react-native/React/Layout/Layout.c

/**
 *
 * !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
 * !! This file is a check-in from github!                       !!
 * !!                                                            !!
 * !! You should not modify this file directly. Instead:         !!
 * !! 1) Go to https://github.com/facebook/css-layout            !!
 * !! 2) Make a pull request and get it merged                   !!
 * !! 3) Execute ./import.sh to pull in the latest version       !!
 * !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
 *
 * Copyright (c) 2014, Facebook, Inc.
 * All rights reserved.
 *
 * This source code is licensed under the BSD-style license found in the
 * LICENSE file in the root directory of this source tree. An additional grant
 * of patent rights can be found in the PATENTS file in the same directory.
 */

#include <math.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdbool.h>

#include "Layout.h"

bool isUndefined(float value) {
  return isnan(value);
}

static bool eq(float a, float b) {
  if (isUndefined(a)) {
    return isUndefined(b);
  }
  return fabs(a - b) < 0.0001;
}

void init_css_node(css_node_t *node) {
  node->style.align_items = CSS_ALIGN_STRETCH;

  // Some of the fields default to undefined and not 0
  node->style.dimensions[CSS_WIDTH] = CSS_UNDEFINED;
  node->style.dimensions[CSS_HEIGHT] = CSS_UNDEFINED;

  node->style.position[CSS_LEFT] = CSS_UNDEFINED;
  node->style.position[CSS_TOP] = CSS_UNDEFINED;
  node->style.position[CSS_RIGHT] = CSS_UNDEFINED;
  node->style.position[CSS_BOTTOM] = CSS_UNDEFINED;

  node->layout.dimensions[CSS_WIDTH] = CSS_UNDEFINED;
  node->layout.dimensions[CSS_HEIGHT] = CSS_UNDEFINED;

  // Such that the comparison is always going to be false
  node->layout.last_requested_dimensions[CSS_WIDTH] = -1;
  node->layout.last_requested_dimensions[CSS_HEIGHT] = -1;
  node->layout.last_parent_max_width = -1;
  node->layout.should_update = true;
}

css_node_t *new_css_node() {
  css_node_t *node = calloc(1, sizeof(*node));
  init_css_node(node);
  return node;
}

void free_css_node(css_node_t *node) {
  free(node);
}

static void indent(int n) {
  for (int i = 0; i < n; ++i) {
    printf("  ");
  }
}

static void print_number_0(const char *str, float number) {
  if (!eq(number, 0)) {
    printf("%s: %g, ", str, number);
  }
}

static void print_number_nan(const char *str, float number) {
  if (!isnan(number)) {
    printf("%s: %g, ", str, number);
  }
}

static bool four_equal(float four[4]) {
  return
    eq(four[0], four[1]) &&
    eq(four[0], four[2]) &&
    eq(four[0], four[3]);
}


static void print_css_node_rec(
  css_node_t *node,
  css_print_options_t options,
  int level
) {
  indent(level);
  printf("{");

  if (node->print) {
    node->print(node->context);
  }

  if (options & CSS_PRINT_LAYOUT) {
    printf("layout: {");
    printf("width: %g, ", node->layout.dimensions[CSS_WIDTH]);
    printf("height: %g, ", node->layout.dimensions[CSS_HEIGHT]);
    printf("top: %g, ", node->layout.position[CSS_TOP]);
    printf("left: %g", node->layout.position[CSS_LEFT]);
    printf("}, ");
  }

  if (options & CSS_PRINT_STYLE) {
    if (node->style.flex_direction == CSS_FLEX_DIRECTION_ROW) {
      printf("flexDirection: 'row', ");
    }

    if (node->style.justify_content == CSS_JUSTIFY_CENTER) {
      printf("justifyContent: 'center', ");
    } else if (node->style.justify_content == CSS_JUSTIFY_FLEX_END) {
      printf("justifyContent: 'flex-end', ");
    } else if (node->style.justify_content == CSS_JUSTIFY_SPACE_AROUND) {
      printf("justifyContent: 'space-around', ");
    } else if (node->style.justify_content == CSS_JUSTIFY_SPACE_BETWEEN) {
      printf("justifyContent: 'space-between', ");
    }

    if (node->style.align_items == CSS_ALIGN_CENTER) {
      printf("alignItems: 'center', ");
    } else if (node->style.align_items == CSS_ALIGN_FLEX_END) {
      printf("alignItems: 'flex-end', ");
    } else if (node->style.align_items == CSS_ALIGN_STRETCH) {
      printf("alignItems: 'stretch', ");
    }

    if (node->style.align_self == CSS_ALIGN_FLEX_START) {
      printf("alignSelf: 'flex-start', ");
    } else if (node->style.align_self == CSS_ALIGN_CENTER) {
      printf("alignSelf: 'center', ");
    } else if (node->style.align_self == CSS_ALIGN_FLEX_END) {
      printf("alignSelf: 'flex-end', ");
    } else if (node->style.align_self == CSS_ALIGN_STRETCH) {
      printf("alignSelf: 'stretch', ");
    }

    print_number_nan("flex", node->style.flex);

    if (four_equal(node->style.margin)) {
      print_number_0("margin", node->style.margin[CSS_LEFT]);
    } else {
      print_number_0("marginLeft", node->style.margin[CSS_LEFT]);
      print_number_0("marginRight", node->style.margin[CSS_RIGHT]);
      print_number_0("marginTop", node->style.margin[CSS_TOP]);
      print_number_0("marginBottom", node->style.margin[CSS_BOTTOM]);
    }

    if (four_equal(node->style.padding)) {
      print_number_0("padding", node->style.margin[CSS_LEFT]);
    } else {
      print_number_0("paddingLeft", node->style.padding[CSS_LEFT]);
      print_number_0("paddingRight", node->style.padding[CSS_RIGHT]);
      print_number_0("paddingTop", node->style.padding[CSS_TOP]);
      print_number_0("paddingBottom", node->style.padding[CSS_BOTTOM]);
    }

    if (four_equal(node->style.border)) {
      print_number_0("borderWidth", node->style.border[CSS_LEFT]);
    } else {
      print_number_0("borderLeftWidth", node->style.border[CSS_LEFT]);
      print_number_0("borderRightWidth", node->style.border[CSS_RIGHT]);
      print_number_0("borderTopWidth", node->style.border[CSS_TOP]);
      print_number_0("borderBottomWidth", node->style.border[CSS_BOTTOM]);
    }

    print_number_nan("width", node->style.dimensions[CSS_WIDTH]);
    print_number_nan("height", node->style.dimensions[CSS_HEIGHT]);

    if (node->style.position_type == CSS_POSITION_ABSOLUTE) {
      printf("position: 'absolute', ");
    }

    print_number_nan("left", node->style.position[CSS_LEFT]);
    print_number_nan("right", node->style.position[CSS_RIGHT]);
    print_number_nan("top", node->style.position[CSS_TOP]);
    print_number_nan("bottom", node->style.position[CSS_BOTTOM]);
  }

  if (options & CSS_PRINT_CHILDREN && node->children_count > 0) {
    printf("children: [\n");
    for (int i = 0; i < node->children_count; ++i) {
      print_css_node_rec(node->get_child(node->context, i), options, level + 1);
    }
    indent(level);
    printf("]},\n");
  } else {
    printf("},\n");
  }
}

void print_css_node(css_node_t *node, css_print_options_t options) {
  print_css_node_rec(node, options, 0);
}


static css_position_t leading[2] = {
  /* CSS_FLEX_DIRECTION_COLUMN = */ CSS_TOP,
  /* CSS_FLEX_DIRECTION_ROW = */ CSS_LEFT
};
static css_position_t trailing[2] = {
  /* CSS_FLEX_DIRECTION_COLUMN = */ CSS_BOTTOM,
  /* CSS_FLEX_DIRECTION_ROW = */ CSS_RIGHT
};
static css_position_t pos[2] = {
  /* CSS_FLEX_DIRECTION_COLUMN = */ CSS_TOP,
  /* CSS_FLEX_DIRECTION_ROW = */ CSS_LEFT
};
static css_dimension_t dim[2] = {
  /* CSS_FLEX_DIRECTION_COLUMN = */ CSS_HEIGHT,
  /* CSS_FLEX_DIRECTION_ROW = */ CSS_WIDTH
};



static float getMargin(css_node_t *node, int location) {
  return node->style.margin[location];
}

static float getPadding(css_node_t *node, int location) {
  if (node->style.padding[location] >= 0) {
    return node->style.padding[location];
  }
  return 0;
}

static float getBorder(css_node_t *node, int location) {
  if (node->style.border[location] >= 0) {
    return node->style.border[location];
  }
  return 0;
}

static float getPaddingAndBorder(css_node_t *node, int location) {
  return getPadding(node, location) + getBorder(node, location);
}

static float getMarginAxis(css_node_t *node, css_flex_direction_t axis) {
  return getMargin(node, leading[axis]) + getMargin(node, trailing[axis]);
}

static float getPaddingAndBorderAxis(css_node_t *node, css_flex_direction_t axis) {
  return getPaddingAndBorder(node, leading[axis]) + getPaddingAndBorder(node, trailing[axis]);
}

static css_position_type_t getPositionType(css_node_t *node) {
  return node->style.position_type;
}

static css_justify_t getJustifyContent(css_node_t *node) {
  return node->style.justify_content;
}

static css_align_t getAlignItem(css_node_t *node, css_node_t *child) {
  if (child->style.align_self != CSS_ALIGN_AUTO) {
    return child->style.align_self;
  }
  return node->style.align_items;
}

static css_flex_direction_t getFlexDirection(css_node_t *node) {
  return node->style.flex_direction;
}

static float getFlex(css_node_t *node) {
  return node->style.flex;
}

static bool isFlex(css_node_t *node) {
  return (
    getPositionType(node) == CSS_POSITION_RELATIVE &&
    getFlex(node) > 0
  );
}

static bool isFlexWrap(css_node_t *node) {
  return node->style.flex_wrap == CSS_WRAP;
}

static float getDimWithMargin(css_node_t *node, css_flex_direction_t axis) {
  return node->layout.dimensions[dim[axis]] +
    getMargin(node, leading[axis]) +
    getMargin(node, trailing[axis]);
}

static bool isDimDefined(css_node_t *node, css_flex_direction_t axis) {
  return !isUndefined(node->style.dimensions[dim[axis]]);
}

static bool isPosDefined(css_node_t *node, css_position_t position) {
  return !isUndefined(node->style.position[position]);
}

static bool isMeasureDefined(css_node_t *node) {
  return node->measure;
}

static float getPosition(css_node_t *node, css_position_t position) {
  float result = node->style.position[position];
  if (!isUndefined(result)) {
    return result;
  }
  return 0;
}

// When the user specifically sets a value for width or height
static void setDimensionFromStyle(css_node_t *node, css_flex_direction_t axis) {
  // The parent already computed us a width or height. We just skip it
  if (!isUndefined(node->layout.dimensions[dim[axis]])) {
    return;
  }
  // We only run if there's a width or height defined
  if (!isDimDefined(node, axis)) {
    return;
  }

  // The dimensions can never be smaller than the padding and border
  node->layout.dimensions[dim[axis]] = fmaxf(
    node->style.dimensions[dim[axis]],
    getPaddingAndBorderAxis(node, axis)
  );
}

// If both left and right are defined, then use left. Otherwise return
// +left or -right depending on which is defined.
static float getRelativePosition(css_node_t *node, css_flex_direction_t axis) {
  float lead = node->style.position[leading[axis]];
  if (!isUndefined(lead)) {
    return lead;
  }
  return -getPosition(node, trailing[axis]);
}

static void layoutNodeImpl(css_node_t *node, float parentMaxWidth) {
  /** START_GENERATED **/
  css_flex_direction_t mainAxis = getFlexDirection(node);
  css_flex_direction_t crossAxis = mainAxis == CSS_FLEX_DIRECTION_ROW ?
    CSS_FLEX_DIRECTION_COLUMN :
    CSS_FLEX_DIRECTION_ROW;

  // Handle width and height style attributes
  setDimensionFromStyle(node, mainAxis);
  setDimensionFromStyle(node, crossAxis);

  // The position is set by the parent, but we need to complete it with a
  // delta composed of the margin and left/top/right/bottom
  node->layout.position[leading[mainAxis]] += getMargin(node, leading[mainAxis]) +
    getRelativePosition(node, mainAxis);
  node->layout.position[leading[crossAxis]] += getMargin(node, leading[crossAxis]) +
    getRelativePosition(node, crossAxis);

  if (isMeasureDefined(node)) {
    float width = CSS_UNDEFINED;
    if (isDimDefined(node, CSS_FLEX_DIRECTION_ROW)) {
      width = node->style.dimensions[CSS_WIDTH];
    } else if (!isUndefined(node->layout.dimensions[dim[CSS_FLEX_DIRECTION_ROW]])) {
      width = node->layout.dimensions[dim[CSS_FLEX_DIRECTION_ROW]];
    } else {
      width = parentMaxWidth -
        getMarginAxis(node, CSS_FLEX_DIRECTION_ROW);
    }
    width -= getPaddingAndBorderAxis(node, CSS_FLEX_DIRECTION_ROW);

    // We only need to give a dimension for the text if we haven't got any
    // for it computed yet. It can either be from the style attribute or because
    // the element is flexible.
    bool isRowUndefined = !isDimDefined(node, CSS_FLEX_DIRECTION_ROW) &&
      isUndefined(node->layout.dimensions[dim[CSS_FLEX_DIRECTION_ROW]]);
    bool isColumnUndefined = !isDimDefined(node, CSS_FLEX_DIRECTION_COLUMN) &&
      isUndefined(node->layout.dimensions[dim[CSS_FLEX_DIRECTION_COLUMN]]);

    // Let's not measure the text if we already know both dimensions
    if (isRowUndefined || isColumnUndefined) {
      css_dim_t measure_dim = node->measure(
        node->context,
        width
      );
      if (isRowUndefined) {
        node->layout.dimensions[CSS_WIDTH] = measure_dim.dimensions[CSS_WIDTH] +
          getPaddingAndBorderAxis(node, CSS_FLEX_DIRECTION_ROW);
      }
      if (isColumnUndefined) {
        node->layout.dimensions[CSS_HEIGHT] = measure_dim.dimensions[CSS_HEIGHT] +
          getPaddingAndBorderAxis(node, CSS_FLEX_DIRECTION_COLUMN);
      }
    }
    return;
  }

  // Pre-fill some dimensions straight from the parent
  for (int i = 0; i < node->children_count; ++i) {
    css_node_t* child = node->get_child(node->context, i);
    // Pre-fill cross axis dimensions when the child is using stretch before
    // we call the recursive layout pass
    if (getAlignItem(node, child) == CSS_ALIGN_STRETCH &&
        getPositionType(child) == CSS_POSITION_RELATIVE &&
        !isUndefined(node->layout.dimensions[dim[crossAxis]]) &&
        !isDimDefined(child, crossAxis)) {
      child->layout.dimensions[dim[crossAxis]] = fmaxf(
        node->layout.dimensions[dim[crossAxis]] -
          getPaddingAndBorderAxis(node, crossAxis) -
          getMarginAxis(child, crossAxis),
        // You never want to go smaller than padding
        getPaddingAndBorderAxis(child, crossAxis)
      );
    } else if (getPositionType(child) == CSS_POSITION_ABSOLUTE) {
      // Pre-fill dimensions when using absolute position and both offsets for the axis are defined (either both
      // left and right or top and bottom).
      for (int ii = 0; ii < 2; ii++) {
        css_flex_direction_t axis = (ii != 0) ? CSS_FLEX_DIRECTION_ROW : CSS_FLEX_DIRECTION_COLUMN;
        if (!isUndefined(node->layout.dimensions[dim[axis]]) &&
            !isDimDefined(child, axis) &&
            isPosDefined(child, leading[axis]) &&
            isPosDefined(child, trailing[axis])) {
          child->layout.dimensions[dim[axis]] = fmaxf(
            node->layout.dimensions[dim[axis]] -
            getPaddingAndBorderAxis(node, axis) -
            getMarginAxis(child, axis) -
            getPosition(child, leading[axis]) -
            getPosition(child, trailing[axis]),
            // You never want to go smaller than padding
            getPaddingAndBorderAxis(child, axis)
          );
        }
      }
    }
  }

  float definedMainDim = CSS_UNDEFINED;
  if (!isUndefined(node->layout.dimensions[dim[mainAxis]])) {
    definedMainDim = node->layout.dimensions[dim[mainAxis]] -
        getPaddingAndBorderAxis(node, mainAxis);
  }

  // We want to execute the next two loops one per line with flex-wrap
  int startLine = 0;
  int endLine = 0;
  int nextLine = 0;
  // We aggregate the total dimensions of the container in those two variables
  float linesCrossDim = 0;
  float linesMainDim = 0;
  while (endLine != node->children_count) {
    // <Loop A> Layout non flexible children and count children by type

    // mainContentDim is accumulation of the dimensions and margin of all the
    // non flexible children. This will be used in order to either set the
    // dimensions of the node if none already exist, or to compute the
    // remaining space left for the flexible children.
    float mainContentDim = 0;

    // There are three kind of children, non flexible, flexible and absolute.
    // We need to know how many there are in order to distribute the space.
    int flexibleChildrenCount = 0;
    float totalFlexible = 0;
    int nonFlexibleChildrenCount = 0;
    for (int i = startLine; i < node->children_count; ++i) {
      css_node_t* child = node->get_child(node->context, i);
      float nextContentDim = 0;

      // It only makes sense to consider a child flexible if we have a computed
      // dimension for the node->
      if (!isUndefined(node->layout.dimensions[dim[mainAxis]]) && isFlex(child)) {
        flexibleChildrenCount++;
        totalFlexible += getFlex(child);

        // Even if we don't know its exact size yet, we already know the padding,
        // border and margin. We'll use this partial information to compute the
        // remaining space.
        nextContentDim = getPaddingAndBorderAxis(child, mainAxis) +
          getMarginAxis(child, mainAxis);

      } else {
        float maxWidth = CSS_UNDEFINED;
        if (mainAxis == CSS_FLEX_DIRECTION_ROW) {
          // do nothing
        } else if (isDimDefined(node, CSS_FLEX_DIRECTION_ROW)) {
          maxWidth = node->layout.dimensions[dim[CSS_FLEX_DIRECTION_ROW]] -
            getPaddingAndBorderAxis(node, CSS_FLEX_DIRECTION_ROW);
        } else {
          maxWidth = parentMaxWidth -
            getMarginAxis(node, CSS_FLEX_DIRECTION_ROW) -
            getPaddingAndBorderAxis(node, CSS_FLEX_DIRECTION_ROW);
        }

        // This is the main recursive call. We layout non flexible children.
        if (nextLine == 0) {
          layoutNode(child, maxWidth);
        }

        // Absolute positioned elements do not take part of the layout, so we
        // don't use them to compute mainContentDim
        if (getPositionType(child) == CSS_POSITION_RELATIVE) {
          nonFlexibleChildrenCount++;
          // At this point we know the final size and margin of the element.
          nextContentDim = getDimWithMargin(child, mainAxis);
        }
      }

      // The element we are about to add would make us go to the next line
      if (isFlexWrap(node) &&
          !isUndefined(node->layout.dimensions[dim[mainAxis]]) &&
          mainContentDim + nextContentDim > definedMainDim) {
        nonFlexibleChildrenCount--;
        nextLine = i + 1;
        break;
      }
      nextLine = 0;
      mainContentDim += nextContentDim;
      endLine = i + 1;
    }

    // <Loop B> Layout flexible children and allocate empty space

    // In order to position the elements in the main axis, we have two
    // controls. The space between the beginning and the first element
    // and the space between each two elements.
    float leadingMainDim = 0;
    float betweenMainDim = 0;

    // The remaining available space that needs to be allocated
    float remainingMainDim = 0;
    if (!isUndefined(node->layout.dimensions[dim[mainAxis]])) {
      remainingMainDim = definedMainDim - mainContentDim;
    } else {
      remainingMainDim = fmaxf(mainContentDim, 0) - mainContentDim;
    }

    // If there are flexible children in the mix, they are going to fill the
    // remaining space
    if (flexibleChildrenCount != 0) {
      float flexibleMainDim = remainingMainDim / totalFlexible;

      // The non flexible children can overflow the container, in this case
      // we should just assume that there is no space available.
      if (flexibleMainDim < 0) {
        flexibleMainDim = 0;
      }
      // We iterate over the full array and only apply the action on flexible
      // children. This is faster than actually allocating a new array that
      // contains only flexible children.
      for (int i = startLine; i < endLine; ++i) {
        css_node_t* child = node->get_child(node->context, i);
        if (isFlex(child)) {
          // At this point we know the final size of the element in the main
          // dimension
          child->layout.dimensions[dim[mainAxis]] = flexibleMainDim * getFlex(child) +
            getPaddingAndBorderAxis(child, mainAxis);

          float maxWidth = CSS_UNDEFINED;
          if (mainAxis == CSS_FLEX_DIRECTION_ROW) {
            // do nothing
          } else if (isDimDefined(node, CSS_FLEX_DIRECTION_ROW)) {
            maxWidth = node->layout.dimensions[dim[CSS_FLEX_DIRECTION_ROW]] -
              getPaddingAndBorderAxis(node, CSS_FLEX_DIRECTION_ROW);
          } else {
            maxWidth = parentMaxWidth -
              getMarginAxis(node, CSS_FLEX_DIRECTION_ROW) -
              getPaddingAndBorderAxis(node, CSS_FLEX_DIRECTION_ROW);
          }

          // And we recursively call the layout algorithm for this child
          layoutNode(child, maxWidth);
        }
      }

    // We use justifyContent to figure out how to allocate the remaining
    // space available
    } else {
      css_justify_t justifyContent = getJustifyContent(node);
      if (justifyContent == CSS_JUSTIFY_FLEX_START) {
        // Do nothing
      } else if (justifyContent == CSS_JUSTIFY_CENTER) {
        leadingMainDim = remainingMainDim / 2;
      } else if (justifyContent == CSS_JUSTIFY_FLEX_END) {
        leadingMainDim = remainingMainDim;
      } else if (justifyContent == CSS_JUSTIFY_SPACE_BETWEEN) {
        remainingMainDim = fmaxf(remainingMainDim, 0);
        if (flexibleChildrenCount + nonFlexibleChildrenCount - 1 != 0) {
          betweenMainDim = remainingMainDim /
            (flexibleChildrenCount + nonFlexibleChildrenCount - 1);
        } else {
          betweenMainDim = 0;
        }
      } else if (justifyContent == CSS_JUSTIFY_SPACE_AROUND) {
        // Space on the edges is half of the space between elements
        betweenMainDim = remainingMainDim /
          (flexibleChildrenCount + nonFlexibleChildrenCount);
        leadingMainDim = betweenMainDim / 2;
      }
    }

    // <Loop C> Position elements in the main axis and compute dimensions

    // At this point, all the children have their dimensions set. We need to
    // find their position. In order to do that, we accumulate data in
    // variables that are also useful to compute the total dimensions of the
    // container!
    float crossDim = 0;
    float mainDim = leadingMainDim +
      getPaddingAndBorder(node, leading[mainAxis]);

    for (int i = startLine; i < endLine; ++i) {
      css_node_t* child = node->get_child(node->context, i);

      if (getPositionType(child) == CSS_POSITION_ABSOLUTE &&
          isPosDefined(child, leading[mainAxis])) {
        // In case the child is position absolute and has left/top being
        // defined, we override the position to whatever the user said
        // (and margin/border).
        child->layout.position[pos[mainAxis]] = getPosition(child, leading[mainAxis]) +
          getBorder(node, leading[mainAxis]) +
          getMargin(child, leading[mainAxis]);
      } else {
        // If the child is position absolute (without top/left) or relative,
        // we put it at the current accumulated offset.
        child->layout.position[pos[mainAxis]] += mainDim;
      }

      // Now that we placed the element, we need to update the variables
      // We only need to do that for relative elements. Absolute elements
      // do not take part in that phase.
      if (getPositionType(child) == CSS_POSITION_RELATIVE) {
        // The main dimension is the sum of all the elements dimension plus
        // the spacing.
        mainDim += betweenMainDim + getDimWithMargin(child, mainAxis);
        // The cross dimension is the max of the elements dimension since there
        // can only be one element in that cross dimension.
        crossDim = fmaxf(crossDim, getDimWithMargin(child, crossAxis));
      }
    }

    float containerCrossAxis = node->layout.dimensions[dim[crossAxis]];
    if (isUndefined(node->layout.dimensions[dim[crossAxis]])) {
      containerCrossAxis = fmaxf(
        // For the cross dim, we add both sides at the end because the value
        // is aggregate via a max function. Intermediate negative values
        // can mess this computation otherwise
        crossDim + getPaddingAndBorderAxis(node, crossAxis),
        getPaddingAndBorderAxis(node, crossAxis)
      );
    }

    // <Loop D> Position elements in the cross axis

    for (int i = startLine; i < endLine; ++i) {
      css_node_t* child = node->get_child(node->context, i);

      if (getPositionType(child) == CSS_POSITION_ABSOLUTE &&
          isPosDefined(child, leading[crossAxis])) {
        // In case the child is absolutely positionned and has a
        // top/left/bottom/right being set, we override all the previously
        // computed positions to set it correctly.
        child->layout.position[pos[crossAxis]] = getPosition(child, leading[crossAxis]) +
          getBorder(node, leading[crossAxis]) +
          getMargin(child, leading[crossAxis]);

      } else {
        float leadingCrossDim = getPaddingAndBorder(node, leading[crossAxis]);

        // For a relative children, we're either using alignItems (parent) or
        // alignSelf (child) in order to determine the position in the cross axis
        if (getPositionType(child) == CSS_POSITION_RELATIVE) {
          css_align_t alignItem = getAlignItem(node, child);
          if (alignItem == CSS_ALIGN_FLEX_START) {
            // Do nothing
          } else if (alignItem == CSS_ALIGN_STRETCH) {
            // You can only stretch if the dimension has not already been set
            // previously.
            if (!isDimDefined(child, crossAxis)) {
              child->layout.dimensions[dim[crossAxis]] = fmaxf(
                containerCrossAxis -
                  getPaddingAndBorderAxis(node, crossAxis) -
                  getMarginAxis(child, crossAxis),
                // You never want to go smaller than padding
                getPaddingAndBorderAxis(child, crossAxis)
              );
            }
          } else {
            // The remaining space between the parent dimensions+padding and child
            // dimensions+margin.
            float remainingCrossDim = containerCrossAxis -
              getPaddingAndBorderAxis(node, crossAxis) -
              getDimWithMargin(child, crossAxis);

            if (alignItem == CSS_ALIGN_CENTER) {
              leadingCrossDim += remainingCrossDim / 2;
            } else { // CSS_ALIGN_FLEX_END
              leadingCrossDim += remainingCrossDim;
            }
          }
        }

        // And we apply the position
        child->layout.position[pos[crossAxis]] += linesCrossDim + leadingCrossDim;
      }
    }

    linesCrossDim += crossDim;
    linesMainDim = fmaxf(linesMainDim, mainDim);
    startLine = endLine;
  }

  // If the user didn't specify a width or height, and it has not been set
  // by the container, then we set it via the children.
  if (isUndefined(node->layout.dimensions[dim[mainAxis]])) {
    node->layout.dimensions[dim[mainAxis]] = fmaxf(
      // We're missing the last padding at this point to get the final
      // dimension
      linesMainDim + getPaddingAndBorder(node, trailing[mainAxis]),
      // We can never assign a width smaller than the padding and borders
      getPaddingAndBorderAxis(node, mainAxis)
    );
  }

  if (isUndefined(node->layout.dimensions[dim[crossAxis]])) {
    node->layout.dimensions[dim[crossAxis]] = fmaxf(
      // For the cross dim, we add both sides at the end because the value
      // is aggregate via a max function. Intermediate negative values
      // can mess this computation otherwise
      linesCrossDim + getPaddingAndBorderAxis(node, crossAxis),
      getPaddingAndBorderAxis(node, crossAxis)
    );
  }

  // <Loop E> Calculate dimensions for absolutely positioned elements

  for (int i = 0; i < node->children_count; ++i) {
    css_node_t* child = node->get_child(node->context, i);
    if (getPositionType(child) == CSS_POSITION_ABSOLUTE) {
      // Pre-fill dimensions when using absolute position and both offsets for the axis are defined (either both
      // left and right or top and bottom).
      for (int ii = 0; ii < 2; ii++) {
        css_flex_direction_t axis = (ii != 0) ? CSS_FLEX_DIRECTION_ROW : CSS_FLEX_DIRECTION_COLUMN;
        if (!isUndefined(node->layout.dimensions[dim[axis]]) &&
            !isDimDefined(child, axis) &&
            isPosDefined(child, leading[axis]) &&
            isPosDefined(child, trailing[axis])) {
          child->layout.dimensions[dim[axis]] = fmaxf(
            node->layout.dimensions[dim[axis]] -
            getPaddingAndBorderAxis(node, axis) -
            getMarginAxis(child, axis) -
            getPosition(child, leading[axis]) -
            getPosition(child, trailing[axis]),
            // You never want to go smaller than padding
            getPaddingAndBorderAxis(child, axis)
          );
        }
      }
      for (int ii = 0; ii < 2; ii++) {
        css_flex_direction_t axis = (ii != 0) ? CSS_FLEX_DIRECTION_ROW : CSS_FLEX_DIRECTION_COLUMN;
        if (isPosDefined(child, trailing[axis]) &&
            !isPosDefined(child, leading[axis])) {
          child->layout.position[leading[axis]] =
            node->layout.dimensions[dim[axis]] -
            child->layout.dimensions[dim[axis]] -
            getPosition(child, trailing[axis]);
        }
      }
    }
  }
  /** END_GENERATED **/
}

void layoutNode(css_node_t *node, float parentMaxWidth) {
  css_layout_t *layout = &node->layout;
  layout->should_update = true;

  bool skipLayout =
    !node->is_dirty(node->context) &&
    eq(layout->last_requested_dimensions[CSS_WIDTH], layout->dimensions[CSS_WIDTH]) &&
    eq(layout->last_requested_dimensions[CSS_HEIGHT], layout->dimensions[CSS_HEIGHT]) &&
    eq(layout->last_parent_max_width, parentMaxWidth);

  if (skipLayout) {
    layout->dimensions[CSS_WIDTH] = layout->last_dimensions[CSS_WIDTH];
    layout->dimensions[CSS_HEIGHT] = layout->last_dimensions[CSS_HEIGHT];
    layout->position[CSS_TOP] = layout->last_position[CSS_TOP];
    layout->position[CSS_LEFT] = layout->last_position[CSS_LEFT];
  } else {
    layout->last_requested_dimensions[CSS_WIDTH] = layout->dimensions[CSS_WIDTH];
    layout->last_requested_dimensions[CSS_HEIGHT] = layout->dimensions[CSS_HEIGHT];
    layout->last_parent_max_width = parentMaxWidth;

    layoutNodeImpl(node, parentMaxWidth);

    layout->last_dimensions[CSS_WIDTH] = layout->dimensions[CSS_WIDTH];
    layout->last_dimensions[CSS_HEIGHT] = layout->dimensions[CSS_HEIGHT];
    layout->last_position[CSS_TOP] = layout->position[CSS_TOP];
    layout->last_position[CSS_LEFT] = layout->position[CSS_LEFT];
  }
}