Heatmap Layout

The heatmap_layout()/ggheatmap() function provides a powerful way to create customizable heatmaps in R using ggplot2. This vignette will guide you through its usage.

input data

The data input can be a numeric or character vector, a data frame, and any other data which can be converted into a matrix by fortify_matrix().

set.seed(123)
small_mat <- matrix(rnorm(81), nrow = 9)
rownames(small_mat) <- paste0("row", seq_len(nrow(small_mat)))
colnames(small_mat) <- paste0("column", seq_len(ncol(small_mat)))
library(ggalign)
#> Loading required package: ggplot2
ggheatmap(small_mat)
#> → heatmap built with `geom_tile()`

heatmap body

For ggplot2 usage, the matrix input will be converted into a long formated data frame when drawing. The default mapping will use aes(.data$.x, .data$.y), but can be controlled using mapping argument. The data in the underlying ggplot object contains following columns:

You can treat the ggheatmap()/heatmap_layout() object as a standard ggplot2 object with default mapping and data. This means you can add ggplot2 layers or elements just like in any ggplot object.

ggheatmap(small_mat) + geom_point() + scale_fill_viridis_c()
#> → heatmap built with `geom_tile()`

By default, ggheatmap()/heatmap_layout() adds a heatmap layer. If the matrix has more than 20,000 cells (nrow * ncol > 20000), it uses geom_raster() for performance efficiency; for smaller matrices, geom_tile() is used. You can explicitly choose the layer by providing a single string ("raster" or "tile") in the filling argument.

ggheatmap(small_mat, filling = "raster")

ggheatmap(small_mat, filling = "tile")

If you set filling = NULL, a blank heatmap will be drawn, allowing for customized filling geoms. In this way, you must set fill mapping manually.

ggheatmap(small_mat, filling = NULL) +
    geom_tile(aes(fill = value), color = "black", width = 0.9, height = 0.9)

A heatmap pie charts:

set.seed(123)
ggheatmap(matrix(runif(360L), nrow = 20L), filling = NULL) +
    geom_pie(aes(angle = value * 360, fill = value))

If you want more complex customization of pie charts, try using ggforce::geom_arc_bar() instead.

You can use external packages like ggrastr or ggfx to rasterize the heatmap body. Additionally, ggfx offers many image filters that can be applied to ggplot2 layers.

ggheatmap(small_mat, filling = FALSE) +
    ggrastr::rasterise(geom_tile(aes(fill = value)), dev = "ragg")

You can rasterize all plots in the layout directly with ggrastr::rasterise(). This method works for both ggheatmap()/quad_layout() and ggstack() objects.

ggrastr::rasterise(ggheatmap(small_mat), dev = "ragg")
#> → heatmap built with `geom_tile()`

heatmap annotations

A heatmap typically has two observation axes (rows and columns), which can be reordered or supplemented with additional information. In ggheatmap(), annotations are handled by a stack_layout() object, specifically stack_align(), which aligns the observations. This object can hold multiple plots and can be positioned at the top, left, bottom, or right of the heatmap.

Note that ggalign use the concept of "number of observations" in the vctrs package or NROW() function. When aligning the observations, you must ensure the number of observations is equal. For column annotations, the layout matrix will be transposed before use. This is necessary because column annotations use heatmap columns as observations, but we need rows.

quad_anno()

By default, heatmap_layout()/ggheatmap() do not initialize an active context, which means that all additions are directed within the heatmap body. You can use quad_anno() to set the active context, directing all subsequent additions to the specified annotation position. The quad_anno() function has the following aliases:

The annotations allows for custom layout adjustments and the addition of various plot types. In the following example, align_kmeans() is used to group the columns into three panels. It doesn’t matter if this is added to the top or bottom since it won’t add a plot area:

ggheatmap(small_mat) +
    # we set the active context to the top annotation
    anno_top() +
    # we split the observations into 3 groups by kmeans
    align_kmeans(3L)
#> → heatmap built with `geom_tile()`

We can add any align_*() function to the annotation. For more details on align_*() functions, refer to layout-customize and layout-plot.

ggheatmap(small_mat) +
    # in the heatmap body, we set the axis text theme
    theme(axis.text.x = element_text(angle = -60, hjust = 0)) +
    # we set the active context to the right annotation
    anno_right() +
    # in the right annotation, we add a dendrogram
    align_dendro(k = 3L) +
    # in the dendrogram, we add a point layer
    geom_point(aes(color = factor(branch)))
#> → heatmap built with `geom_tile()`

In this example:

quad_active()

To remove the active context and redirect additions back to the heatmap body, you can use quad_active().

ggheatmap(small_mat) +
    # we set the active context to the top annotation
    anno_top() +
    # we split the observations into 3 groups by kmeans
    align_kmeans(3L) +
    # remove any active annotation
    quad_active() +
    # set fill color scale for the heatmap body
    scale_fill_viridis_c()
#> → heatmap built with `geom_tile()`

quad_switch()/hmanno()

We also provide quad_switch()/hmanno() (heatmap annotation) which integrates quad_active() and quad_anno() into one function for ease of use. Feel free to use any of these functions to streamline your annotation process.

ggheatmap(small_mat) +
    # we set the active context to the top annotation
    quad_switch("t") +
    # we split the observations into 3 groups by kmeans
    align_kmeans(3L) +
    # remove any active annotation
    quad_switch() +
    # set fill color scale for the heatmap body
    scale_fill_viridis_c()
#> → heatmap built with `geom_tile()`

ggheatmap(small_mat) +
    # we set the active context to the top annotation
    hmanno("t") +
    # we split the observations into 3 groups by kmeans
    align_kmeans(3L) +
    # remove any active annotation
    hmanno() +
    # set fill color scale for the heatmap body
    scale_fill_viridis_c()
#> → heatmap built with `geom_tile()`

You may wonder about the prefix quad_. The ggheatmap() function is a specialized version of quad_layout(), designed to simplify the creation of heatmap plots by integrating essential elements for a standard heatmap layout. Both quad_anno() and quad_active() are functions designed for quad_layout().

Plot Size

Heatmap Body Size

You can specify the relative sizes of the heatmap body using the width and height arguments in the ggheatmap() function.

ggheatmap(small_mat, height = 2) +
    scale_fill_viridis_c() +
    anno_top() +
    align_dendro()
#> → heatmap built with `geom_tile()`

Alternatively, the quad_active() function allows you to control the heatmap body sizes.

ggheatmap(small_mat) +
    quad_active(height = 2) +
    scale_fill_viridis_c() +
    anno_top() +
    align_dendro()
#> → heatmap built with `geom_tile()`

Annotation Stack Size

The quad_anno() function allows you to control the total annotation stack size. The size argument controls the relative width (for left and right annotations) or height (for top and bottom annotations) of the whole annotation stack.

ggheatmap(small_mat) +
    scale_fill_viridis_c() +
    anno_top(size = 1) +
    align_dendro()
#> → heatmap built with `geom_tile()`

You can also specify it as an absolute size using unit():

ggheatmap(small_mat) +
    scale_fill_viridis_c() +
    anno_top(size = unit(30, "mm")) +
    align_dendro()
#> → heatmap built with `geom_tile()`

Single Plot Size

All align_*()/ggfree() functions that add plots in the annotation stack have a size argument to control the relative width (for left and right annotations) or height (for top and bottom annotations) of the single plot in the annotation stack.

ggheatmap(small_mat) +
    scale_fill_viridis_c() +
    anno_left(size = 0.2) +
    ggalign(data = rowSums, aes(x = value), size = unit(10, "mm")) +
    geom_bar(
        aes(y = .y, fill = factor(.y)),
        stat = "identity", orientation = "y"
    ) +
    scale_fill_brewer(palette = "Set1", guide = "none")
#> → heatmap built with `geom_tile()`

Session information

sessionInfo()
#> R version 4.4.0 (2024-04-24)
#> Platform: x86_64-pc-linux-gnu
#> Running under: Ubuntu 24.04 LTS
#> 
#> Matrix products: default
#> BLAS/LAPACK: /usr/lib/x86_64-linux-gnu/libmkl_rt.so;  LAPACK version 3.8.0
#> 
#> locale:
#>  [1] LC_CTYPE=C.UTF-8       LC_NUMERIC=C           LC_TIME=C.UTF-8       
#>  [4] LC_COLLATE=C           LC_MONETARY=C.UTF-8    LC_MESSAGES=C.UTF-8   
#>  [7] LC_PAPER=C.UTF-8       LC_NAME=C              LC_ADDRESS=C          
#> [10] LC_TELEPHONE=C         LC_MEASUREMENT=C.UTF-8 LC_IDENTIFICATION=C   
#> 
#> time zone: Asia/Shanghai
#> tzcode source: system (glibc)
#> 
#> attached base packages:
#> [1] stats     graphics  grDevices utils     datasets  methods   base     
#> 
#> other attached packages:
#> [1] ggalign_0.0.5 ggplot2_3.5.1
#> 
#> loaded via a namespace (and not attached):
#>  [1] gtable_0.3.5       jsonlite_1.8.8     dplyr_1.1.4        compiler_4.4.0    
#>  [5] highr_0.11         tidyselect_1.2.1   ggbeeswarm_0.7.2   jquerylib_0.1.4   
#>  [9] textshaping_0.4.0  systemfonts_1.1.0  scales_1.3.0       yaml_2.3.8        
#> [13] fastmap_1.2.0      R6_2.5.1           labeling_0.4.3     generics_0.1.3    
#> [17] knitr_1.47         tibble_3.2.1       bookdown_0.39      desc_1.4.3        
#> [21] munsell_0.5.1      RColorBrewer_1.1-3 bslib_0.7.0        pillar_1.9.0      
#> [25] rlang_1.1.4        utf8_1.2.4         cachem_1.1.0       xfun_0.45         
#> [29] sass_0.4.9         viridisLite_0.4.2  cli_3.6.3          withr_3.0.0       
#> [33] magrittr_2.0.3     digest_0.6.36      grid_4.4.0         beeswarm_0.4.0    
#> [37] lifecycle_1.0.4    vipor_0.4.7        ggrastr_1.0.2      vctrs_0.6.5       
#> [41] evaluate_0.24.0    glue_1.7.0         farver_2.1.2       ragg_1.3.2        
#> [45] fansi_1.0.6        colorspace_2.1-0   rmarkdown_2.27     tools_4.4.0       
#> [49] pkgconfig_2.0.3    htmltools_0.5.8.1