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gristlabs_grist-core/app/client/components/SelectionSummary.ts

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import {CellSelector, COL, ROW} from 'app/client/components/CellSelector';
import {copyToClipboard} from 'app/client/lib/copyToClipboard';
import {Delay} from "app/client/lib/Delay";
import {KoArray} from 'app/client/lib/koArray';
import {ViewFieldRec} from 'app/client/models/entities/ViewFieldRec';
import {UserError} from 'app/client/models/errors';
import {ALL, RowsChanged, SortedRowSet} from "app/client/models/rowset";
import {showTransientTooltip} from 'app/client/ui/tooltips';
import {colors, isNarrowScreen, isNarrowScreenObs, theme, vars} from 'app/client/ui2018/cssVars';
import {icon} from 'app/client/ui2018/icons';
import {CellValue} from 'app/common/DocActions';
import {isEmptyList, isListType, isRefListType} from "app/common/gristTypes";
import {TableData} from "app/common/TableData";
import {BaseFormatter} from 'app/common/ValueFormatter';
import ko from 'knockout';
import {Computed, Disposable, dom, makeTestId, Observable, styled, subscribe} from 'grainjs';
import {makeT} from 'app/client/lib/localization';
const t = makeT('components.SelectionSummary');
/**
* A beginning and end index for a range of columns or rows.
*/
interface Range {
begin: number;
end: number;
}
/**
* A single part of the cell selection summary.
*/
interface SummaryPart {
/** Identifier for the summary part. */
id: 'sum' | 'count' | 'dimensions';
/** Label that's shown to the left of `value`. */
label: string;
/** Value of the summary part. */
value: string;
/** If true, displays a copy button on hover. Defaults to false. */
clickToCopy?: boolean;
}
const testId = makeTestId('test-selection-summary-');
// We can handle a million cells in under 60ms on a good laptop. Much beyond that, and we'll break
// selection with the bad performance. Instead, skip the counting and summing for too many cells.
const MAX_CELLS_TO_SCAN = 1_000_000;
export class SelectionSummary extends Disposable {
private _colTotalCount = Computed.create(this, (use) =>
use(use(this._viewFields).getObservable()).length);
private _rowTotalCount = Computed.create(this, (use) => {
const rowIds = use(this._sortedRows.getKoArray().getObservable());
const includesNewRow = (rowIds.length > 0 && rowIds[rowIds.length - 1] === 'new');
return rowIds.length - (includesNewRow ? 1 : 0);
});
// In CellSelector, start and end are 0-based, inclusive, and not necessarily in order.
// It's not good for representing an empty range. Here, we convert ranges as [begin, end),
// with end >= begin.
private _rowRange = Computed.create<Range>(this, (use) => {
const type = use(this._cellSelector.currentSelectType);
if (type === COL) {
return {begin: 0, end: use(this._rowTotalCount)};
} else {
const start = use(this._cellSelector.row.start);
const end = use(this._cellSelector.row.end);
return {
begin: Math.min(start, end),
end: Math.max(start, end) + 1,
};
}
});
private _colRange = Computed.create<Range>(this, (use) => {
const type = use(this._cellSelector.currentSelectType);
if (type === ROW) {
return {begin: 0, end: use(this._colTotalCount)};
} else {
const start = use(this._cellSelector.col.start);
const end = use(this._cellSelector.col.end);
return {
begin: Math.min(start, end),
end: Math.max(start, end) + 1,
};
}
});
private _summary = Observable.create<SummaryPart[]>(this, []);
private _delayedRecalc = this.autoDispose(Delay.create());
constructor(
private _cellSelector: CellSelector,
private _tableData: TableData,
private _sortedRows: SortedRowSet,
private _viewFields: ko.Computed<KoArray<ViewFieldRec>>,
) {
super();
this.autoDispose(this._sortedRows.getKoArray().subscribe(this._onSpliceChange, this, 'spliceChange'));
const onRowNotify = this._onRowNotify.bind(this);
this._sortedRows.on('rowNotify', onRowNotify);
this.onDispose(() => this._sortedRows.off('rowNotify', onRowNotify));
this.autoDispose(subscribe(this._rowRange, this._colRange,
() => this._scheduleRecalc()));
this.autoDispose(isNarrowScreenObs().addListener((isNarrow) => {
if (isNarrow) { return; }
// No calculations occur while the screen is narrow, so we need to schedule one.
this._scheduleRecalc();
}));
}
public buildDom() {
return cssSummary(
dom.forEach(this._summary, ({id, label, value, clickToCopy}) =>
cssSummaryPart(
label ? dom('span', cssLabelText(label), cssCopyIcon('Copy')) : null,
value,
cssSummaryPart.cls('-copyable', Boolean(clickToCopy)),
(clickToCopy ? dom.on('click', (ev, elem) => doCopy(value, elem)) : null),
testId(id),
)
),
);
}
private _onSpliceChange(splice: {start: number}) {
const rowRange = this._rowRange.get();
const rowCount = rowRange.end - rowRange.begin;
if (rowCount === 1) { return; }
if (splice.start >= rowRange.end) { return; }
// We could be smart here and only recalculate when the splice affects our selection. But for
// that to make sense, the selection itself needs to be smart. Currently, the selection is
// lost whenever the cursor is affected. For example, when you have a selection and another
// user adds/removes columns or rows before the selection, the selection won't be shifted
// with the cursor, and will instead be cleared. Since we can't always rely on the selection
// being there, we'll err on the safe side and always schedule a recalc.
this._scheduleRecalc();
}
private _onRowNotify(rows: RowsChanged) {
const rowRange = this._rowRange.get();
if (rows === ALL) {
this._scheduleRecalc();
} else {
const rowArray = this._sortedRows.getKoArray().peek();
const rowIdSet = new Set(rows);
for (let r = rowRange.begin; r < rowRange.end; r++) {
if (rowIdSet.has(rowArray[r])) {
this._scheduleRecalc();
break;
}
}
}
}
/**
* Schedules a re-calculation to occur in the immediate future.
*
* May be called repeatedly, but only a single re-calculation will be scheduled, to
* avoid queueing unnecessary amounts of work.
*/
private _scheduleRecalc() {
// `_recalc` may take a non-trivial amount of time, so we defer until the stack is clear.
this._delayedRecalc.schedule(0, () => this._recalc());
}
private _recalc() {
const rowRange = this._rowRange.get();
const colRange = this._colRange.get();
let rowCount = rowRange.end - rowRange.begin;
let colCount = colRange.end - colRange.begin;
const cellCount = rowCount * colCount;
const summary: SummaryPart[] = [];
// Do nothing on narrow screens, because we haven't come up with a place to render sum anyway.
if (cellCount > 1 && !isNarrowScreen()) {
if (cellCount <= MAX_CELLS_TO_SCAN) {
const rowArray = this._sortedRows.getKoArray().peek();
const fields = this._viewFields.peek().peek();
let countNumeric = 0;
let countNonEmpty = 0;
let sum = 0;
let sumFormatter: BaseFormatter|null = null;
const rowIndices: number[] = [];
for (let r = rowRange.begin; r < rowRange.end; r++) {
const rowId = rowArray[r];
if (rowId === undefined || rowId === 'new') {
// We can run into this whenever the selection gets out of sync due to external
// changes, like another user removing some rows. For now, we'll skip rows that are
// still selected and no longer exist, but the real TODO is to better update the
// selection so that it doesn't have out-of-date and invalid ranges.
rowCount -= 1;
continue;
}
rowIndices.push(this._tableData.getRowIdIndex(rowId)!);
}
for (let c = colRange.begin; c < colRange.end; c++) {
const field = fields[c];
if (field === undefined) {
// Like with rows (see comment above), we need to watch out for out-of-date ranges.
colCount -= 1;
continue;
}
const col = fields[c].column.peek();
const displayCol = fields[c].displayColModel.peek();
const colType = col.type.peek();
const visibleColType = fields[c].visibleColModel.peek().type.peek();
const effectiveColType = visibleColType ?? colType;
const displayColId = displayCol.colId.peek();
// Note: we get values from the display column so that reference columns displaying
// numbers are included in the computed sum. Unfortunately, that also means we can't
// show a count of non-empty references. For now, that's a trade-off we'll have to make,
// but in the future it should be possible to allow showing multiple summary parts with
// some level of configurability.
const values = this._tableData.getColValues(displayColId);
if (!values) {
throw new UserError(`Invalid column ${this._tableData.tableId}.${displayColId}`);
}
const isNumeric = ['Numeric', 'Int', 'Any'].includes(effectiveColType);
const isEmpty: undefined | ((value: CellValue) => boolean) = (
colType.startsWith('Ref:') && !visibleColType ? value => (value === 0) :
isRefListType(colType) || isListType(effectiveColType) ? isEmptyList :
undefined
);
// The loops below are optimized, minimizing the amount of work done per row. For
// example, column values are retrieved in bulk above instead of once per row. In one
// unscientific test, they take 30-60ms per million numeric cells.
//
// TODO: Add a benchmark test suite that automates checking for performance regressions.
if (isNumeric) {
if (!sumFormatter) {
sumFormatter = fields[c].formatter.peek();
}
for (const i of rowIndices) {
const value = values[i];
if (typeof value === 'number') {
countNumeric++;
sum += value;
} else if (value !== null && value !== undefined && value !== '' && !isEmpty?.(value)) {
countNonEmpty++;
}
}
} else {
for (const i of rowIndices) {
const value = values[i];
if (value !== null && value !== undefined && value !== '' && !isEmpty?.(value)) {
countNonEmpty++;
}
}
}
}
if (countNumeric > 0) {
const sumValue = sumFormatter ? sumFormatter.formatAny(sum) : String(sum);
summary.push({id: 'sum', label: 'Sum ', value: sumValue, clickToCopy: true});
} else {
summary.push({id: 'count', label: 'Count ', value: String(countNonEmpty), clickToCopy: true});
}
}
summary.push({id: 'dimensions', label: '', value: `${rowCount}${colCount}`});
}
this._summary.set(summary);
}
}
async function doCopy(value: string, elem: Element) {
await copyToClipboard(value);
showTransientTooltip(elem, t('CopiedClipboard'), {key: 'copy-selection-summary'});
}
const cssSummary = styled('div', `
position: absolute;
bottom: -18px;
height: 18px;
line-height: 18px;
display: flex;
column-gap: 8px;
width: 100%;
justify-content: end;
color: ${theme.text};
font-family: ${vars.fontFamilyData};
@media print {
& {
display: none;
}
}
`);
// Note: the use of an extra element for the background is to set its opacity, to make it a bit
// lighter (or darker, in dark-mode) than actual mediumGrey, without defining a special color.
const cssSummaryPart = styled('div', `
padding: 0 8px;
border-radius: 4px;
border-top-left-radius: 0px;
border-top-right-radius: 0px;
border-top: none;
z-index: 100;
position: relative;
overflow: hidden;
text-overflow: ellipsis;
white-space: nowrap;
/* Set explicit backdrop to improve visibility in raw data views. */
background-color: ${theme.mainPanelBg};
&-copyable:hover {
cursor: pointer;
}
&::before {
content: "";
position: absolute;
top: 0;
left: 0;
bottom: 0;
right: 0;
background-color: ${colors.mediumGrey};
opacity: 0.8;
z-index: -1;
}
`);
const cssLabelText = styled('span', `
font-size: ${vars.xsmallFontSize};
text-transform: uppercase;
position: relative;
margin-right: 4px;
.${cssSummaryPart.className}-copyable:hover & {
visibility: hidden;
}
`);
const cssCopyIcon = styled(icon, `
position: absolute;
top: 0;
margin: 1px 0 0 4px;
--icon-color: ${theme.controlFg};
display: none;
.${cssSummaryPart.className}-copyable:hover & {
display: block;
}
`);
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