/** * Custom positioning reference element. * @see https://floating-ui.com/docs/virtual-elements */ const sides = ['top', 'right', 'bottom', 'left']; const alignments = ['start', 'end']; const placements = /*#__PURE__*/sides.reduce((acc, side) => acc.concat(side, side + "-" + alignments[0], side + "-" + alignments[1]), []); const min = Math.min; const max = Math.max; const oppositeSideMap = { left: 'right', right: 'left', bottom: 'top', top: 'bottom' }; const oppositeAlignmentMap = { start: 'end', end: 'start' }; function clamp(start, value, end) { return max(start, min(value, end)); } function evaluate(value, param) { return typeof value === 'function' ? value(param) : value; } function getSide(placement) { return placement.split('-')[0]; } function getAlignment(placement) { return placement.split('-')[1]; } function getOppositeAxis(axis) { return axis === 'x' ? 'y' : 'x'; } function getAxisLength(axis) { return axis === 'y' ? 'height' : 'width'; } function getSideAxis(placement) { return ['top', 'bottom'].includes(getSide(placement)) ? 'y' : 'x'; } function getAlignmentAxis(placement) { return getOppositeAxis(getSideAxis(placement)); } function getAlignmentSides(placement, rects, rtl) { if (rtl === void 0) { rtl = false; } const alignment = getAlignment(placement); const alignmentAxis = getAlignmentAxis(placement); const length = getAxisLength(alignmentAxis); let mainAlignmentSide = alignmentAxis === 'x' ? alignment === (rtl ? 'end' : 'start') ? 'right' : 'left' : alignment === 'start' ? 'bottom' : 'top'; if (rects.reference[length] > rects.floating[length]) { mainAlignmentSide = getOppositePlacement(mainAlignmentSide); } return [mainAlignmentSide, getOppositePlacement(mainAlignmentSide)]; } function getExpandedPlacements(placement) { const oppositePlacement = getOppositePlacement(placement); return [getOppositeAlignmentPlacement(placement), oppositePlacement, getOppositeAlignmentPlacement(oppositePlacement)]; } function getOppositeAlignmentPlacement(placement) { return placement.replace(/start|end/g, alignment => oppositeAlignmentMap[alignment]); } function getSideList(side, isStart, rtl) { const lr = ['left', 'right']; const rl = ['right', 'left']; const tb = ['top', 'bottom']; const bt = ['bottom', 'top']; switch (side) { case 'top': case 'bottom': if (rtl) return isStart ? rl : lr; return isStart ? lr : rl; case 'left': case 'right': return isStart ? tb : bt; default: return []; } } function getOppositeAxisPlacements(placement, flipAlignment, direction, rtl) { const alignment = getAlignment(placement); let list = getSideList(getSide(placement), direction === 'start', rtl); if (alignment) { list = list.map(side => side + "-" + alignment); if (flipAlignment) { list = list.concat(list.map(getOppositeAlignmentPlacement)); } } return list; } function getOppositePlacement(placement) { return placement.replace(/left|right|bottom|top/g, side => oppositeSideMap[side]); } function expandPaddingObject(padding) { return { top: 0, right: 0, bottom: 0, left: 0, ...padding }; } function getPaddingObject(padding) { return typeof padding !== 'number' ? expandPaddingObject(padding) : { top: padding, right: padding, bottom: padding, left: padding }; } function rectToClientRect(rect) { return { ...rect, top: rect.y, left: rect.x, right: rect.x + rect.width, bottom: rect.y + rect.height }; } function computeCoordsFromPlacement(_ref, placement, rtl) { let { reference, floating } = _ref; const sideAxis = getSideAxis(placement); const alignmentAxis = getAlignmentAxis(placement); const alignLength = getAxisLength(alignmentAxis); const side = getSide(placement); const isVertical = sideAxis === 'y'; const commonX = reference.x + reference.width / 2 - floating.width / 2; const commonY = reference.y + reference.height / 2 - floating.height / 2; const commonAlign = reference[alignLength] / 2 - floating[alignLength] / 2; let coords; switch (side) { case 'top': coords = { x: commonX, y: reference.y - floating.height }; break; case 'bottom': coords = { x: commonX, y: reference.y + reference.height }; break; case 'right': coords = { x: reference.x + reference.width, y: commonY }; break; case 'left': coords = { x: reference.x - floating.width, y: commonY }; break; default: coords = { x: reference.x, y: reference.y }; } switch (getAlignment(placement)) { case 'start': coords[alignmentAxis] -= commonAlign * (rtl && isVertical ? -1 : 1); break; case 'end': coords[alignmentAxis] += commonAlign * (rtl && isVertical ? -1 : 1); break; } return coords; } /** * Computes the `x` and `y` coordinates that will place the floating element * next to a given reference element. * * This export does not have any `platform` interface logic. You will need to * write one for the platform you are using Floating UI with. */ const computePosition = async (reference, floating, config) => { const { placement = 'bottom', strategy = 'absolute', middleware = [], platform } = config; const validMiddleware = middleware.filter(Boolean); const rtl = await (platform.isRTL == null ? void 0 : platform.isRTL(floating)); let rects = await platform.getElementRects({ reference, floating, strategy }); let { x, y } = computeCoordsFromPlacement(rects, placement, rtl); let statefulPlacement = placement; let middlewareData = {}; let resetCount = 0; for (let i = 0; i < validMiddleware.length; i++) { const { name, fn } = validMiddleware[i]; const { x: nextX, y: nextY, data, reset } = await fn({ x, y, initialPlacement: placement, placement: statefulPlacement, strategy, middlewareData, rects, platform, elements: { reference, floating } }); x = nextX != null ? nextX : x; y = nextY != null ? nextY : y; middlewareData = { ...middlewareData, [name]: { ...middlewareData[name], ...data } }; if (reset && resetCount <= 50) { resetCount++; if (typeof reset === 'object') { if (reset.placement) { statefulPlacement = reset.placement; } if (reset.rects) { rects = reset.rects === true ? await platform.getElementRects({ reference, floating, strategy }) : reset.rects; } ({ x, y } = computeCoordsFromPlacement(rects, statefulPlacement, rtl)); } i = -1; } } return { x, y, placement: statefulPlacement, strategy, middlewareData }; }; /** * Resolves with an object of overflow side offsets that determine how much the * element is overflowing a given clipping boundary on each side. * - positive = overflowing the boundary by that number of pixels * - negative = how many pixels left before it will overflow * - 0 = lies flush with the boundary * @see https://floating-ui.com/docs/detectOverflow */ async function detectOverflow(state, options) { var _await$platform$isEle; if (options === void 0) { options = {}; } const { x, y, platform, rects, elements, strategy } = state; const { boundary = 'clippingAncestors', rootBoundary = 'viewport', elementContext = 'floating', altBoundary = false, padding = 0 } = evaluate(options, state); const paddingObject = getPaddingObject(padding); const altContext = elementContext === 'floating' ? 'reference' : 'floating'; const element = elements[altBoundary ? altContext : elementContext]; const clippingClientRect = rectToClientRect(await platform.getClippingRect({ element: ((_await$platform$isEle = await (platform.isElement == null ? void 0 : platform.isElement(element))) != null ? _await$platform$isEle : true) ? element : element.contextElement || (await (platform.getDocumentElement == null ? void 0 : platform.getDocumentElement(elements.floating))), boundary, rootBoundary, strategy })); const rect = elementContext === 'floating' ? { ...rects.floating, x, y } : rects.reference; const offsetParent = await (platform.getOffsetParent == null ? void 0 : platform.getOffsetParent(elements.floating)); const offsetScale = (await (platform.isElement == null ? void 0 : platform.isElement(offsetParent))) ? (await (platform.getScale == null ? void 0 : platform.getScale(offsetParent))) || { x: 1, y: 1 } : { x: 1, y: 1 }; const elementClientRect = rectToClientRect(platform.convertOffsetParentRelativeRectToViewportRelativeRect ? await platform.convertOffsetParentRelativeRectToViewportRelativeRect({ elements, rect, offsetParent, strategy }) : rect); return { top: (clippingClientRect.top - elementClientRect.top + paddingObject.top) / offsetScale.y, bottom: (elementClientRect.bottom - clippingClientRect.bottom + paddingObject.bottom) / offsetScale.y, left: (clippingClientRect.left - elementClientRect.left + paddingObject.left) / offsetScale.x, right: (elementClientRect.right - clippingClientRect.right + paddingObject.right) / offsetScale.x }; } /** * Provides data to position an inner element of the floating element so that it * appears centered to the reference element. * @see https://floating-ui.com/docs/arrow */ const arrow = options => ({ name: 'arrow', options, async fn(state) { const { x, y, placement, rects, platform, elements, middlewareData } = state; // Since `element` is required, we don't Partial<> the type. const { element, padding = 0 } = evaluate(options, state) || {}; if (element == null) { return {}; } const paddingObject = getPaddingObject(padding); const coords = { x, y }; const axis = getAlignmentAxis(placement); const length = getAxisLength(axis); const arrowDimensions = await platform.getDimensions(element); const isYAxis = axis === 'y'; const minProp = isYAxis ? 'top' : 'left'; const maxProp = isYAxis ? 'bottom' : 'right'; const clientProp = isYAxis ? 'clientHeight' : 'clientWidth'; const endDiff = rects.reference[length] + rects.reference[axis] - coords[axis] - rects.floating[length]; const startDiff = coords[axis] - rects.reference[axis]; const arrowOffsetParent = await (platform.getOffsetParent == null ? void 0 : platform.getOffsetParent(element)); let clientSize = arrowOffsetParent ? arrowOffsetParent[clientProp] : 0; // DOM platform can return `window` as the `offsetParent`. if (!clientSize || !(await (platform.isElement == null ? void 0 : platform.isElement(arrowOffsetParent)))) { clientSize = elements.floating[clientProp] || rects.floating[length]; } const centerToReference = endDiff / 2 - startDiff / 2; // If the padding is large enough that it causes the arrow to no longer be // centered, modify the padding so that it is centered. const largestPossiblePadding = clientSize / 2 - arrowDimensions[length] / 2 - 1; const minPadding = min(paddingObject[minProp], largestPossiblePadding); const maxPadding = min(paddingObject[maxProp], largestPossiblePadding); // Make sure the arrow doesn't overflow the floating element if the center // point is outside the floating element's bounds. const min$1 = minPadding; const max = clientSize - arrowDimensions[length] - maxPadding; const center = clientSize / 2 - arrowDimensions[length] / 2 + centerToReference; const offset = clamp(min$1, center, max); // If the reference is small enough that the arrow's padding causes it to // to point to nothing for an aligned placement, adjust the offset of the // floating element itself. To ensure `shift()` continues to take action, // a single reset is performed when this is true. const shouldAddOffset = !middlewareData.arrow && getAlignment(placement) != null && center !== offset && rects.reference[length] / 2 - (center < min$1 ? minPadding : maxPadding) - arrowDimensions[length] / 2 < 0; const alignmentOffset = shouldAddOffset ? center < min$1 ? center - min$1 : center - max : 0; return { [axis]: coords[axis] + alignmentOffset, data: { [axis]: offset, centerOffset: center - offset - alignmentOffset, ...(shouldAddOffset && { alignmentOffset }) }, reset: shouldAddOffset }; } }); function getPlacementList(alignment, autoAlignment, allowedPlacements) { const allowedPlacementsSortedByAlignment = alignment ? [...allowedPlacements.filter(placement => getAlignment(placement) === alignment), ...allowedPlacements.filter(placement => getAlignment(placement) !== alignment)] : allowedPlacements.filter(placement => getSide(placement) === placement); return allowedPlacementsSortedByAlignment.filter(placement => { if (alignment) { return getAlignment(placement) === alignment || (autoAlignment ? getOppositeAlignmentPlacement(placement) !== placement : false); } return true; }); } /** * Optimizes the visibility of the floating element by choosing the placement * that has the most space available automatically, without needing to specify a * preferred placement. Alternative to `flip`. * @see https://floating-ui.com/docs/autoPlacement */ const autoPlacement = function (options) { if (options === void 0) { options = {}; } return { name: 'autoPlacement', options, async fn(state) { var _middlewareData$autoP, _middlewareData$autoP2, _placementsThatFitOnE; const { rects, middlewareData, placement, platform, elements } = state; const { crossAxis = false, alignment, allowedPlacements = placements, autoAlignment = true, ...detectOverflowOptions } = evaluate(options, state); const placements$1 = alignment !== undefined || allowedPlacements === placements ? getPlacementList(alignment || null, autoAlignment, allowedPlacements) : allowedPlacements; const overflow = await detectOverflow(state, detectOverflowOptions); const currentIndex = ((_middlewareData$autoP = middlewareData.autoPlacement) == null ? void 0 : _middlewareData$autoP.index) || 0; const currentPlacement = placements$1[currentIndex]; if (currentPlacement == null) { return {}; } const alignmentSides = getAlignmentSides(currentPlacement, rects, await (platform.isRTL == null ? void 0 : platform.isRTL(elements.floating))); // Make `computeCoords` start from the right place. if (placement !== currentPlacement) { return { reset: { placement: placements$1[0] } }; } const currentOverflows = [overflow[getSide(currentPlacement)], overflow[alignmentSides[0]], overflow[alignmentSides[1]]]; const allOverflows = [...(((_middlewareData$autoP2 = middlewareData.autoPlacement) == null ? void 0 : _middlewareData$autoP2.overflows) || []), { placement: currentPlacement, overflows: currentOverflows }]; const nextPlacement = placements$1[currentIndex + 1]; // There are more placements to check. if (nextPlacement) { return { data: { index: currentIndex + 1, overflows: allOverflows }, reset: { placement: nextPlacement } }; } const placementsSortedByMostSpace = allOverflows.map(d => { const alignment = getAlignment(d.placement); return [d.placement, alignment && crossAxis ? // Check along the mainAxis and main crossAxis side. d.overflows.slice(0, 2).reduce((acc, v) => acc + v, 0) : // Check only the mainAxis. d.overflows[0], d.overflows]; }).sort((a, b) => a[1] - b[1]); const placementsThatFitOnEachSide = placementsSortedByMostSpace.filter(d => d[2].slice(0, // Aligned placements should not check their opposite crossAxis // side. getAlignment(d[0]) ? 2 : 3).every(v => v <= 0)); const resetPlacement = ((_placementsThatFitOnE = placementsThatFitOnEachSide[0]) == null ? void 0 : _placementsThatFitOnE[0]) || placementsSortedByMostSpace[0][0]; if (resetPlacement !== placement) { return { data: { index: currentIndex + 1, overflows: allOverflows }, reset: { placement: resetPlacement } }; } return {}; } }; }; /** * Optimizes the visibility of the floating element by flipping the `placement` * in order to keep it in view when the preferred placement(s) will overflow the * clipping boundary. Alternative to `autoPlacement`. * @see https://floating-ui.com/docs/flip */ const flip = function (options) { if (options === void 0) { options = {}; } return { name: 'flip', options, async fn(state) { var _middlewareData$arrow, _middlewareData$flip; const { placement, middlewareData, rects, initialPlacement, platform, elements } = state; const { mainAxis: checkMainAxis = true, crossAxis: checkCrossAxis = true, fallbackPlacements: specifiedFallbackPlacements, fallbackStrategy = 'bestFit', fallbackAxisSideDirection = 'none', flipAlignment = true, ...detectOverflowOptions } = evaluate(options, state); // If a reset by the arrow was caused due to an alignment offset being // added, we should skip any logic now since `flip()` has already done its // work. // https://github.com/floating-ui/floating-ui/issues/2549#issuecomment-1719601643 if ((_middlewareData$arrow = middlewareData.arrow) != null && _middlewareData$arrow.alignmentOffset) { return {}; } const side = getSide(placement); const isBasePlacement = getSide(initialPlacement) === initialPlacement; const rtl = await (platform.isRTL == null ? void 0 : platform.isRTL(elements.floating)); const fallbackPlacements = specifiedFallbackPlacements || (isBasePlacement || !flipAlignment ? [getOppositePlacement(initialPlacement)] : getExpandedPlacements(initialPlacement)); if (!specifiedFallbackPlacements && fallbackAxisSideDirection !== 'none') { fallbackPlacements.push(...getOppositeAxisPlacements(initialPlacement, flipAlignment, fallbackAxisSideDirection, rtl)); } const placements = [initialPlacement, ...fallbackPlacements]; const overflow = await detectOverflow(state, detectOverflowOptions); const overflows = []; let overflowsData = ((_middlewareData$flip = middlewareData.flip) == null ? void 0 : _middlewareData$flip.overflows) || []; if (checkMainAxis) { overflows.push(overflow[side]); } if (checkCrossAxis) { const sides = getAlignmentSides(placement, rects, rtl); overflows.push(overflow[sides[0]], overflow[sides[1]]); } overflowsData = [...overflowsData, { placement, overflows }]; // One or more sides is overflowing. if (!overflows.every(side => side <= 0)) { var _middlewareData$flip2, _overflowsData$filter; const nextIndex = (((_middlewareData$flip2 = middlewareData.flip) == null ? void 0 : _middlewareData$flip2.index) || 0) + 1; const nextPlacement = placements[nextIndex]; if (nextPlacement) { // Try next placement and re-run the lifecycle. return { data: { index: nextIndex, overflows: overflowsData }, reset: { placement: nextPlacement } }; } // First, find the candidates that fit on the mainAxis side of overflow, // then find the placement that fits the best on the main crossAxis side. let resetPlacement = (_overflowsData$filter = overflowsData.filter(d => d.overflows[0] <= 0).sort((a, b) => a.overflows[1] - b.overflows[1])[0]) == null ? void 0 : _overflowsData$filter.placement; // Otherwise fallback. if (!resetPlacement) { switch (fallbackStrategy) { case 'bestFit': { var _overflowsData$map$so; const placement = (_overflowsData$map$so = overflowsData.map(d => [d.placement, d.overflows.filter(overflow => overflow > 0).reduce((acc, overflow) => acc + overflow, 0)]).sort((a, b) => a[1] - b[1])[0]) == null ? void 0 : _overflowsData$map$so[0]; if (placement) { resetPlacement = placement; } break; } case 'initialPlacement': resetPlacement = initialPlacement; break; } } if (placement !== resetPlacement) { return { reset: { placement: resetPlacement } }; } } return {}; } }; }; function getSideOffsets(overflow, rect) { return { top: overflow.top - rect.height, right: overflow.right - rect.width, bottom: overflow.bottom - rect.height, left: overflow.left - rect.width }; } function isAnySideFullyClipped(overflow) { return sides.some(side => overflow[side] >= 0); } /** * Provides data to hide the floating element in applicable situations, such as * when it is not in the same clipping context as the reference element. * @see https://floating-ui.com/docs/hide */ const hide = function (options) { if (options === void 0) { options = {}; } return { name: 'hide', options, async fn(state) { const { rects } = state; const { strategy = 'referenceHidden', ...detectOverflowOptions } = evaluate(options, state); switch (strategy) { case 'referenceHidden': { const overflow = await detectOverflow(state, { ...detectOverflowOptions, elementContext: 'reference' }); const offsets = getSideOffsets(overflow, rects.reference); return { data: { referenceHiddenOffsets: offsets, referenceHidden: isAnySideFullyClipped(offsets) } }; } case 'escaped': { const overflow = await detectOverflow(state, { ...detectOverflowOptions, altBoundary: true }); const offsets = getSideOffsets(overflow, rects.floating); return { data: { escapedOffsets: offsets, escaped: isAnySideFullyClipped(offsets) } }; } default: { return {}; } } } }; }; function getBoundingRect(rects) { const minX = min(...rects.map(rect => rect.left)); const minY = min(...rects.map(rect => rect.top)); const maxX = max(...rects.map(rect => rect.right)); const maxY = max(...rects.map(rect => rect.bottom)); return { x: minX, y: minY, width: maxX - minX, height: maxY - minY }; } function getRectsByLine(rects) { const sortedRects = rects.slice().sort((a, b) => a.y - b.y); const groups = []; let prevRect = null; for (let i = 0; i < sortedRects.length; i++) { const rect = sortedRects[i]; if (!prevRect || rect.y - prevRect.y > prevRect.height / 2) { groups.push([rect]); } else { groups[groups.length - 1].push(rect); } prevRect = rect; } return groups.map(rect => rectToClientRect(getBoundingRect(rect))); } /** * Provides improved positioning for inline reference elements that can span * over multiple lines, such as hyperlinks or range selections. * @see https://floating-ui.com/docs/inline */ const inline = function (options) { if (options === void 0) { options = {}; } return { name: 'inline', options, async fn(state) { const { placement, elements, rects, platform, strategy } = state; // A MouseEvent's client{X,Y} coords can be up to 2 pixels off a // ClientRect's bounds, despite the event listener being triggered. A // padding of 2 seems to handle this issue. const { padding = 2, x, y } = evaluate(options, state); const nativeClientRects = Array.from((await (platform.getClientRects == null ? void 0 : platform.getClientRects(elements.reference))) || []); const clientRects = getRectsByLine(nativeClientRects); const fallback = rectToClientRect(getBoundingRect(nativeClientRects)); const paddingObject = getPaddingObject(padding); function getBoundingClientRect() { // There are two rects and they are disjoined. if (clientRects.length === 2 && clientRects[0].left > clientRects[1].right && x != null && y != null) { // Find the first rect in which the point is fully inside. return clientRects.find(rect => x > rect.left - paddingObject.left && x < rect.right + paddingObject.right && y > rect.top - paddingObject.top && y < rect.bottom + paddingObject.bottom) || fallback; } // There are 2 or more connected rects. if (clientRects.length >= 2) { if (getSideAxis(placement) === 'y') { const firstRect = clientRects[0]; const lastRect = clientRects[clientRects.length - 1]; const isTop = getSide(placement) === 'top'; const top = firstRect.top; const bottom = lastRect.bottom; const left = isTop ? firstRect.left : lastRect.left; const right = isTop ? firstRect.right : lastRect.right; const width = right - left; const height = bottom - top; return { top, bottom, left, right, width, height, x: left, y: top }; } const isLeftSide = getSide(placement) === 'left'; const maxRight = max(...clientRects.map(rect => rect.right)); const minLeft = min(...clientRects.map(rect => rect.left)); const measureRects = clientRects.filter(rect => isLeftSide ? rect.left === minLeft : rect.right === maxRight); const top = measureRects[0].top; const bottom = measureRects[measureRects.length - 1].bottom; const left = minLeft; const right = maxRight; const width = right - left; const height = bottom - top; return { top, bottom, left, right, width, height, x: left, y: top }; } return fallback; } const resetRects = await platform.getElementRects({ reference: { getBoundingClientRect }, floating: elements.floating, strategy }); if (rects.reference.x !== resetRects.reference.x || rects.reference.y !== resetRects.reference.y || rects.reference.width !== resetRects.reference.width || rects.reference.height !== resetRects.reference.height) { return { reset: { rects: resetRects } }; } return {}; } }; }; // For type backwards-compatibility, the `OffsetOptions` type was also // Derivable. async function convertValueToCoords(state, options) { const { placement, platform, elements } = state; const rtl = await (platform.isRTL == null ? void 0 : platform.isRTL(elements.floating)); const side = getSide(placement); const alignment = getAlignment(placement); const isVertical = getSideAxis(placement) === 'y'; const mainAxisMulti = ['left', 'top'].includes(side) ? -1 : 1; const crossAxisMulti = rtl && isVertical ? -1 : 1; const rawValue = evaluate(options, state); let { mainAxis, crossAxis, alignmentAxis } = typeof rawValue === 'number' ? { mainAxis: rawValue, crossAxis: 0, alignmentAxis: null } : { mainAxis: 0, crossAxis: 0, alignmentAxis: null, ...rawValue }; if (alignment && typeof alignmentAxis === 'number') { crossAxis = alignment === 'end' ? alignmentAxis * -1 : alignmentAxis; } return isVertical ? { x: crossAxis * crossAxisMulti, y: mainAxis * mainAxisMulti } : { x: mainAxis * mainAxisMulti, y: crossAxis * crossAxisMulti }; } /** * Modifies the placement by translating the floating element along the * specified axes. * A number (shorthand for `mainAxis` or distance), or an axes configuration * object may be passed. * @see https://floating-ui.com/docs/offset */ const offset = function (options) { if (options === void 0) { options = 0; } return { name: 'offset', options, async fn(state) { var _middlewareData$offse, _middlewareData$arrow; const { x, y, placement, middlewareData } = state; const diffCoords = await convertValueToCoords(state, options); // If the placement is the same and the arrow caused an alignment offset // then we don't need to change the positioning coordinates. if (placement === ((_middlewareData$offse = middlewareData.offset) == null ? void 0 : _middlewareData$offse.placement) && (_middlewareData$arrow = middlewareData.arrow) != null && _middlewareData$arrow.alignmentOffset) { return {}; } return { x: x + diffCoords.x, y: y + diffCoords.y, data: { ...diffCoords, placement } }; } }; }; /** * Optimizes the visibility of the floating element by shifting it in order to * keep it in view when it will overflow the clipping boundary. * @see https://floating-ui.com/docs/shift */ const shift = function (options) { if (options === void 0) { options = {}; } return { name: 'shift', options, async fn(state) { const { x, y, placement } = state; const { mainAxis: checkMainAxis = true, crossAxis: checkCrossAxis = false, limiter = { fn: _ref => { let { x, y } = _ref; return { x, y }; } }, ...detectOverflowOptions } = evaluate(options, state); const coords = { x, y }; const overflow = await detectOverflow(state, detectOverflowOptions); const crossAxis = getSideAxis(getSide(placement)); const mainAxis = getOppositeAxis(crossAxis); let mainAxisCoord = coords[mainAxis]; let crossAxisCoord = coords[crossAxis]; if (checkMainAxis) { const minSide = mainAxis === 'y' ? 'top' : 'left'; const maxSide = mainAxis === 'y' ? 'bottom' : 'right'; const min = mainAxisCoord + overflow[minSide]; const max = mainAxisCoord - overflow[maxSide]; mainAxisCoord = clamp(min, mainAxisCoord, max); } if (checkCrossAxis) { const minSide = crossAxis === 'y' ? 'top' : 'left'; const maxSide = crossAxis === 'y' ? 'bottom' : 'right'; const min = crossAxisCoord + overflow[minSide]; const max = crossAxisCoord - overflow[maxSide]; crossAxisCoord = clamp(min, crossAxisCoord, max); } const limitedCoords = limiter.fn({ ...state, [mainAxis]: mainAxisCoord, [crossAxis]: crossAxisCoord }); return { ...limitedCoords, data: { x: limitedCoords.x - x, y: limitedCoords.y - y } }; } }; }; /** * Built-in `limiter` that will stop `shift()` at a certain point. */ const limitShift = function (options) { if (options === void 0) { options = {}; } return { options, fn(state) { const { x, y, placement, rects, middlewareData } = state; const { offset = 0, mainAxis: checkMainAxis = true, crossAxis: checkCrossAxis = true } = evaluate(options, state); const coords = { x, y }; const crossAxis = getSideAxis(placement); const mainAxis = getOppositeAxis(crossAxis); let mainAxisCoord = coords[mainAxis]; let crossAxisCoord = coords[crossAxis]; const rawOffset = evaluate(offset, state); const computedOffset = typeof rawOffset === 'number' ? { mainAxis: rawOffset, crossAxis: 0 } : { mainAxis: 0, crossAxis: 0, ...rawOffset }; if (checkMainAxis) { const len = mainAxis === 'y' ? 'height' : 'width'; const limitMin = rects.reference[mainAxis] - rects.floating[len] + computedOffset.mainAxis; const limitMax = rects.reference[mainAxis] + rects.reference[len] - computedOffset.mainAxis; if (mainAxisCoord < limitMin) { mainAxisCoord = limitMin; } else if (mainAxisCoord > limitMax) { mainAxisCoord = limitMax; } } if (checkCrossAxis) { var _middlewareData$offse, _middlewareData$offse2; const len = mainAxis === 'y' ? 'width' : 'height'; const isOriginSide = ['top', 'left'].includes(getSide(placement)); const limitMin = rects.reference[crossAxis] - rects.floating[len] + (isOriginSide ? ((_middlewareData$offse = middlewareData.offset) == null ? void 0 : _middlewareData$offse[crossAxis]) || 0 : 0) + (isOriginSide ? 0 : computedOffset.crossAxis); const limitMax = rects.reference[crossAxis] + rects.reference[len] + (isOriginSide ? 0 : ((_middlewareData$offse2 = middlewareData.offset) == null ? void 0 : _middlewareData$offse2[crossAxis]) || 0) - (isOriginSide ? computedOffset.crossAxis : 0); if (crossAxisCoord < limitMin) { crossAxisCoord = limitMin; } else if (crossAxisCoord > limitMax) { crossAxisCoord = limitMax; } } return { [mainAxis]: mainAxisCoord, [crossAxis]: crossAxisCoord }; } }; }; /** * Provides data that allows you to change the size of the floating element — * for instance, prevent it from overflowing the clipping boundary or match the * width of the reference element. * @see https://floating-ui.com/docs/size */ const size = function (options) { if (options === void 0) { options = {}; } return { name: 'size', options, async fn(state) { const { placement, rects, platform, elements } = state; const { apply = () => {}, ...detectOverflowOptions } = evaluate(options, state); const overflow = await detectOverflow(state, detectOverflowOptions); const side = getSide(placement); const alignment = getAlignment(placement); const isYAxis = getSideAxis(placement) === 'y'; const { width, height } = rects.floating; let heightSide; let widthSide; if (side === 'top' || side === 'bottom') { heightSide = side; widthSide = alignment === ((await (platform.isRTL == null ? void 0 : platform.isRTL(elements.floating))) ? 'start' : 'end') ? 'left' : 'right'; } else { widthSide = side; heightSide = alignment === 'end' ? 'top' : 'bottom'; } const overflowAvailableHeight = height - overflow[heightSide]; const overflowAvailableWidth = width - overflow[widthSide]; const noShift = !state.middlewareData.shift; let availableHeight = overflowAvailableHeight; let availableWidth = overflowAvailableWidth; if (isYAxis) { const maximumClippingWidth = width - overflow.left - overflow.right; availableWidth = alignment || noShift ? min(overflowAvailableWidth, maximumClippingWidth) : maximumClippingWidth; } else { const maximumClippingHeight = height - overflow.top - overflow.bottom; availableHeight = alignment || noShift ? min(overflowAvailableHeight, maximumClippingHeight) : maximumClippingHeight; } if (noShift && !alignment) { const xMin = max(overflow.left, 0); const xMax = max(overflow.right, 0); const yMin = max(overflow.top, 0); const yMax = max(overflow.bottom, 0); if (isYAxis) { availableWidth = width - 2 * (xMin !== 0 || xMax !== 0 ? xMin + xMax : max(overflow.left, overflow.right)); } else { availableHeight = height - 2 * (yMin !== 0 || yMax !== 0 ? yMin + yMax : max(overflow.top, overflow.bottom)); } } await apply({ ...state, availableWidth, availableHeight }); const nextDimensions = await platform.getDimensions(elements.floating); if (width !== nextDimensions.width || height !== nextDimensions.height) { return { reset: { rects: true } }; } return {}; } }; }; export { arrow, autoPlacement, computePosition, detectOverflow, flip, hide, inline, limitShift, offset, rectToClientRect, shift, size };