惯性聚合 高效追踪和阅读你感兴趣的博客、新闻、科技资讯
阅读原文 在惯性聚合中打开

推荐订阅源

D
DataBreaches.Net
S
Schneier on Security
T
The Exploit Database - CXSecurity.com
Webroot Blog
Webroot Blog
AI
AI
P
Palo Alto Networks Blog
Attack and Defense Labs
Attack and Defense Labs
WordPress大学
WordPress大学
月光博客
月光博客
阮一峰的网络日志
阮一峰的网络日志
Spread Privacy
Spread Privacy
T
Tor Project blog
罗磊的独立博客
小众软件
小众软件
S
Security Affairs
酷 壳 – CoolShell
酷 壳 – CoolShell
量子位
Apple Machine Learning Research
Apple Machine Learning Research
T
Threatpost
NISL@THU
NISL@THU
博客园_首页
PCI Perspectives
PCI Perspectives
大猫的无限游戏
大猫的无限游戏
IT之家
IT之家
N
News and Events Feed by Topic
freeCodeCamp Programming Tutorials: Python, JavaScript, Git & More
Forbes - Security
Forbes - Security
博客园 - 叶小钗
D
Darknet – Hacking Tools, Hacker News & Cyber Security
OSCHINA 社区最新新闻
OSCHINA 社区最新新闻
Last Week in AI
Last Week in AI
L
LINUX DO - 热门话题
T
Threat Research - Cisco Blogs
cs.AI updates on arXiv.org
cs.AI updates on arXiv.org
腾讯CDC
Security Latest
Security Latest
Exploit-DB.com RSS Feed
Exploit-DB.com RSS Feed
The Cloudflare Blog
A
About on SuperTechFans
爱范儿
爱范儿
Threat Intelligence Blog | Flashpoint
Threat Intelligence Blog | Flashpoint
TaoSecurity Blog
TaoSecurity Blog
宝玉的分享
宝玉的分享
G
GRAHAM CLULEY
雷峰网
雷峰网
F
Full Disclosure
I
Intezer
Cloudbric
Cloudbric
博客园 - 三生石上(FineUI控件)
U
Unit 42

CSS Articles by Temani Afif

Get Ready For the Powerful CSS border-shape Property! | CSS-Tricks Let’s Play With Gap Decorations! How to Control Infinite CSS Animations (Part 2 of 2) How to Control Infinite CSS Animations (Part 1 of 2) Two Circles, One Arrow, and Anchor Positioning Making a Responsive Pyramidal Grid With Modern CSS | CSS-Tricks How to Create a CSS-only Elastic Text Effect Making Complex CSS Shapes Using shape() | CSS-Tricks Responsive Hexagon Grid Using Modern CSS | CSS-Tricks Responsive List of Avatars Using Modern CSS (Part 2) | CSS-Tricks Responsive List of Avatars Using Modern CSS (Part 1) | CSS-Tricks Perfectly Pointed Tooltips: To The Corners Perfectly Pointed Tooltips: All Four Sides Perfectly Pointed Tooltips: A Foundation Sequential linear() Animation With N Elements | CSS-Tricks Infinite Marquee Animation using Modern CSS Better CSS Shapes Using shape() — Part 4: Close and Move | CSS-Tricks Drawing CSS Shapes using corner-shape Better CSS Shapes Using shape() — Part 3: Curves | CSS-Tricks Better CSS Shapes Using shape() — Part 2: More on Arcs | CSS-Tricks Better CSS Shapes Using shape() — Part 1: Lines and Arcs | CSS-Tricks Creating Blob Shapes using clip-path: shape() Creating Flower Shapes using clip-path: shape() Custom progress element using the attr() function A CSS-Only Star Rating Component and More! (Part 2) | CSS-Tricks A CSS-Only Star Rating Component and More! (Part 1) | CSS-Tricks How to Create Wavy Boxes Using CSS Full-Bleed Layout with Modern CSS Fancy Menu Navigation Using Anchor Positioning | CSS-Tricks How to Create a Zig-Zag Box Using CSS How to Create Zig-Zag CSS Loaders Using One Element Custom Progress Element Using Anchor Positioning & Scroll-Driven Animations How to Create Filling CSS Loaders Using One Element How to Create Curved-Edge and Rounded-Edge Shapes Using CSS CSS Tricks That Use Only One Gradient | CSS-Tricks How to create Shapes with Inner Curves using CSS Mask Custom Range Slider Using Anchor Positioning & Scroll-Driven Animations How to Get the Width/Height of Any Element in Only CSS How Keyboard Navigation Works in a CSS Game How To Create Cut-Out Shapes using The clip-path property The Modern Guide For Making CSS Shapes — Smashing Magazine css-shape.com: The Ultimate Collection of CSS-only Shapes ⚡️ Sliding 3D Image Frames In CSS — Smashing Magazine CSS Tricks To Master The clip-path Property Creating Wavy Circles with Fancy Animations in CSS Modern CSS Tooltips And Speech Bubbles (Part 2) — Smashing Magazine Do you need a Tooltip or a Speech Bubble? I have created 100 using CSS 😲 Modern CSS Tooltips And Speech Bubbles (Part 1) — Smashing Magazine Creating Flower Shapes using CSS Mask & Trigonometric Functions CSS Shapes: The Triangle The Complex But Awesome CSS border-image Property — Smashing Magazine CSS Tricks to add 3D Effects to your Text CSS Responsive Multi-Line Ribbon Shapes (Part 2) — Smashing Magazine CSS Responsive Multi-Line Ribbon Shapes (Part 1) — Smashing Magazine I have made 100+ CSS-only Ribbon Shapes | The Perfect Collection 🎀 How to create a CSS-only infinite scroll animation Re-Creating The Pop-Out Hover Effect With Modern CSS (Part 2) — Smashing Magazine Re-Creating The Pop-Out Hover Effect With Modern CSS (Part 1) — Smashing Magazine How to Create CSS Ribbon Shapes with a Single Element CSS Shapes: The Ribbon Revealing Images With CSS Mask Animations — Smashing Magazine css-loaders.com: The Biggest Collection of Loading Animations (more than 500 🤯) How To Define An Array Of Colors With CSS — Smashing Magazine CSS effects on images II Shines, Perspective, And Rotations: Fancy CSS 3D Effects For Images — Smashing Magazine What's your Lucky CSS Pattern? Check It Now! How to Add a CSS Reveal Animation to Your Images Modern Layouts using CSS Grid I created 100+ unique CSS patterns | The best collection 🤩 How to Create a Custom Range Slider Using CSS CSS Shapes: The Heart CSS Shapes: Polygon & Starburst A Text Reveal Animation using CSS CSS Tip: learn CSS the easy way! How to build a CSS-only accordion How to create Breadcrumb Navigation with CSS Different Ways to Get CSS Gradient Shadows | CSS-Tricks A CSS-only responsive Stepper component A Fancy Hover Effect For Your Avatar | CSS-Tricks How to make a zoom effect using CSS Creating a Custom Cursor using CSS CSS Infinite 3D Sliders | CSS-Tricks CSS Infinite Slider Flipping Through Polaroid Images | CSS-Tricks How to create a responsive sidebar menu using CSS CSS Infinite and Circular Rotating Image Slider | CSS-Tricks Making Static Noise From a Weird CSS Gradient Bug | CSS-Tricks CSS Grid and Custom Shapes, Part 3 | CSS-Tricks Fancy Image Decorations: Outlines and Complex Animations | CSS-Tricks Fancy Image Decorations: Masks and Advanced Hover Effects | CSS-Tricks Fancy Image Decorations: Single Element Magic | CSS-Tricks How to create an infinite image slider using CSS How to Create Wavy Shapes & Patterns in CSS | CSS-Tricks How I Made a Pure CSS Puzzle Game | CSS-Tricks How to create a Tooltip/Speech Bubble using CSS CSS Grid and Custom Shapes, Part 1 | CSS-Tricks Zooming Images in a Grid Layout | CSS-Tricks How to create a CSS-only loader with one element Exploring CSS Grid’s Implicit Grid and Auto-Placement Powers | CSS-Tricks How to create background pattern using CSS & conic-gradient Single Element Loaders: The Bars | CSS-Tricks
CSS Grid and Custom Shapes, Part 2 | CSS-Tricks
Temani Afif · 2022-08-22 · via CSS Articles by Temani Afif

Alright, so the last time we checked in, we were using CSS Grid and combining them with CSS clip-path and mask techniques to create grids with fancy shapes.

Here’s just one of the fantastic grids we made together:

Ready for the second round? We are still working with CSS Grid, clip-path, and mask, but by the end of this article, we’ll end up with different ways to arrange images on the grid, including some rad hover effects that make for an authentic, interactive experience to view pictures.

And guess what? We’re using the same markup that we used last time. Here’s that again:

<div class="gallery">
  <img src="..." alt="...">
  <img src="..." alt="...">
  <img src="..." alt="...">
  <img src="..." alt="...">
  <!-- as many times as we want -->
</div>

Like the previous article, we only need a container with images inside. Nothing more!

Nested Image Grid

Last time, our grids were, well, typical image grids. Other than the neat shapes we masked them with, they were pretty standard symmetrical grids as far as how we positioned the images inside.

Let’s try nesting an image in the center of the grid:

We start by setting a 2✕2 grid for four images:

.gallery {
  --s: 200px; /* controls the image size */
  --g: 10px; /* controls the gap between images */

  display: grid;
  gap: var(--g);
  grid-template-columns: repeat(2, auto);
}
.gallery > img {
  width: var(--s);
  aspect-ratio: 1;
  object-fit: cover;
}

Nothing complex yet. The next step is to cut the corner of our images to create the space for the nested image. I already have a detailed article on how to cut corners using clip-path and mask. You can also use my online generator to get the CSS for masking corners.

What we need here is to cut out the corners at an angle equal to 90deg. We can use the same conic-gradient technique from that article to do that:

.gallery > img {
   mask: conic-gradient(from var(--_a), #0000 90deg, #000 0);
}
.gallery > img:nth-child(1) { --_a: 90deg; }
.gallery > img:nth-child(2) { --_a: 180deg; }
.gallery > img:nth-child(3) { --_a: 0deg; }
.gallery > img:nth-child(4) { --_a:-90deg; }

We could use the clip-path method for cutting corners from that same article, but masking with gradients is more suitable here because we have the same configuration for all the images — all we need is a rotation (defined with the variable --_a) get the effect, so we’re masking from the inside instead of the outside edges.

Two by two grid of images with a white square stacked on top in the center.

Now we can place the nested image inside the masked space. First, let’s make sure we have a fifth image element in the HTML:

<div class="gallery">
  <img src="..." alt="...">
  <img src="..." alt="...">
  <img src="..." alt="...">
  <img src="..." alt="...">
  <img src="..." alt="...">
</div>

We are going to rely on the good ol’ absolute positioning to place it in there:

.gallery > img:nth-child(5) {
  position: absolute;
  inset: calc(50% - .5*var(--s));
  clip-path: inset(calc(var(--g) / 4));
}

The inset property allows us to place the image at the center using a single declaration. We know the size of the image (defined with the variable --s), and we know that the container’s size equals 100%. We do some math, and the distance from each edge should be equal to (100% - var(--s))/2.

Diagram of the widths needed to complete the design.

You might be wondering why we’re using clip-path at all here. We’re using it with the nested image to have a consistent gap. If we were to remove it, you would notice that we don’t have the same gap between all the images. This way, we’re cutting a little bit from the fifth image to get the proper spacing around it.

The complete code again:

.gallery {
  --s: 200px; /* controls the image size */
  --g: 10px;  /* controls the gap between images */
  
  display: grid;
  gap: var(--g);
  grid-template-columns: repeat(2, auto);
  position: relative;
}

.gallery > img {
  width: var(--s);
  aspect-ratio: 1;
  object-fit: cover;
  mask: conic-gradient(from var(--_a), #0000 90deg, #000 0);
}

.gallery > img:nth-child(1) {--_a: 90deg}
.gallery > img:nth-child(2) {--_a:180deg}
.gallery > img:nth-child(3) {--_a:  0deg}
.gallery > img:nth-child(4) {--_a:-90deg}
.gallery > img:nth-child(5) {
  position: absolute;
  inset: calc(50% - .5*var(--s));
  clip-path: inset(calc(var(--g) / 4));
}

Now, many of you might also be wondering: why all the complex stuff when we can place the last image on the top and add a border to it? That would hide the images underneath the nested image without a mask, right?

That’s true, and we will get the following:

No mask, no clip-path. Yes, the code is easy to understand, but there is a little drawback: the border color needs to be the same as the main background to make the illusion perfect. This little drawback is enough for me to make the code more complex in exchange for real transparency independent of the background. I am not saying a border approach is bad or wrong. I would recommend it in most cases where the background is known. But we are here to explore new stuff and, most important, build components that don’t depend on their environment.

Let’s try another shape this time:

This time, we made the nested image a circle instead of a square. That’s an easy task with border-radius But we need to use a circular cut-out for the other images. This time, though, we will rely on a radial-gradient() instead of a conic-gradient() to get that nice rounded look.

.gallery > img {
  mask: 
    radial-gradient(farthest-side at var(--_a),
      #0000 calc(50% + var(--g)/2), #000 calc(51% + var(--g)/2));
}
.gallery > img:nth-child(1) { --_a: calc(100% + var(--g)/2) calc(100% + var(--g)/2); }
.gallery > img:nth-child(2) { --_a: calc(0%   - var(--g)/2) calc(100% + var(--g)/2); }
.gallery > img:nth-child(3) { --_a: calc(100% + var(--g)/2) calc(0%   - var(--g)/2); }
.gallery > img:nth-child(4) { --_a: calc(0%   - var(--g)/2) calc(0%   - var(--g)/2); }

All the images use the same configuration as the previous example, but we update the center point each time.

Diagram showing the center values for each quadrant of the grid.

The above figure illustrates the center point for each circle. Still, in the actual code, you will notice that I am also accounting for the gap to ensure all the points are at the same position (the center of the grid) to get a continuous circle if we combine them.

Now that we have our layout let’s talk about the hover effect. In case you didn’t notice, a cool hover effect increases the size of the nested image and adjusts everything else accordingly. Increasing the size is a relatively easy task, but updating the gradient is more complicated since, by default, gradients cannot be animated. To overcome this, I will use a font-size hack to be able to animate the radial gradient.

If you check the code of the gradient, you can see that I am adding 1em:

mask: 
    radial-gradient(farthest-side at var(--_a),
      #0000 calc(50% + var(--g)/2 + 1em), #000 calc(51% + var(--g)/2 + 1em));

It’s known that em units are relative to the parent element’s font-size, so changing the font-size of the .gallery will also change the computed em value — this is the trick we are using. We are animating the font-size from a value of 0 to a given value and, as a result, the gradient is animated, making the cut-out part larger, following the size of the nested image that is getting bigger.

Here is the code that highlights the parts involved in the hover effect:

.gallery {
  --s: 200px; /* controls the image size */
  --g: 10px; /* controls the gaps between images */

  font-size: 0; /* initially we have 1em = 0 */
  transition: .5s;
}
/* we increase the cut-out by 1em */
.gallery > img {
  mask: 
    radial-gradient(farthest-side at var(--_a),
      #0000 calc(50% + var(--g)/2 + 1em), #000 calc(51% + var(--g)/2 + 1em));
}
/* we increase the size by 2em */
.gallery > img:nth-child(5) {
  width: calc(var(--s) + 2em);
}
/* on hover 1em = S/5 */
.gallery:hover {
  font-size: calc(var(--s) / 5);
}

The font-size trick is helpful if we want to animate gradients or other properties that cannot be animated. Custom properties defined with @property can solve such a problem, but support for it is still lacking at the time of writing.

I discovered the font-size trick from @SelenIT2 while trying to solve a challenge on Twitter.

Another shape? Let’s go!

This time we clipped the nested image into the shape of a rhombus. I’ll let you dissect the code as an exercise to figure out how we got here. You will notice that the structure is the same as in our examples. The only differences are how we’re using the gradient to create the shape. Dig in and learn!

Circular Image Grid

We can combine what we’ve learned here and in previous articles to make an even more exciting image grid. This time, let’s make all the images in our grid circular and, on hover, expand an image to reveal the entire thing as it covers the rest of the photos.

The HTML and CSS structure of the grid is nothing new from before, so let’s skip that part and focus instead on the circular shape and hover effect we want.

We are going to use clip-path and its circle() function to — you guessed it! — cut a circle out of the images.

Showing the two states of an image, the natural state on the left, and the hovered state on the right, including the clip-path values to create them.

That figure illustrates the clip-path used for the first image. The left side shows the image’s initial state, while the right shows the hovered state. You can use this online tool to play and visualize the clip-path values.

For the other images, we can update the center of the circle (70% 70%) to get the following code:

.gallery > img:hover {
  --_c: 50%; /* same as "50% at 50% 50%" */
}
.gallery > img:nth-child(1) {
  clip-path: circle(var(--_c, 55% at 70% 70%));
}
.gallery > img:nth-child(2) {
  clip-path: circle(var(--_c, 55% at 30% 70%));
}
.gallery > img:nth-child(3) {
  clip-path: circle(var(--_c, 55% at 70% 30%));
}
.gallery > img:nth-child(4) {
  clip-path: circle(var(--_c, 55% at 30% 30%));
}

Note how we are defining the clip-path values as a fallback inside var(). This way allows us to more easily update the value on hover by setting the value of the --_c variable. When using circle(), the default position of the center point is 50% 50%, so we get to omit that for more concise code. That’s why you see that we are only setting 50% instead of 50% at 50% 50%.

Then we increase the size of our image on hover to the overall size of the grid so we can cover the other images. We also ensure the z-index has a higher value on the hovered image, so it is the top one in our stacking context.

.gallery {
  --s: 200px; /* controls the image size */
  --g: 8px;   /* controls the gap between images */

  display: grid;
  grid: auto-flow var(--s) / repeat(2, var(--s));
  gap: var(--g);
}

.gallery > img {
  width: 100%; 
  aspect-ratio: 1;
  cursor: pointer;
  z-index: 0;
  transition: .25s, z-index 0s .25s;
}
.gallery > img:hover {
  --_c: 50%; /* change the center point on hover */
  width: calc(200% + var(--g));
  z-index: 1;
  transition: .4s, z-index 0s;
}

.gallery > img:nth-child(1){
  clip-path: circle(var(--_c, 55% at 70% 70%));
  place-self: start;
}
.gallery > img:nth-child(2){
  clip-path: circle(var(--_c, 55% at 30% 70%));
  place-self: start end;
}
.gallery > img:nth-child(3){
  clip-path: circle(var(--_c, 55% at 70% 30%));
  place-self: end start;
}
.gallery > img:nth-child(4){
  clip-path: circle(var(--_c, 55% at 30% 30%));
  place-self: end;
}

What’s going on with the place-self property? Why do we need it and why does each image have a specific value?

Do you remember the issue we had in the previous article when creating the grid of puzzle pieces? We increased the size of the images to create an overflow, but the overflow of some images was incorrect. We fixed them using the place-self property.

Same issue here. We are increasing the size of the images so each one overflows its grid cells. But if we do nothing, all of them will overflow on the right and bottom sides of the grid. What we need is:

  1. the first image to overflow the bottom-right edge (the default behavior),
  2. the second image to overflow the bottom-left edge,
  3. the third image to overflow the top-right edge, and
  4. the fourth image to overflow the top-left edge.

To get that, we need to place each image correctly using the place-self property.

Diagram showing the place-self property values for each quadrant of the grid.

In case you are not familiar with place-self, it’s the shorthand for justify-self and align-self to place the element horizontally and vertically. When it takes one value, both alignments use that same value.

Expanding Image Panels

In a previous article, I created a cool zoom effect that applies to a grid of images where we can control everything: number of rows, number of columns, sizes, scale factor, etc.

A particular case was the classic expanding panels, where we only have one row and a full-width container.

We will take this example and combine it with shapes!

Before we continue, I highly recommend reading my other article to understand how the tricks we’re about to cover work. Check that out, and we’ll continue here to focus on creating the panel shapes.

First, let’s start by simplifying the code and removing some variables

We only need one row and the number of columns should adjust based on the number of images. That means we no longer need variables for the number of rows (--n) and columns (--m ) but we need to use grid-auto-flow: column, allowing the grid to auto-generate columns as we add new images. We will consider a fixed height for our container; by default, it will be full-width.

Let’s clip the images into a slanted shape:

A headshot of a calm red wolf looking downward with vertices overlayed showing the clip-path property points.
clip-path: polygon(S 0%, 100% 0%, (100% - S) 100%, 0% 100%);

Once again, each image is contained in its grid cell, so there’s more space between the images than we’d like:

A six-panel grid of slanted images of various wild animals showing the grid lines and gaps.

We need to increase the width of the images to create an overlap. We replace min-width: 100% with min-width: calc(100% + var(--s)), where --s is a new variable that controls the shape.

Now we need to fix the first and last images, so they sort of bleed off the page without gaps. In other words, we can remove the slant from the left side of the first image and the slant from the right side of the last image. We need a new clip-path specifically for those two images.

We also need to rectify the overflow. By default, all the images will overflow on both sides, but for the first one, we need an overflow on the right side while we need a left overflow for the last image.

.gallery > img:first-child {
  min-width: calc(100% + var(--s)/2);
  place-self: start;
  clip-path: polygon(0 0,100% 0,calc(100% - var(--s)) 100%,0 100%);
}
.gallery > img:last-child {
  min-width: calc(100% + var(--s)/2);
  place-self: end;
  clip-path: polygon(var(--s) 0,100% 0,100% 100%,0 100%);
}

The final result is a nice expanding panel of slanted images!

We can add as many images as you want, and the grid will adjust automatically. Plus, we only need to control one value to control the shape!

We could have made this same layout with flexbox since we are dealing with a single row of elements. Here is my implementation.

Sure, slanted images are cool, but what about a zig-zag pattern? I already teased this one at the end of the last article.

All I’m doing here is replacing clip-path with mask… and guess what? I already have a detailed article on creating that zig-zag shape — not to mention an online generator to get the code. See how all everything comes together?

The trickiest part here is to make sure the zig-zags are perfectly aligned, and for this, we need to add an offset for every :nth-child(odd) image element.

.gallery > img {
  mask: 
    conic-gradient(from -135deg at right, #0000, #000 1deg 89deg, #0000 90deg) 
      100% calc(50% + var(--_p, 0%))/51% calc(2*var(--s)) repeat-y,
    conic-gradient(from   45deg at left,  #0000, #000 1deg 89deg, #0000 90deg) 
      0%   calc(50% + var(--_p, 0%))/51% calc(2*var(--s)) repeat-y;
}
/* we add an offset to the odd elements */
.gallery > img:nth-child(odd) {
  --_p: var(--s);
}
.gallery > img:first-child {
  mask: 
    conic-gradient(from -135deg at right, #0000, #000 1deg 89deg, #0000 90deg) 
      0 calc(50% + var(--_p, 0%))/100% calc(2*var(--s));
}
.gallery > img:last-child {
  mask: 
    conic-gradient(from 45deg at left, #0000, #000 1deg 89deg, #0000 90deg) 
      0 calc(50% + var(--_p, 0%)) /100% calc(2*var(--s));
}

Note the use of the --_p variable, which will fall back to 0% but will be equal to --_s for the odd images.

Here is a demo that illustrates the issue. Hover to see how the offset — defined by --_p — is fixing the alignment.

Also, notice how we use a different mask for the first and last image as we did in the previous example. We only need a zig-zag on the right side of the first image and the left side of the last image.

And why not rounded sides? Let’s do it!

I know that the code may look scary and tough to understand, but all that’s going on is a combination of different tricks we’ve covered in this and other articles I’ve already shared. In this case, I use the same code structure as the zig-zag and the slanted shapes. Compare it with those examples, and you will find no difference! Those are the same tricks in my previous article about the zoom effect. Then, I am using my other writing and my online generator to get the code for the mask that creates those rounded shapes.

If you recall what we did for the zig-zag, we had used the same mask for all the images but then had to add an offset to the odd images to create a perfect overlap. In this case, we need a different mask for the odd-numbered images.

The first mask:

mask: 
  linear-gradient(-90deg,#0000 calc(2*var(--s)),#000 0) var(--s),
  radial-gradient(var(--s),#000 98%,#0000) 50% / calc(2*var(--s)) calc(1.8*var(--s)) space repeat;

The second one:

mask:
  radial-gradient(calc(var(--s) + var(--g)) at calc(var(--s) + var(--g)) 50%,#0000 98% ,#000) 
  calc(50% - var(--s) - var(--g)) / 100% calc(1.8*var(--s))

The only effort I did here is update the second mask to include the gap variable (--g) to create that space between the images.

The final touch is to fix the first and last image. Like all the previous examples, the first image needs a straight left edge while the last one needs a straight right edge.

For the first image, we always know the mask it needs to have, which is the following:

.gallery > img:first-child {
  mask: 
    radial-gradient(calc(var(--s) + var(--g)) at right, #0000 98%, #000) 50% / 100% calc(1.8 * var(--s));
}
A brown bear headshot with a wavy pattern for the right border.

For the last image, it depends on the number of elements, so it matters if that element is :nth-child(odd) or :nth-child(even).

The complete grid of wild animal photos with all of the correct borders and gaps between images.
.gallery > img:last-child:nth-child(even) {
  mask: 
    linear-gradient(to right,#0000 var(--s),#000 0),
    radial-gradient(var(--s),#000 98%,#0000) left / calc(2*var(--s)) calc(1.8*var(--s)) repeat-y
}
A single-row grid of three wild animal photos with wavy borders where the last image is an odd-numbered element.
.gallery > img:last-child:nth-child(odd) {
  mask: 
    radial-gradient(calc(var(--s) + var(--g)) at left,#0000 98%,#000) 50% / 100% calc(1.8*var(--s))
}

That’s all! Three different layouts but the same CSS tricks each time:

  • the code structure to create the zoom effect
  • a mask or clip-path to create the shapes
  • a separate configuration for the odd elements in some cases to make sure we have a perfect overlap
  • a specific configuration for the first and last image to keep the shape on only one side.

And here is a big demo with all of them together. All you need is to add a class to activate the layout you want to see.

And here is the one with the Flexbox implementation

Wrapping up

Oof, we are done! I know there are many CSS tricks and examples between this article and the last one, not to mention all of the other tricks I’ve referenced here from other articles I’ve written. It took me time to put everything together, and you don’t have to understand everything at once. One reading will give you a good overview of all the layouts, but you may need to read the article more than once and focus on each example to grasp all the tricks.

Did you notice that we didn’t touch the HTML at all other than perhaps the number of images in the markup? All the layouts we made share the same HTML code, which is nothing but a list of images.

Before I end, I will leave you with one last example. It’s a “versus” between two anime characters with a cool hover effect.

What about you? Can you create something based on what you have learned? It doesn’t need to be complex — imagine something cool or funny like I did with that anime matchup. It can be a good exercise for you, and we may end with an excellent collection in the comment section.