For a better version of the stars vignettes see https://r-spatial.github.io/stars/articles/
When your imagery or array data easily fits a couple of times in R’s working memory (RAM), consider yourself lucky. This document was not written for you. If your imagery is too large, or for other reasons you want to work with smaller chunks of data than the files in which they come, read on about your options. First, we will discuss the low-level interface for this, then the higher level, using stars proxy objects that delay all reading.
To run all of the examples in this vignette, you must install a package with datasets that are too large (1 Gb) to be held in the stars
package. They are in a drat repo, installation is done by
install.packages("starsdata", repos = "http://gis-bigdata.uni-muenster.de/pebesma", type = "source")
# possibly after: options(timeout = 100)
# or from an alternative repository:
# install.packages("starsdata", repos = "http://pebesma.staff.ifgi.de", type = "source")
read_stars
has an argument called RasterIO
which controls how a GDAL dataset is being read. By default, all pixels and all bands are read in memory. This can consume a lot of time and require a lot of memory. Remember that your file may be compressed, and that pixel values represented in the file by bytes are converted to 8-byte doubles in R.
The reason for using RasterIO
for this is that the parameters we use are directly mapped to the GDAL RasterIO function used (after adapting the 1-based offset index in R to 0-based offset in C++).
An example of using RasterIO
is
library(stars)
system.file("tif/L7_ETMs.tif", package = "stars")
tif = list(nXOff = 6, nYOff = 6, nXSize = 100, nYSize = 100, bands = c(1, 3, 4))
rasterio =x = read_stars(tif, RasterIO = rasterio))
(## stars object with 3 dimensions and 1 attribute
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## L7_ETMs.tif 23 54 63 62.05977 73.25 235
## dimension(s):
## from to offset delta refsys point x/y
## x 6 105 288776 28.5 SIRGAS 2000 / UTM zone 25S FALSE [x]
## y 6 105 9120761 -28.5 SIRGAS 2000 / UTM zone 25S FALSE [y]
## band 1 3 NA NA NA NA
dim(x)
## x y band
## 100 100 3
Compare this to
st_dimensions(read_stars(tif))
## from to offset delta refsys point x/y
## x 1 349 288776 28.5 SIRGAS 2000 / UTM zone 25S FALSE [x]
## y 1 352 9120761 -28.5 SIRGAS 2000 / UTM zone 25S FALSE [y]
## band 1 6 NA NA NA NA
and we see that
delta
values remain the same,from
and to
reflect the new area, and relate to the new delta
valuesdim(x)
reflects the new size, andReading datasets at a lower (but also higher!) resolution can be done by setting nBufXSize
and nBufYSize
list(nXOff = 6, nYOff = 6, nXSize = 100, nYSize = 100,
rasterio =nBufXSize = 20, nBufYSize = 20, bands = c(1, 3, 4))
x = read_stars(tif, RasterIO = rasterio))
(## stars object with 3 dimensions and 1 attribute
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## L7_ETMs.tif 27 53 63 62.09417 74 151
## dimension(s):
## from to offset delta refsys point x/y
## x 2 21 288776 142.5 SIRGAS 2000 / UTM zone 25S FALSE [x]
## y 2 21 9120761 -142.5 SIRGAS 2000 / UTM zone 25S FALSE [y]
## band 1 3 NA NA NA NA
and we see that in addition:
delta
(raster cell size) values have increased a factor 5, because nBufXSize
and nBufYSize
were set to values a factor 5 smaller than nXSize
and nYSize
from
and to
reflect the new area, but relate to the new delta
cell size valuesWe can also read at higher resolution; here we read a 3 x 3 area and blow it up to 100 x 100:
list(nXOff = 6, nYOff = 6, nXSize = 3, nYSize = 3,
rasterio =nBufXSize = 100, nBufYSize = 100, bands = 1)
read_stars(tif, RasterIO = rasterio)
x =dim(x)
## x y
## 100 100
plot(x)
The reason we “see” only three grid cells is that the default sampling method is “nearest neighbour”. We can modify this by
list(nXOff = 6, nYOff = 6, nXSize = 3, nYSize = 3,
rasterio =nBufXSize = 100, nBufYSize = 100, bands = 1, resample = "cubic_spline")
read_stars(tif, RasterIO = rasterio)
x =dim(x)
## x y
## 100 100
plot(x)
The following methods are allowed for parameter resample
:
resample |
method used |
---|---|
nearest_neighbour |
Nearest neighbour (default) |
bilinear |
Bilinear (2x2 kernel) |
cubic |
Cubic Convolution Approximation (4x4 kernel) |
cubic_spline |
Cubic B-Spline Approximation (4x4 kernel) |
lanczos |
Lanczos windowed sinc interpolation (6x6 kernel) |
average |
Average |
mode |
Mode (selects the value which appears most often of all the sampled points) |
Gauss |
Gauss blurring |
All these methods are implemented in GDAL; for what these methods exactly do, we refer to the GDAL documentation or source code.
Stars proxy objects take another approach: upon creation they contain no data at all, but only pointers to where the data can be read. Data is only read when it is needed, and only as much as is needed: if we plot a proxy objects, the data are read at the resolution of pixels on the screen, rather than at the native resolution, so that if we have e.g. a 10000 x 10000 Sentinel 2 (level 1C) image, we can open it by
system.file("sentinel/S2A_MSIL1C_20180220T105051_N0206_R051_T32ULE_20180221T134037.zip", package = "starsdata")
granule = paste0("SENTINEL2_L1C:/vsizip/", granule, "/S2A_MSIL1C_20180220T105051_N0206_R051_T32ULE_20180221T134037.SAFE/MTD_MSIL1C.xml:10m:EPSG_32632")
s2 =p = read_stars(s2, proxy = TRUE))
(## stars_proxy object with 1 attribute in 1 file(s):
## $EPSG_32632
## [1] "[...]/MTD_MSIL1C.xml:10m:EPSG_32632"
##
## dimension(s):
## from to offset delta refsys values x/y
## x 1 10980 3e+05 10 WGS 84 / UTM zone 32N NULL [x]
## y 1 10980 6e+06 -10 WGS 84 / UTM zone 32N NULL [y]
## band 1 4 NA NA NA B4,...,B8
and this happens instantly, because no data is read. When we plot this object,
system.time(plot(p))
## downsample set to 43
## user system elapsed
## 0.766 0.356 0.166
This takes only around 1 second, since only those pixels are read that can be seen on the plot. If we read the entire image in memory first, as we would do with
read_stars(s2, proxy = FALSE) p =
then only the reading would take over a minute, and require 5 Gb memory.
methods(class = "stars_proxy")
## [1] Math Ops [ [<-
## [5] [[<- adrop aggregate aperm
## [9] as.data.frame c coerce dim
## [13] droplevels filter hist image
## [17] initialize is.na merge mutate
## [21] plot prcomp predict print
## [25] pull rename select show
## [29] slice slotsFromS3 split st_apply
## [33] st_as_sf st_as_stars st_crop st_dimensions<-
## [37] st_downsample st_mosaic st_normalize st_redimension
## [41] st_sample st_set_bbox transmute write_stars
## see '?methods' for accessing help and source code
We can select attributes as with regular stars
objects, by using the first argument to [
:
c("avhrr-only-v2.19810901.nc",
x ="avhrr-only-v2.19810902.nc",
"avhrr-only-v2.19810903.nc",
"avhrr-only-v2.19810904.nc",
"avhrr-only-v2.19810905.nc",
"avhrr-only-v2.19810906.nc",
"avhrr-only-v2.19810907.nc",
"avhrr-only-v2.19810908.nc",
"avhrr-only-v2.19810909.nc")
system.file(paste0("netcdf/", x), package = "starsdata")
file_list = read_stars(file_list, quiet = TRUE, proxy = TRUE)
y =names(y)
## [1] "sst" "anom" "err" "ice"
"sst"]
y[## stars_proxy object with 1 attribute in 9 file(s):
## $sst
## [1] "[...]/avhrr-only-v2.19810901.nc:sst" "[...]/avhrr-only-v2.19810902.nc:sst"
## [3] "[...]/avhrr-only-v2.19810903.nc:sst" "[...]/avhrr-only-v2.19810904.nc:sst"
## [5] "[...]/avhrr-only-v2.19810905.nc:sst" "[...]/avhrr-only-v2.19810906.nc:sst"
## [7] "[...]/avhrr-only-v2.19810907.nc:sst" "[...]/avhrr-only-v2.19810908.nc:sst"
## [9] "[...]/avhrr-only-v2.19810909.nc:sst"
##
## dimension(s):
## from to offset delta refsys x/y
## x 1 1440 0 0.25 NA [x]
## y 1 720 90 -0.25 NA [y]
## zlev 1 1 0 [m] NA NA
## time 1 9 1981-09-01 UTC 1 days POSIXct
Note that this selection limits the reading from 4 to 1 subdataset from all 9 NetCDF files.
Another possibility is to crop, or select a rectangular region based on a spatial object. This can be done by passing a bbox
object, or an sf
, sfc
or stars
object from which the bounding box will be taken. An example:
st_bbox(c(xmin = 10.125, ymin = 0.125, xmax = 70.125, ymax = 70.125))
bb = y[bb]
ysub =st_dimensions(ysub)
## from to offset delta refsys x/y
## x 41 281 0 0.25 NA [x]
## y 80 360 90 -0.25 NA [y]
## zlev 1 1 0 [m] NA NA
## time 1 9 1981-09-01 UTC 1 days POSIXct
class(ysub) # still no data here!!
## [1] "stars_proxy" "stars"
plot(ysub, reset = FALSE) # plot reads the data, at resolution that is relevant
plot(st_as_sfc(bb), add = TRUE, lwd = .5, border = 'red')
Some other actions can be carried out on stars_proxy
objects, but their effect is delayed until the data are actually needed (plot
, write_stars
). For instance, range selections on dimensions other than shown above first need data, and can only then be carried out. Such functions are added to the object, in an attribute called call_list
:
adrop(y)
yy = yy[,1:10,1:10,]
yyy =class(yyy) # still no data
## [1] "stars_proxy" "stars"
st_dimensions(yyy) # and dimensions not adjusted
## from to offset delta refsys x/y
## x 1 1440 0 0.25 NA [x]
## y 1 720 90 -0.25 NA [y]
## zlev 1 1 0 [m] NA NA
## time 1 9 1981-09-01 UTC 1 days POSIXct
attr(yyy, "call_list") # the name of object in the call (y) is replaced with x:
## [[1]]
## adrop(x = x, drop = drop)
## attr(,".Environment")
## <environment: 0x62e8bab6dbf8>
##
## [[2]]
## x[i = i, 1:10, 1:10, , drop = drop, crop = crop]
## attr(,".Environment")
## <environment: 0x62e8bab1ff68>
Doing this allows for optimizing the order in which operations are done. As an example, for st_apply
, reading can be done sequentially over the dimensions over which the function is applied:
plot(st_apply(x, c("x", "y"), range))
the order of evaluation is reversed: plot
knows which pixels are going to be shown, and controls how x
is downsampled before st_apply
is carried out on this subset.
Fetching the data now involves reading the whole array and then evaluating the call_list
on it, sequentially:
x = st_as_stars(yyy)) # read, adrop, subset
(## stars object with 3 dimensions and 4 attributes
## attribute(s):
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## sst [C*°] -1.28 -1.17 -1.11 -1.1163555 -1.06 -0.95
## anom [C*°] 0.48 0.62 0.69 0.6649555 0.72 0.77
## err [C*°] 0.30 0.30 0.30 0.3000000 0.30 0.30
## ice [percent] 0.76 0.79 0.81 0.8062889 0.82 0.85
## dimension(s):
## from to offset delta refsys x/y
## x 1 10 0 0.25 NA [x]
## y 1 10 90 -0.25 NA [y]
## time 1 9 1981-09-01 UTC 1 days POSIXct
For the Sentinel 2 data, band 4 represents NIR and band 1 red, so we can compute NDVI by
# S2 10m: band 4: near infrared, band 1: red.
#ndvi = function(x) (x[4] - x[1])/(x[4] + x[1])
function(x1, x2, x3, x4) (x4 - x1)/(x4 + x1)
ndvi =rm(x)
s2.ndvi = st_apply(p, c("x", "y"), ndvi))
(## stars_proxy object with 1 attribute in 1 file(s):
## $EPSG_32632
## [1] "[...]/MTD_MSIL1C.xml:10m:EPSG_32632"
##
## dimension(s):
## from to offset delta refsys values x/y
## x 1 10980 3e+05 10 WGS 84 / UTM zone 32N NULL [x]
## y 1 10980 6e+06 -10 WGS 84 / UTM zone 32N NULL [y]
## band 1 4 NA NA NA B4,...,B8
## call_list:
## [[1]]
## st_apply(X = X, MARGIN = MARGIN, FUN = FUN, CLUSTER = CLUSTER,
## PROGRESS = PROGRESS, FUTURE = FUTURE, rename = rename, .fname = .fname)
## attr(,".Environment")
## <environment: 0x62e8a9034ad8>
##
## This object has pending lazy operations: dimensions as printed may not reflect this.
system.time(plot(s2.ndvi)) # read - compute ndvi - plot
## downsample set to 43
## user system elapsed
## 0.736 0.282 0.127
This sections shows some examples how stars_proxy
objects deal with the situation where the different maps have dissimilar resolution. The assumptions here are:
We’ll create four maps with cells size 1, 2 and 3:
st_as_stars(matrix(1:16, 4))
s1 = st_as_stars(matrix(1:16, 4))
s2 = st_as_stars(matrix(1:16, 4))
s3 =attr(s1, "dimensions")$X1$offset = 0
attr(s1, "dimensions")$X2$offset = 4
attr(s2, "dimensions")$X1$offset = 0
attr(s2, "dimensions")$X2$offset = 4
attr(s3, "dimensions")$X1$offset = 0
attr(s3, "dimensions")$X2$offset = 4
attr(s1, "dimensions")$X1$delta = 1
attr(s1, "dimensions")$X2$delta = -1
attr(s2, "dimensions")$X1$delta = 2
attr(s2, "dimensions")$X2$delta = -2
attr(s3, "dimensions")$X1$delta = 3
attr(s3, "dimensions")$X2$delta = -3
plot(s1, axes = TRUE, text_values = TRUE, text_color = 'orange')
plot(s2, axes = TRUE, text_values = TRUE, text_color = 'orange')
plot(s3, axes = TRUE, text_values = TRUE, text_color = 'orange')
We created three rasters with identical cell values and dimensions, but different cell sizes, and hence extents. If we bind them in a single proxy object, with
paste0(tempdir(), .Platform$file.sep, "img1.tif")
fn1 = paste0(tempdir(), .Platform$file.sep, "img2.tif")
fn2 = paste0(tempdir(), .Platform$file.sep, "img3.tif")
fn3 =write_stars(s1, fn1)
write_stars(s2, fn2)
write_stars(s3, fn3)
r1 = read_stars(c(fn1, fn2, fn3), proxy = TRUE))
(## multi-resolution stars_proxy object with 3 attributes in 3 file(s):
## $`1`
## [1] "[...]/img1.tif"
##
## $`2`
## [1] "[...]/img2.tif"
##
## $`3`
## [1] "[...]/img3.tif"
##
## dimension(s):
## from to offset delta x/y
## x 1 4 0 1 [x]
## y 1 4 4 -1 [y]
We see that multi-resolution is mentioned in the printed summary. When converting this to a stars
object, the secondary rasters are resampled to the cellsize + extent of the first:
st_as_stars(r1) %>%
merge() %>%
plot(breaks = "equal", text_values = TRUE, text_color = 'orange', axes = TRUE)
If we do this for a sub-range, defined for the object resolutions, we get:
st_as_stars(r1[,2:4,2:4]) %>%
merge() %>%
plot(breaks = "equal", text_values = TRUE, text_color = 'orange', axes = TRUE)
We now create four maps, all over the same region ([0,4] x [0,4]), with different resolutions (cell size 1, 1/2 and 1/3):
st_as_stars(matrix(1: 16, 4))
s4 = st_as_stars(matrix(1: 64, 8))
s5 = st_as_stars(matrix(1:144,12))
s6 =attr(s4, "dimensions")$X1$offset = 0
attr(s4, "dimensions")$X2$offset = 4
attr(s5, "dimensions")$X1$offset = 0
attr(s5, "dimensions")$X2$offset = 4
attr(s6, "dimensions")$X1$offset = 0
attr(s6, "dimensions")$X2$offset = 4
attr(s4, "dimensions")$X1$delta = 1
attr(s4, "dimensions")$X2$delta = -1
attr(s5, "dimensions")$X1$delta = 1/2
attr(s5, "dimensions")$X2$delta = -1/2
attr(s6, "dimensions")$X1$delta = 1/3
attr(s6, "dimensions")$X2$delta = -1/3
plot(s4, axes = TRUE, text_values = TRUE, text_color = 'orange')
plot(s5, axes = TRUE, text_values = TRUE, text_color = 'orange')
plot(s6, axes = TRUE, text_values = TRUE, text_color = 'orange')
paste0(tempdir(), .Platform$file.sep, "img4.tif")
fn4 = paste0(tempdir(), .Platform$file.sep, "img5.tif")
fn5 = paste0(tempdir(), .Platform$file.sep, "img6.tif")
fn6 =write_stars(s4, fn4)
write_stars(s5, fn5)
write_stars(s6, fn6)
r2 = read_stars(c(fn4, fn5, fn6), proxy = TRUE))
(## multi-resolution stars_proxy object with 3 attributes in 3 file(s):
## $`4`
## [1] "[...]/img4.tif"
##
## $`5`
## [1] "[...]/img5.tif"
##
## $`6`
## [1] "[...]/img6.tif"
##
## dimension(s):
## from to offset delta x/y
## x 1 4 0 1 [x]
## y 1 4 4 -1 [y]
st_as_stars(r2) %>%
merge() %>%
plot(breaks = "equal", text_values = TRUE, text_color = 'orange', axes = TRUE)
st_as_stars(r2[,2:4,2:4]) %>%
merge() %>%
plot(breaks = "equal", text_values = TRUE, text_color = 'orange', axes = TRUE)
Finally, an example where the first raster has the higher resolution:
r3 = read_stars(c(fn6, fn5, fn4), proxy = TRUE))
(## multi-resolution stars_proxy object with 3 attributes in 3 file(s):
## $`6`
## [1] "[...]/img6.tif"
##
## $`5`
## [1] "[...]/img5.tif"
##
## $`4`
## [1] "[...]/img4.tif"
##
## dimension(s):
## from to offset delta x/y
## x 1 12 0 0.3333 [x]
## y 1 12 4 -0.3333 [y]
st_as_stars(r3) %>%
merge() %>%
plot(breaks = "equal", text_values = TRUE, text_color = 'orange', axes = TRUE)
st_as_stars(r3[,2:6,3:6]) %>%
merge() %>%
plot(breaks = "equal", text_values = TRUE, text_color = 'orange', axes = TRUE)