gristlabs_grist-core/app/server/lib/DocSnapshots.ts

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import {ObjSnapshotWithMetadata} from 'app/common/DocSnapshot';
import {SnapshotWindow} from 'app/common/Features';
import {KeyedMutex} from 'app/common/KeyedMutex';
import {KeyedOps} from 'app/common/KeyedOps';
import {ExternalStorage} from 'app/server/lib/ExternalStorage';
import * as log from 'app/server/lib/log';
import * as fse from 'fs-extra';
import * as moment from 'moment-timezone';
/**
* A subset of the ExternalStorage interface, focusing on maintaining a list of versions.
*/
export interface IInventory {
getSnapshotWindow?: (key: string) => Promise<SnapshotWindow|undefined>;
versions(key: string): Promise<ObjSnapshotWithMetadata[]>;
remove(key: string, snapshotIds: string[]): Promise<void>;
}
/**
* A utility for pruning snapshots, so the number of snapshots doesn't get out of hand.
*/
export class DocSnapshotPruner {
private _closing: boolean = false; // when set, should ignore prune requests
private _prunes: KeyedOps;
// Specify store to be pruned, and delay before pruning.
constructor(private _ext: IInventory, _options: {
delayBeforeOperationMs?: number,
minDelayBetweenOperationsMs?: number
} = {}) {
this._prunes = new KeyedOps((key) => this.prune(key), {
..._options,
retry: false,
logError: (key, failureCount, err) => log.error(`Pruning document ${key} gave error ${err}`)
});
}
// Shut down. Prunes scheduled for the future are run immediately.
// Can be called repeated safely.
public async close() {
this._closing = true;
this._prunes.expediteOperations();
await this.wait();
}
// Wait for all in-progress prunes to finish up in an orderly fashion.
public async wait() {
await this._prunes.wait(() => 'waiting for pruning to finish');
}
// Note that a document has changed, and should be pruned (or repruned). Pruning operation
// done as a background operation. Returns true if a pruning operation has been scheduled.
public requestPrune(key: string): boolean {
// If closing down, do not accept any prune requests.
if (!this._closing) {
// Mark the key as needing work.
this._prunes.addOperation(key);
}
return this._prunes.hasPendingOperation(key);
}
// Get all snapshots for a document, and whether they should be kept or pruned.
public async classify(key: string): Promise<Array<{snapshot: ObjSnapshotWithMetadata, keep: boolean}>> {
const snapshotWindow = await this._ext.getSnapshotWindow?.(key);
const versions = await this._ext.versions(key);
return shouldKeepSnapshots(versions, snapshotWindow).map((keep, index) => ({keep, snapshot: versions[index]}));
}
// Prune the specified document immediately. If no snapshotIds are provided, they
// will be chosen automatically.
public async prune(key: string, snapshotIds?: string[]) {
if (!snapshotIds) {
const versions = await this.classify(key);
const redundant = versions.filter(v => !v.keep);
snapshotIds = redundant.map(r => r.snapshot.snapshotId);
await this._ext.remove(key, snapshotIds);
log.info(`Pruned ${snapshotIds.length} versions of ${versions.length} for document ${key}`);
} else {
await this._ext.remove(key, snapshotIds);
log.info(`Pruned ${snapshotIds.length} externally selected versions for document ${key}`);
}
}
}
/**
* Maintain a list of document versions, with metadata, so we can query versions and
* make sensible pruning decisions without needing to HEAD each version (in the
* steady state).
*
* The list of versions (with metadata) for a document is itself stored in S3. This isn't
2022-02-19 09:46:49 +00:00
* ideal since we cannot simply append a new version to the list without rewriting it in full.
* But the alternatives have more serious problems, and this way folds quite well into the
* existing pruning setup.
* - Storing in db would mean we'd need sharding sooner than otherwise
* - Storing in redis would similarly make this the dominant load driving redis
* - Storing in dynamodb would create more operational work
* - Using S3 metadata alone would be too slow
* - Using S3 tags could do some of what we want, but tags have serious limits
*
* Operations related to a particular document are serialized for clarity.
*
* The inventory is cached on the local file system, since we reuse the ExternalStorage
* interface which is file based.
*/
export class DocSnapshotInventory implements IInventory {
private _needFlush = new Set<string>();
private _mutex = new KeyedMutex();
/**
* Expects to be given the store for documents, a store for metadata, and a method
* for naming cache files on the local filesystem. The stores should be consistent.
*/
constructor(
private _doc: ExternalStorage,
private _meta: ExternalStorage,
private _getFilename: (key: string) => Promise<string>,
public getSnapshotWindow: (key: string) => Promise<SnapshotWindow|undefined>,
) {}
/**
* Start keeping inventory for a new document.
*/
public async create(key: string) {
await this._mutex.runExclusive(key, async() => {
const fname = await this._getFilename(key);
await this._saveToFile(fname, []);
this._needFlush.add(key);
});
}
/**
* Return true if document inventory does not need to be saved and is not in flux.
*/
public isSaved(key: string) {
return !this._needFlush.has(key) && !this._mutex.isLocked(key);
}
/**
* Add a new snapshot of a document to the existing inventory. A prevSnapshotId may
* be supplied as a cross-check. It will be matched against the most recent
* snapshotId in the inventory, and if it doesn't match the inventory will be
* recreated.
*
* The inventory is not automatically flushed to S3. Call flush() to do that,
* or ask DocSnapshotPrune.requestPrune() to prune the document - it will flush
* after pruning.
*
* The snapshot supplied will be modified in place to a normalized form.
*/
public async add(key: string, snapshot: ObjSnapshotWithMetadata, prevSnapshotId: string|null) {
await this._mutex.runExclusive(key, async() => {
const snapshots = await this._getSnapshots(key, prevSnapshotId);
// Could be already added if reconstruction happened.
if (snapshots[0] && snapshots[0].snapshotId === snapshot.snapshotId) { return; }
this._normalizeMetadata(snapshot);
snapshots.unshift(snapshot);
const fname = await this._getFilename(key);
await this._saveToFile(fname, snapshots);
// We don't write to s3 yet, but do mark the list as dirty.
this._needFlush.add(key);
});
}
/**
* Make sure the latest state of the inventory is stored in S3.
*/
public async flush(key: string) {
await this._mutex.runExclusive(key, async() => {
await this._flush(key);
});
}
/**
* Wipe local cached state of the inventory.
*/
public async clear(key: string) {
await this._mutex.runExclusive(key, async() => {
await this._flush(key);
const fname = await this._getFilename(key);
// NOTE: fse.remove succeeds also when the file does not exist.
await fse.remove(fname);
});
}
/**
* Remove a set of snapshots from the inventory, and then flush to S3.
*/
public async remove(key: string, snapshotIds: string[]) {
await this._mutex.runExclusive(key, async() => {
const current = await this._getSnapshots(key, null);
const oldIds = new Set(snapshotIds);
if (oldIds.size > 0) {
const results = current.filter(v => !oldIds.has(v.snapshotId));
const fname = await this._getFilename(key);
await this._doc.remove(key, snapshotIds);
await this._saveToFile(fname, results);
this._needFlush.add(key);
}
await this._flush(key);
});
}
/**
* Read the cached version of the inventory if available, otherwise fetch
* it from S3. If expectSnapshotId is set, the cached version is ignored if
* the most recent version listed is not the expected one.
*/
public async versions(key: string, expectSnapshotId?: string|null): Promise<ObjSnapshotWithMetadata[]> {
return this._mutex.runExclusive(key, async() => {
return await this._getSnapshots(key, expectSnapshotId || null);
});
}
// Do whatever it takes to get an inventory of versions.
// Most recent versions returned first.
private async _getSnapshots(key: string, expectSnapshotId: string|null): Promise<ObjSnapshotWithMetadata[]> {
// Check if we have something useful cached on the local filesystem.
const fname = await this._getFilename(key);
let data = await this._loadFromFile(fname);
if (data && expectSnapshotId && data[0]?.snapshotId !== expectSnapshotId) {
data = null;
}
// If nothing yet, check if we have something useful in s3.
if (!data && await this._meta.exists(key)) {
await fse.remove(fname);
await this._meta.download(key, fname);
data = await this._loadFromFile(fname);
if (data && expectSnapshotId && data[0]?.snapshotId !== expectSnapshotId) {
data = null;
}
}
if (!data) {
// No joy, all we can do is reconstruct from individual s3 version HEAD metadata.
data = await this._reconstruct(key);
if (data) {
if (expectSnapshotId && data[0]?.snapshotId !== expectSnapshotId) {
// Surprising, since S3 ExternalInterface should have its own consistency
// checks. Not much we can do about it other than accept it.
log.error(`Surprise in getSnapshots, expected ${expectSnapshotId} for ${key} ` +
`but got ${data[0]?.snapshotId}`);
}
// Reconstructed data is precious. Make sure it gets saved.
await this._saveToFile(fname, data);
this._needFlush.add(key);
}
}
return data;
}
// Load inventory from local file system, if available.
private async _loadFromFile(fname: string): Promise<ObjSnapshotWithMetadata[]|null> {
try {
if (await fse.pathExists(fname)) {
return JSON.parse(await fse.readFile(fname, 'utf8'));
}
return null;
} catch (e) {
return null;
}
}
// Save inventory to local file system.
private async _saveToFile(fname: string, data: ObjSnapshotWithMetadata[]) {
await fse.outputFile(fname, JSON.stringify(data, null, 2), 'utf8');
}
// This is a relatively expensive operation, calling the S3 api for every stored
// version of a document. In the steady state, we should rarely need to do this.
private async _reconstruct(key: string): Promise<ObjSnapshotWithMetadata[]> {
const snapshots = await this._doc.versions(key);
if (snapshots.length > 1) {
log.info(`Reconstructing history of ${key} (${snapshots.length} versions)`);
}
const results: ObjSnapshotWithMetadata[] = [];
for (const snapshot of snapshots) {
const head = await this._doc.head(key, snapshot.snapshotId);
if (head) {
this._normalizeMetadata(head);
results.push(head);
} else {
log.debug(`When reconstructing history of ${key}, did not find ${snapshot.snapshotId}`);
}
}
return results;
}
// Flush inventory to S3.
private async _flush(key: string) {
if (this._needFlush.has(key)) {
const fname = await this._getFilename(key);
await this._meta.upload(key, fname);
this._needFlush.delete(key);
}
}
// Normalize metadata. We store a timestamp that is distinct from the S3 timestamp,
// recording when the file was changed by Grist.
// TODO: deal with possibility of this creating trouble with pruning if the local time is
// sufficiently wrong.
private _normalizeMetadata(snapshot: ObjSnapshotWithMetadata) {
if (snapshot?.metadata?.t) {
snapshot.lastModified = snapshot.metadata.t;
delete snapshot.metadata.t;
}
}
}
/**
* Calculate which snapshots to keep. Expects most recent snapshots to be first.
* We keep:
* - The five most recent versions (including the current version)
* - The most recent version in every hour, for up to 25 distinct hours
* - The most recent version in every day, for up to 32 distinct days
* - The most recent version in every week, for up to 12 distinct weeks
* - The most recent version in every month, for up to 36 distinct months
* - The most recent version in every year, for up to 1000 distinct years
* - Anything with a label, for up to 32 days before the current version.
* Calculations done in UTC, Gregorian calendar, ISO weeks (week starts with Monday).
*/
export function shouldKeepSnapshots(snapshots: ObjSnapshotWithMetadata[], snapshotWindow?: SnapshotWindow): boolean[] {
// Get current version
const current = snapshots[0];
if (!current) { return []; }
const tz = current.metadata?.tz || 'UTC';
// Get time of current version
const start = moment.tz(current.lastModified, tz);
// Track saved version per hour, day, week, month, year, and number of times a version
// has been saved based on a corresponding rule.
const buckets: TimeBucket[] = [
{range: 'hour', prev: start, usage: 0, cap: 25},
{range: 'day', prev: start, usage: 0, cap: 32},
{range: 'isoWeek', prev: start, usage: 0, cap: 12},
{range: 'month', prev: start, usage: 0, cap: 36},
{range: 'year', prev: start, usage: 0, cap: 1000}
];
// For each snapshot starting with newest, check if it is worth saving by comparing
// it with the last saved snapshot based on hour, day, week, month, year
return snapshots.map((snapshot, index) => {
// Just to make extra sure we don't delete everything
if (index === 0) {
return true;
}
const date = moment.tz(snapshot.lastModified, tz);
// Limit snapshots to the given window corresponding to what the user has paid for
if (snapshotWindow && start.diff(date, snapshotWindow.unit, true) > snapshotWindow.count) {
return false;
}
let keep = index < 5; // Keep 5 most recent versions
for (const bucket of buckets) {
if (updateAndCheckRange(date, bucket)) { keep = true; }
}
// Preserve recent labelled snapshots in a naive and limited way. No doubt this will
// be elaborated on if we make this a user-facing feature.
if (snapshot.metadata?.label &&
start.diff(date, 'days') < 32) { keep = true; }
return keep;
});
}
/**
* Check whether time `t` is in the same time-bucket as the time
* stored in `prev` for that time-bucket, and the time-bucket has not
* been used to its limit to justify saving versions.
*
* If all is good, we return true, store `t` in the appropriate
* time-bucket in `prev`, and increment the usage count. Note keeping
* a single version can increment usage on several buckets. This is
* easy to change, but other variations have results that feel
* counter-intuitive.
*/
function updateAndCheckRange(t: moment.Moment, bucket: TimeBucket) {
if (bucket.usage < bucket.cap && !t.isSame(bucket.prev, bucket.range)) {
bucket.prev = t;
bucket.usage++;
return true;
}
return false;
}
interface TimeBucket {
range: 'hour' | 'day' | 'isoWeek' | 'month' | 'year',
prev: moment.Moment; // last time stored in this bucket
usage: number; // number of times this bucket justified saving a snapshot
cap: number; // maximum number of usages permitted
}