappedObject<T>
: never;
export type UnwrappedArray<T> = Array<Unwrap<T>>;
export type UnwrappedObject<T> = {
[P in keyof T]: Unwrap<T[P]>;
};
/**
* Instance side of the [Output<T>] type. Exposes the deployment-time and run-time mechanisms
* for working with the underlying value of an [Output<T>].
*/
export interface OutputInstance<T> {
/** @internal */ allResources?: () => Promise<Set<Resource>>;
/** @internal */ readonly isKnown: Promise<boolean>;
/** @internal */ readonly isSecret: Promise<boolean>;
/** @internal */ promise(withUnknowns?: boolean): Promise<T>;
/** @internal */ resources(): Set<Resource>;
/**
* Transforms the data of the output with the provided func. The result remains a
* Output so that dependent resources can be properly tracked.
*
* 'func' is not allowed to make resources.
*
* 'func' can return other Outputs. This can be handy if you have a Output<SomeVal>
* and you want to get a transitive dependency of it. i.e.
*
* ```ts
* var d1: Output<SomeVal>;
* var d2 = d1.apply(v => v.x.y.OtherOutput); // getting an output off of 'v'.
* ```
*
* In this example, taking a dependency on d2 means a resource will depend on all the resources
* of d1. It will *also* depend on the resources of v.x.y.OtherDep.
*
* Importantly, the Resources that d2 feels like it will depend on are the same resources as d1.
* If you need have multiple Outputs and a single Output is needed that combines both
* set of resources, then 'pulumi.all' should be used instead.
*
* This function will be called execution of a 'pulumi up' or 'pulumi preview' request, but it
* will ont run when the values of the output are unknown. It is not
* available for functions that end up executing in the cloud during runtime. To get the value
* of the Output during cloud runtime execution, use `get()`.
*/
apply<U>(func: (t: T) => Promise<U>): Output<U>;
apply<U>(func: (t: T) => OutputInstance<U>): Output<U>;
apply<U>(func: (t: T) => U): Output<U>;
/**
* Retrieves the underlying value of this dependency.
*
* This function is only callable in code that runs in the cloud post-deployment. At this
* point all Output values will be known and can be safely retrieved. During pulumi deployment
* or preview execution this must not be called (and will throw). This is because doing so
* would allow Output values to flow into Resources while losing the data that would allow
* the dependency graph to be changed.
*/
get(): T;
}
/**
* Static side of the [Output<T>] type. Can be used to [create] Outputs as well as test
* arbitrary values to see if they are [Output]s.
*/
export interface OutputConstructor {
create<T>(val: Input<T>): Output<Unwrap<T>>;
create<T>(val: Input<T> | undefined): Output<Unwrap<T | undefined>>;
isInstance<T>(obj: any): obj is Output<T>;
/** @internal */ new <T>(
resources: Set<Resource> | Resource[] | Resource,
promise: Promise<T>,
isKnown: Promise<boolean>,
isSecret: Promise<boolean>,
allResources: Promise<Set<Resource> | Resource[] | Resource>,
): Output<T>;
}
/**
* [Output] helps encode the relationship between Resources in a Pulumi application. Specifically an
* [Output] holds onto a piece of Data and the Resource it was generated from. An [Output] value can
* then be provided when constructing new Resources, allowing that new Resource to know both the
* value as well as the Resource the value came from. This allows for a precise 'Resource
* dependency graph' to be created, which properly tracks the relationship between resources.
*
* An [Output] is used in a Pulumi program differently depending on if the application is executing
* at 'deployment time' (i.e. when actually running the 'pulumi' executable), or at 'run time' (i.e.
* a piece of code running in some Cloud).
*
* At 'deployment time', the correct way to work with the underlying value is to call
* [Output.apply(func)]. This allows the value to be accessed and manipulated, while still
* resulting in an [Output] that is keeping track of [Resource]s appropriately. At deployment time
* the underlying value may or may not exist (for example, if a preview is being performed). In
* this case, the 'func' callback will not be executed, and calling [.apply] will immediately return
* an [Output] that points to the [undefined] value. During a normal [update] though, the 'func'
* callbacks should always be executed.
*
* At 'run time', the correct way to work with the underlying value is to simply call [Output.get]
* which will be promptly return the entire value. This will be a simple JavaScript object that can
* be manipulated as necessary.
*
* To ease with using [Output]s at 'deployment time', pulumi will 'lift' simple data properties of
* an underlying value to the [Output] itself. For example:
*
* ```ts
* const o: Output<{ name: string, age: number, orders: Order[] }> = ...;
* const name : Output<string> = o.name;
* const age : Output<number> = o.age;
* const first: Output<Order> = o.orders[0];
* ```
*
* Instead of having to write:
*
* ```ts
* const o: Output<{ name: string, age: number, orders: Order[] }> = ...;
* const name : Output<string> = o.apply(v => v.name);
* const age : Output<number> = o.apply(v => v.age);
* const first: Output<Order> = o.apply(v => v.orders[0]);
* ```
*/
export type Output<T> = OutputInstance<T> & Lifted<T>;
// eslint-disable-next-line @typescript-eslint/naming-convention,@typescript-eslint/no-redeclare,no-underscore-dangle,id-blacklist,id-match
export const Output: OutputConstructor = <any>OutputImpl;
/**
* The [Lifted] type allows us to express the operation of taking a type, with potentially deeply
* nested objects and arrays and to then get a type with the same properties, except whose property
* types are now [Output]s of the original property type.
*
* For example:
*
*
* `type X = { A: string, B: { c: boolean } }`
*
* Then `Lifted<X>` would be equivalent to:
*
* `... = { A: Output<string>, B: Output<{ C: Output<boolean> }> }`
*
* [Lifted] is somewhat the opposite of [Unwrap]. It's primary purpose is to allow an instance of
* [Output<SomeType>] to provide simple access to the properties of [SomeType] directly on the instance
* itself (instead of haveing to use [.apply]).
*
* This lifting only happens through simple pojo objects and arrays. Functions, for example, are not
* lifted. So you cannot do:
*
* ```ts
* const o: Output<string> = ...;
* const c: Output<number> = o.charCodeAt(0);
* ```
*
* Instead, you still need to write;
*
* ```ts
* const o: Output<string> = ...;
* const c: Output<number> = o.apply(v => v.charCodeAt(0));
* ```
*/
export type Lifted<T> =
// Specially handle 'string' since TS doesn't map the 'String.Length' property to it.
T extends string
? LiftedObject<String, NonFunctionPropertyNames<String>>
: T extends Array<infer U>
? LiftedArray<U>
: T extends object
? LiftedObject<T, NonFunctionPropertyNames<T>>
: // fallback to lifting no properties. Note that `Lifted` is used in
// Output<T> = OutputInstance<T> & Lifted<T>
// so returning an empty object just means that we're adding nothing to Output<T>.
// This is needed for cases like `Output<any>`.
{};
// The set of property names in T that are *not* functions.
type NonFunctionPropertyNames<T> = {
[K in keyof T]: T[K] extends Function ? never : K;
}[keyof T];
// Lift up all the non-function properties. If it was optional before, keep it optional after.
// If it's require before, keep it required afterwards.
export type LiftedObject<T, K extends keyof T> = {
[P in K]: T[P] extends OutputInstance<infer T1>
? Output<T1>
: T[P] extends Promise<infer T2>
? Output<T2>
: Output<T[P]>;
};
export type LiftedArray<T> = {
/**
* Gets the length of the array. This is a number one higher than the highest element defined
* in an array.
*/
readonly length: Output<number>;
readonly [n: number]: Output<T>;
};
/**
* [concat] takes a sequence of [Inputs], stringifies each, and concatenates all values into one
* final string. Individual inputs can be any sort of [Input] value. i.e. they can be [Promise]s,
* [Output]s, or just plain JavaScript values. This can be used like so:
*
* ```ts
* // 'server' and 'loadBalancer' are both resources that expose [Output] properties.
* let val: Output<string> = pulumi.concat("http://", server.hostname, ":", loadBalancer.port);
* ```
*
*/
export function concat(...params: Input<any>[]): Output<string> {
return output(params).apply((array) => array.join(""));
}
/**
* [interpolate] is similar to [concat] but is designed to be used as a tagged template expression.
* i.e.:
*
* ```ts
* // 'server' and 'loadBalancer' are both resources that expose [Output] properties.
* let val: Output<string> = pulumi.interpolate `http://${server.hostname}:${loadBalancer.port}`
* ```
*
* As with [concat] the 'placeholders' between `${}` can be any Inputs. i.e. they can be
* [Promise]s, [Output]s, or just plain JavaScript values.
*/
export function interpolate(literals: TemplateStringsArray, ...placeholders: Input<any>[]): Output<string> {
return output(placeholders).apply((unwrapped) => {
let result = "";
// interleave the literals with the placeholders
for (let i = 0; i < unwrapped.length; i++) {
result += literals[i];
result += unwrapped[i];
}
// add the last literal
result += literals[literals.length - 1];
return result;
});
}
/**
* [jsonStringify] Uses JSON.stringify to serialize the given Input value into a JSON string.
*/
export function jsonStringify(
obj: Input<any>,
replacer?: (this: any, key: string, value: any) => any | (number | string)[],
space?: string | number,
): Output<string> {
return output(obj).apply((o) => {
return JSON.stringify(o, replacer, space);
});
}
/**
* [jsonParse] Uses JSON.parse to deserialize the given Input JSON string into a value.
*/
export function jsonParse(text: Input<string>, reviver?: (this: any, key: string, value: any) => any): Output<any> {
return output(text).apply((t) => {
return JSON.parse(t, reviver);
});
}
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