diff options
author | (quasar) nebula <qznebula@protonmail.com> | 2024-03-09 14:55:29 -0400 |
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committer | (quasar) nebula <qznebula@protonmail.com> | 2024-03-09 15:40:20 -0400 |
commit | dc978010dba8a7780771c79dcdc3894ba7971d67 (patch) | |
tree | 32a94d4261d94c9e120f991ed8e901a9152f8197 | |
parent | 543fba7f4215f6fb2a8cb65467551e3413646122 (diff) |
client: WikiRect utilities + math
-rw-r--r-- | src/static/client3.js | 439 |
1 files changed, 401 insertions, 38 deletions
diff --git a/src/static/client3.js b/src/static/client3.js index 48a69bac..37bcee57 100644 --- a/src/static/client3.js +++ b/src/static/client3.js @@ -177,6 +177,394 @@ function dispatchInternalEvent(event, eventName, ...args) { return results; } +// Rectangle math ----------------------------------------- + +class WikiRect extends DOMRect { + // Useful constructors + + static fromWindow() { + const {clientWidth: width, clientHeight: height} = + document.documentElement; + + return Reflect.construct(this, [0, 0, width, height]); + } + + static fromElement(element) { + return this.fromRect(element.getBoundingClientRect()); + } + + static leftOf(origin, offset = 0) { + // Returns a rectangle representing everywhere to the left of the provided + // point or rectangle (with no top or bottom bounds), towards negative x. + // If an offset is provided, this is added onto the origin. + + return this.#past(origin, offset, { + origin: 'x', + extent: 'width', + edge: 'left', + direction: -Infinity, + construct: from => + [from, -Infinity, -Infinity, Infinity], + }); + } + + static rightOf(origin, offset = 0) { + // Returns a rectangle representing everywhere to the right of the + // provided point or rectangle (with no top or bottom bounds), towards + // positive x. If an offset is provided, this is added onto the origin. + + return this.#past(origin, offset, { + origin: 'x', + extent: 'width', + edge: 'right', + direction: Infinity, + construct: from => + [from, -Infinity, Infinity, Infinity], + }); + } + + static above(origin, offset = 0) { + // Returns a rectangle representing everywhere above the provided point + // or rectangle (with no left or right bounds), towards negative y. + // If an offset is provided, this is added onto the origin. + + return this.#past(origin, offset, { + origin: 'y', + extent: 'height', + edge: 'top', + direction: -Infinity, + construct: from => + [-Infinity, from, Infinity, -Infinity], + }); + } + + static beneath(origin, offset = 0) { + // Returns a rectangle representing everywhere beneath the provided point + // or rectangle (with no left or right bounds), towards positive y. + // If an offset is provided, this is added onto the origin. + + return this.#past(origin, offset, { + origin: 'y', + extent: 'height', + edge: 'bottom', + direction: Infinity, + construct: from => + [-Infinity, from, Infinity, Infinity], + }); + } + + // Constructor helpers + + static #past(origin, offset, opts) { + if (!isFinite(offset)) { + throw new TypeError(`Didn't expect infinite offset`); + } + + const {direction, edge} = opts; + + if (typeof origin === 'object') { + const {origin: originProperty, extent: extentProperty} = opts; + + const normalized = + WikiRect.fromRect(origin).toNormalized(); + + if (normalized[extentProperty] === direction) { + throw new TypeError(`Provided rectangle already extends to ${edge} edge`); + } + + if (normalized[extentProperty] === -direction) { + return this.#past(normalized[originProperty], offset, opts); + } + + if (normalized.y === direction) { + throw new TypeError(`Provided rectangle already starts at ${edge} edge`); + } + + return this.#past(normalized[edge], offset, opts); + } + + const {construct} = opts; + + if (origin === direction) { + throw new TypeError(`Provided point is already at ${edge} edge`); + } + + return Reflect.construct(this, construct(origin + offset)).toNormalized(); + } + + // Predicates + + static rejectInfiniteOriginNonZeroFiniteExtent({origin, extent}) { + // Indicate that, in this context, it's meaningless to provide + // a finite extent starting at an infinite origin and going towards + // or away from zero (i.e. a rectangle along a cardinal edge). + + if (!isFinite(origin) && isFinite(extent) && extent !== 0) { + throw new TypeError(`Didn't expect infinite origin paired with finite extent`); + } + } + + static rejectInfiniteOriginZeroExtent({origin, extent}) { + // Indicate that, in this context, it's meaningless to provide + // a zero extent at an infinite origin (i.e. a cardinal edge). + + if (!isFinite(origin) && extent === 0) { + throw new TypeError(`Didn't expect infinite origin paired with zero extent`); + } + } + + static rejectNonOpposingInfiniteOriginInfiniteExtent({origin, extent}) { + // Indicate that, in this context, it's meaningless to provide + // an infinite extent going in the same direction as its infinite + // origin (an area "infinitely past" a cardinal edge). + + if (!isFinite(origin) && origin === extent) { + throw new TypeError(`Didn't expect non-opposing infinite origin and extent`); + } + } + + // Transformations + + static normalizeOriginExtent({origin, extent}) { + // Varying behavior based on inputs: + // + // - For finite origin and finite extent, flip the orientation + // (if necessary) so that extent is positive. + // - For finite origin and infinite extent (i.e. an origin up to + // a cardinal edge), leave as-is. + // - For infinite origin and infinite extent, flip the orientation + // (if necessary) so origin is negative and extent is positive. + // - For infinite origin and zero extent (i.e. a cardinal edge), + // leave as-is. + // - For all other cases, error. + // + + this.rejectInfiniteOriginNonZeroFiniteExtent({origin, extent}); + this.rejectNonOpposingInfiniteOriginInfiniteExtent({origin, extent}); + + if (isFinite(origin) && isFinite(extent) && extent < 0) { + return {origin: origin + extent, extent: -extent}; + } + + if (!isFinite(origin) && !isFinite(extent)) { + return {origin: -Infinity, extent: Infinity}; + } + + return {origin, extent}; + } + + toNormalized() { + const {origin: newX, extent: newWidth} = + WikiRect.normalizeOriginExtent({ + origin: this.x, + extent: this.width, + }); + + const {origin: newY, extent: newHeight} = + WikiRect.normalizeOriginExtent({ + origin: this.y, + extent: this.height, + }); + + return Reflect.construct(this.constructor, [newX, newY, newWidth, newHeight]); + } + + static intersectionFromOriginsExtents(...entries) { + // An intersection is the common subsection across two or more regions. + + const [first, second, ...rest] = entries; + + if (entries.length >= 3) { + return this.intersection(first, this.intersection(second, ...rest)); + } + + if (entries.length === 2) { + if (first === null || second === null) { + return null; + } + + this.rejectInfiniteOriginZeroExtent(first); + this.rejectInfiniteOriginZeroExtent(second); + + const {origin: origin1, extent: extent1} = this.normalizeOriginExtent(first); + const {origin: origin2, extent: extent2} = this.normalizeOriginExtent(second); + + // After normalizing, *each* region will be one of these: + // + // - Finite origin, finite extent + // (a standard region, bounded on both sides) + // - Finite origin, infinite extent + // (everything to one direction of a given origin) + // - Infinite origin, infinite extent + // (everything everywhere) + // + // So we need to handle any *combination* of these kinds of regions. + + // If either origin is infinite, that region represents everywhere, + // so it'll never limit the region of the other. + + if (!isFinite(origin1)) { + return {origin: origin2, extent: extent2}; + } + + if (!isFinite(origin2)) { + return {origin: origin1, extent: extent1}; + } + + // If neither origin is infinite, both regions are bounded on at least + // one side, and may limit the other accordingly. Find the minimum and + // maximum points in each region, letting Infinity propagate through, + // which represents no boundary in that direction. + + const minimum1 = Math.min(origin1, origin1 + extent1); + const minimum2 = Math.min(origin2, origin2 + extent2); + const maximum1 = Math.max(origin1, origin1 + extent1); + const maximum2 = Math.max(origin2, origin2 + extent2); + + // Now get the maximum of the regions' minimums, and the minimum of the + // regions' maximums. These are the limits of the new region; computing + // with minimums and maximums in this way "polarizes" the limits, so we + // can perform specific polarized math in the following steps. + // + // Infinity will also propagate here, but with some important + // restricitons: only maxOfMinimums can be positive Infinity, and only + // minOfMaximums can be negative Infinity; and if either is Infinity, + // the other is not, since otherwise we'd be working with two everywhere + // regions, and would've just returned an everywhere region above. + + const maxOfMinimums = Math.max(minimum1, minimum2); + const minOfMaximums = Math.min(maximum1, maximum2); + + // Now check if the maximum of minimums is greater than the minimum of + // maximums. If so, the regions don't have any overlap - one region + // limits the overlap to end before the other region starts. This works + // because we've polarized the limits above! + + if (maxOfMinimums > minOfMaximums) { + return null; + } + + // Otherwise there's at least some overlap, even if it's just one point + // (i.e. one ends exactly where the other begins). We have to take care + // of infinities in particular, now. As mentioned above, only one of the + // points will be infinity (at most). So the origin is the non-infinite + // point, and the extent is in the direction of the infinite point. + + if (minOfMaximums === -Infinity) { + return {origin: maxOfMinimums, extent: -Infinity}; + } + + if (maxOfMinimums === Infinity) { + return {origin: minOfMaximums, extent: Infinity}; + } + + // If neither point is infinity, we're working with two regions that are + // both bounded on both sides, so the overlapping region is just the + // region constrained by the limits above. Since these are polarized, + // start from maxOfMinimums and extend to minOfMaximums, resulting in + // a standard, already-normalized region. + + return { + origin: maxOfMinimums, + extent: minOfMaximums - maxOfMinimums, + }; + } + + if (entries.length === 1) { + return first; + } + + throw new TypeError(`Expected at least one {origin, extent} entry`); + } + + intersectionWith(rect) { + const {origin: x, extent: width} = + WikiRect.intersectionFromOriginsExtents( + {origin: this.x, extent: this.width}, + {origin: rect.x, extent: rect.width}); + + const {origin: y, extent: height} = + WikiRect.intersectionFromOriginsExtents( + {origin: this.y, extent: this.height}, + {origin: rect.y, extent: rect.height}); + + return Reflect.construct(this.constructor, [x, y, width, height]); + } + + chopExtendingOutside(rect) { + this.intersectionWith(rect).writeOnto(this); + } + + static insetOriginExtent({origin, extent, start = 0, end = 0}) { + const normalized = + this.normalizeOriginExtent({origin, extent}); + + // If this would crush the bounds past each other, just return + // the halfway point. + if (extent < start + end) { + return {origin: origin + (start + end) / 2, extent: 0}; + } + + return { + origin: origin + start, + extent: extent - start - end, + }; + } + + toInset(arg1, arg2) { + if (typeof arg1 === 'number' && typeof arg2 === 'number') { + return this.toInset({ + left: arg1, + right: arg1, + top: arg1, + bottom: arg1, + }); + } else if (typeof arg1 === 'number') { + return this.toInset({ + left: arg2, + right: arg2, + top: arg1, + bottom: arg1, + }); + } + + const {top, left, bottom, right} = arg1; + + const {origin: x, extent: width} = + WikiRect.insetOriginExtent({ + origin: this.x, + extent: this.width, + start: left, + end: right, + }); + + const {origin: y, extent: height} = + WikiRect.insetOriginExtent({ + origin: this.y, + extent: this.height, + start: top, + end: bottom, + }); + + return Reflect.construct(this.constructor, [x, y, width, height]); + } + + // Interfacing utilities + + static fromRect(rect) { + return Reflect.construct(this, [rect.x, rect.y, rect.width, rect.height]); + } + + writeOnto(destination) { + Object.assign(destination, { + x: this.x, + y: this.y, + width: this.width, + height: this.height, + }); + } +} + // CSS compatibility-assistant ---------------------------- const cssCompatibilityAssistantInfo = clientInfo.cssCompatibilityAssistantInfo = { @@ -1108,23 +1496,19 @@ function getTooltipFromHoverablePlacementOpportunityAreas(hoverable) { function getTooltipBaselineOpportunityArea(tooltip) { const {stickyContainers} = stickyHeadingInfo; - const {documentElement} = document; const windowRect = - new DOMRect( - 0, 0, - documentElement.clientWidth, - documentElement.clientHeight); + WikiRect.fromWindow(); const baselineRect = - DOMRect.fromRect(windowRect); + WikiRect.fromRect(windowRect); const containingParent = getVisuallyContainingElement(tooltip); if (containingParent) { const containingRect = - containingParent.getBoundingClientRect(); + WikiRect.fromElement(containingParent); // Only respect a portion of the container's padding, giving // the tooltip the impression of a "raised" element. @@ -1133,31 +1517,14 @@ function getTooltipBaselineOpportunityArea(tooltip) { parseFloat(cssProp(containingParent, 'padding-' + side)); const insetContainingRect = - new DOMRect( - containingRect.x + padding('left'), - containingRect.y + padding('top'), - containingRect.width - padding('left') - padding('right'), - containingRect.height - padding('top') - padding('bottom')); - - const subtractFromTop = - Math.max(0, insetContainingRect.top); - - const subtractFromBottom = - Math.max(0, windowRect.height - insetContainingRect.bottom); - - const subtractFromLeft = - Math.max(0, insetContainingRect.left); - - const subtractFromRight = - Math.max(0, windowRect.width - insetContainingRect.right); - - baselineRect.y += subtractFromTop; - baselineRect.height -= subtractFromTop; - baselineRect.height -= subtractFromBottom; + containingRect.toInset({ + left: padding('left'), + right: padding('right'), + top: padding('top'), + bottom: padding('bottom'), + }); - baselineRect.x += subtractFromLeft; - baselineRect.width -= subtractFromLeft; - baselineRect.width -= subtractFromRight; + baselineRect.chopExtendingOutside(insetContainingRect); } // This currently assumes a maximum of one sticky container @@ -1173,14 +1540,10 @@ function getTooltipBaselineOpportunityArea(tooltip) { // Add some padding so the tooltip doesn't line up exactly // with the edge of the sticky container. - const stickyBottom = - stickyRect.bottom + 10; - - const overlap = - Math.max(0, stickyBottom - baselineRect.top); + const beneathStickyContainer = + WikiRect.beneath(stickyRect, 10); - baselineRect.y += overlap; - baselineRect.height -= overlap; + baselineRect.chopExtendingOutside(beneathStickyContainer); } return baselineRect; |