GIFT tutorial for advanced users

Pierre Denelle & Patrick Weigelt

2024-02-27


This vignette documents some functions and specificities that were not presented in the main vignette of the package. It is mainly intended for advanced users of the GIFT database.

1. Versions and metadata for checklists

All functions in the package have a version argument. This argument allows you to retrieve different instances of the GIFT database and thus make all previous studies using the GIFT database reproducible. For example, the version used in Weigelt et al. (2020) is "1.0". To get more information about the contents of the different versions, you can go here and click on the Version Log tab.

To access all the available versions of the database, you can run the following function:

versions <- GIFT_versions()
kable(versions, "html") %>%
  kable_styling(full_width = FALSE)
ID version description taxonomy phylogeny overlap
1 1.0 2018-08-08: Data included in and workflows used to assemble GIFT 1.0 are described in detail in: Weigelt, P., König, C. & Kreft, H. (2020) GIFT – A Global Inventory of Floras and Traits for macroecology and biogeography. Journal of Biogeography, 47, 16-43. doi: 10.1111/jbi.13623 The Plant List 1.1 and resources used by TNRS at the time NA gaptani (version: okt2005, ID_column: UNITID); glonaf (version: 2017-06-12; ID_column: OBJIDsic); gmba (version: 1.0, ID_column: rownames)
2 2.0 2019-09-01: New checklist and trait data included for Europe, the Mediterranean, temperate Asia, Panama, Japan, Java, New Zealand, Easter Island and the Torres Strait Islands. Updated workflows to document biases in the distribution of trait data; Updated taxonomic trait derivation; Final trait values and agreement scores for trait values from several resources are now calculated separately including and excluding restricted resources. The Plant List 1.1 and resources used by TNRS at the time NA gaptani (version: okt2005, ID_column: UNITID); glonaf (version: 2017-06-12; ID_column: OBJIDsic); gmba (version: 1.0, ID_column: rownames)
3 2.1 2021-05-21: New checklists and traits included for the Americas, Crimea, Madagascar, Arabian peninsula, Laos, Bhutan, India, China, Sunda-Sahul shelf, Tonga, Canary Islands, West Africa and for ferns and palms globally. Large categorical trait data included from Try. The Plant List 1.1 and resources used by TNRS at the time NA gaptani (version: okt2005, ID_column: UNITID); glonaf (version: 2017-06-12; ID_column: OBJIDsic); gmba (version: 1.0, ID_column: rownames)
4 2.2 2022-05-30: New checklists (with a focus on endemic species) and traits for various oceanic archipelagos (Cook Islands, Madeira, Arctic Islands, Cayman Islands, Comores, Juan Fernandez, Palau, Galapagos, Frisian Islands, Antilles, Japan, Mayotte, Fiji, Taiwan, etc.) and various mainland regions (Equatorial Guinea and the entire former USSR in sub-regions). The Plant List 1.1 and resources used by TNRS at the time NA gaptani (version: okt2005, ID_column: UNITID); glonaf (version: 2017-06-12; ID_column: OBJIDsic); gmba (version: 1.0, ID_column: rownames)
5 3.0 2023-06-30: New data and updated workflows as described in: Denelle, P., Weigelt, P. & Kreft, H. (2023) GIFT - an R package to access the Global Inventory of Floras and Traits. BioRxiv, doi: 10.1101/2023.06.27.546704. Updated workflows include: (1) New taxonomic name standardization based on WCVP; (2) More statistics on species level trait aggregation; (3) Updated extraction of raster layer values per GIFT region and new raster resources; (4) Updated phylogeny. World Checklist of Vascular Plants (WCVP, v9) and resources used by TNRS at the time Phylogeny built using U.PhyloMaker R-package (Jin & Qian, 2022) based on the GBOTB megatree from Smith & Brown (2018) and Zanne et al. (2014), standardized according to WCVP. gaptani (version: okt2005, ID_column: UNITID); glonaf (version: 2021-07-02; ID_column: OBJIDsic); gmba (version: 1.2, ID_column: rownames)
6 3.1 2023-11-11: New checklist data for Mongolia and Farasan Archipelago and correction of seed traits for Hawaii (ref 16; units). World Checklist of Vascular Plants (WCVP, v9) and resources used by TNRS at the time Phylogeny built using U.PhyloMaker R-package (Jin & Qian, 2022) based on the GBOTB megatree from Smith & Brown (2018) and Zanne et al. (2014), standardized according to WCVP. gaptani (version: okt2005, ID_column: UNITID); glonaf (version: 2021-07-02; ID_column: OBJIDsic); gmba (version: 2.0, ID_column: GMBA_V2_ID)

The version column of this table is the one to use if you want to retrieve past versions of the GIFT database. By default, the argument used is GIFT_version = "latest" which leads to the current latest stable version of the database (“2.0” in October 2022).

The GIFT_lists() function can be run to retrieve metadata about the GIFT checklists. In the next chunk, we call it with different values for the GIFT_version argument.

list_latest <- GIFT_lists(GIFT_version = "latest") # default value
list_1 <- GIFT_lists(GIFT_version = "1.0")

The number of available checklists was 3122 in the version 1.0 and equals 4475 in the version 2.0.


2. References

When using the GIFT database in a research article, it is a good practice to cite the references used, and list them in an Appendix. The following function retrieves the reference for each checklist, as well as some metadata. References are documented in the ref_long column.

ref <- GIFT_references()
ref <- ref[which(ref$ref_ID %in% c(22, 10333, 10649)),
           c("ref_ID", "ref_long", "geo_entity_ref")]

# 3 first rows of that table
kable(ref, "html") %>%
  kable_styling(full_width = FALSE)
ref_ID ref_long geo_entity_ref
22 22 Kirchner, Picot, Merceron & Gigot (2010) Flore vasculaire de La Réunion. Conservatoire Botanique National de Mascarin, Réunion; France. La Réunion
667 10333 Zizka (1991) Flowering plants of Easter Island. Palmarum hortus francofurtensis 3, 3-108. Easter Island
880 10649 Pavlov (1954-1966) Flora Kazakhstana. Nauka Kazakhskoy SSR, Alma-Ata, Kazakhstan. Kazakhstan


The next chunk describes the steps to retrieve the publication sources when you start from specific regions, let’s say the Canary islands.

# List of all regions
regions <- GIFT_regions()

# Example
can <- 1036 # entity ID for Canary islands

# What references
gift_lists <- GIFT_lists()

can_ref <- gift_lists[which(gift_lists$entity_ID %in% c(can)), "ref_ID"]

# What sources
kable(ref[which(ref$ref_ID %in% can_ref), ], "html") %>%
  kable_styling(full_width = TRUE)
ref_ID ref_long geo_entity_ref


3. Checklist data

The main wrapper function for retrieving checklists and their species composition is GIFT_checklists() but you can also retrieve individual checklists using GIFT_checklists_raw(). You would need to know the identification number list_ID of the checklists you want to retrieve.
To quickly see all the list_ID available in the database, you can run GIFT_lists() as shown in Section 1.


When calling GIFT_checklists_raw(), you can set the argument namesmatched to TRUE in order to get additional columns informing about the taxonomic harmonization that was performed when the list was uploaded to the GIFT database.

listID_1 <- GIFT_checklists_raw(list_ID = c(11926))
listID_1_tax <- GIFT_checklists_raw(list_ID = c(11926), namesmatched = TRUE)

ncol(listID_1) # 16 columns
ncol(listID_1_tax) # 33 columns
length(unique(listID_1$work_ID)); length(unique(listID_1_tax$orig_ID))

In the list we called up, you can see that we “lost” some species after the taxonomic harmonization since we went from 1331 in the source to 1106 after the taxonomic harmonization. This means that several species were considered as synonyms or unknown plant species in the taxonomic backbone used for harmonization.

Note: the main service used for taxonomic harmonization of species names was The Plant List up to version 2.0 and World checklist of Vascular Plants afterwards.


4. Spatial subset

In the main vignette, we illustrated how to retrieve checklists that fall into a provided shapefile, using the western Mediterranean basin provided with the GIFT R package.

data("western_mediterranean")

Here we provide more details on the different values the overlap argument can take, using the GIFT_spatial() function. The following figure illustrates how this argument works:


Figure 1. GIFT spatial

Figure 1. GIFT spatial


We now illustrate this by retrieving checklists falling in the western Mediterranean basin using the four options available.

med_centroid_inside  <- GIFT_spatial(shp = western_mediterranean,
                                     overlap = "centroid_inside")
med_extent_intersect <- GIFT_spatial(shp = western_mediterranean,
                                     overlap = "extent_intersect")
med_shape_intersect <- GIFT_spatial(shp = western_mediterranean,
                                    overlap = "shape_intersect")
med_shape_inside <- GIFT_spatial(shp = western_mediterranean,
                                 overlap = "shape_inside")
length(unique(med_extent_intersect$entity_ID))
length(unique(med_shape_intersect$entity_ID))
length(unique(med_centroid_inside$entity_ID))
length(unique(med_shape_inside$entity_ID))

We see here that we progressively lose lists as we apply more selective criterion on the spatial overlap. The most restrictive option being overlap = "shape_inside" with 72 regions, then overlap = "centroid_inside" with 84 regions, overlap = "shape_intersect" with 104 regions and finally the less restrictive one being overlap = "extent_intersect" with 108 regions.
Using the functions GIFT_shapes() and calling it for the entity_IDs retrieved in each instance, we can download the shape files for each region.

geodata_extent_intersect <- GIFT_shapes(med_extent_intersect$entity_ID)

geodata_shape_inside <-
  geodata_extent_intersect[which(geodata_extent_intersect$entity_ID %in%
                                   med_shape_inside$entity_ID), ]
geodata_centroid_inside <-
  geodata_extent_intersect[which(geodata_extent_intersect$entity_ID %in%
                                   med_centroid_inside$entity_ID), ]
geodata_shape_intersect <-
  geodata_extent_intersect[which(geodata_extent_intersect$entity_ID %in%
                                   med_shape_intersect$entity_ID), ]

And then make a map.

par_overlap <- par(mfrow = c(2, 2), mai = c(0, 0, 0.5, 0))
plot(sf::st_geometry(geodata_shape_inside),
     col = geodata_shape_inside$entity_ID,
     main = paste("shape inside\n",
                  length(unique(med_shape_inside$entity_ID)),
                  "polygons"))
plot(sf::st_geometry(western_mediterranean), lwd = 2, add = TRUE)

plot(sf::st_geometry(geodata_centroid_inside),
     col = geodata_centroid_inside$entity_ID,
     main = paste("centroid inside\n",
                  length(unique(med_centroid_inside$entity_ID)),
                  "polygons"))
points(geodata_centroid_inside$point_x, geodata_centroid_inside$point_y)
plot(sf::st_geometry(western_mediterranean), lwd = 2, add = TRUE)

plot(sf::st_geometry(geodata_shape_intersect),
     col = geodata_shape_intersect$entity_ID,
     main = paste("shape intersect\n",
                  length(unique(med_shape_intersect$entity_ID)),
                  "polygons"))
plot(sf::st_geometry(western_mediterranean), lwd = 2, add = TRUE)

plot(sf::st_geometry(geodata_extent_intersect),
     col = geodata_extent_intersect$entity_ID,
     main = paste("extent intersect\n",
                  length(unique(med_extent_intersect$entity_ID)),
                  "polygons"))
plot(sf::st_geometry(western_mediterranean), lwd = 2, add = TRUE)
par(par_overlap)


5. Remove overlapping regions

GIFT comprises many polygons and for some regions, there are several polygons overlapping. How to remove overlapping polygons and the associated parameters are two things detailed in the main vignette. We here provide further details:

length(med_shape_inside$entity_ID)
## [1] 72
length(GIFT_no_overlap(med_shape_inside$entity_ID, area_threshold_island = 0,
                       area_threshold_mainland = 100, overlap_threshold = 0.1))
## [1] 53
# The following polygons are overlapping:
GIFT_no_overlap(med_shape_inside$entity_ID, area_threshold_island = 0,
                area_threshold_mainland = 100, overlap_threshold = 0.1)
##  [1]   145   146   147   148   149   150   151   414   415   416   417   547
## [13]   548   549   550   551   552   586   591   592   736   738   739 10001
## [25] 10072 10104 10184 10303 10422 10430 10978 11029 11030 11031 11033 11035
## [37] 11038 11039 11042 11044 11045 11046 11434 11474 11477 11503 12231 12232
## [49] 12233 12632 12633 12634 12635
# Example of two overlapping polygons: Spain mainland and Andalusia
overlap_shape <- GIFT_shapes(entity_ID = c(10071, 12078))
par_overlap_shp <- par(mfrow = c(1, 1))
plot(sf::st_geometry(overlap_shape),
     col = c(rgb(red = 1, green = 0, blue = 0, alpha = 0.5),
             rgb(red = 0, green = 0, blue = 1, alpha = 0.3)),
     lwd = c(2, 1),
     main = "Overlapping polygons")

par(par_overlap_shp)

GIFT_no_overlap(c(10071, 12078), area_threshold_island = 0,
                area_threshold_mainland = 100, overlap_threshold = 0.1)
## [1] 12078
GIFT_no_overlap(c(10071, 12078), area_threshold_island = 0,
                area_threshold_mainland = 100000, overlap_threshold = 0.1)
## [1] 10071


5.2. By ref_ID

In GIFT_checklists(), there is also the possibility to remove overlapping polygons only if they belong to the same reference (i.e. same ref_ID).

We show how this works with the following example:

ex <- GIFT_checklists(taxon_name = "Tracheophyta", by_ref_ID = FALSE,
                      list_set_only = TRUE, GIFT_version = "3.0")
ex2 <- GIFT_checklists(taxon_name = "Tracheophyta",
                       remove_overlap = TRUE, by_ref_ID = TRUE,
                       list_set_only = TRUE, GIFT_version = "3.0")
ex3 <- GIFT_checklists(taxon_name = "Tracheophyta",
                       remove_overlap = TRUE, by_ref_ID = FALSE,
                       list_set_only = TRUE, GIFT_version = "3.0")

length(unique(ex$lists$ref_ID)) # 369 checklists
length(unique(ex2$lists$ref_ID)) # 364 checklists
length(unique(ex3$lists$ref_ID)) # 336 checklists

Asking for checklists of vascular plants, we get 369 checklists without any overlapping criterion, 336 if we remove overlapping polygons and 364 if we remove overlapping polygons at the reference level.

So what is the difference between the second and third case?
Let’s look at the checklists that are present in the second example but not in the third.

unique(ex2$lists$ref_ID)[!(unique(ex2$lists$ref_ID) %in%
                             unique(ex3$lists$ref_ID))] # 28 references

28 references are in the second example (overlapping regions removed at the reference level) and not in the third (all overlapping regions removed). If we look at one of the listed references ref_ID = 10143, we see that it is a checklist for the Pilbara region in Australia. Its entity_ID is 10043. Looking at the GIFT web site, we see that other regions can overlap with it.

# Pilbara region Australy and overlapping shapes
pilbara <- GIFT_shapes(entity_ID = c(10043, 12172, 11398, 11391, 10918))
ggplot(pilbara) +
  geom_sf(aes(fill = as.factor(entity_ID)), alpha = 0.5) +
  scale_fill_brewer("entity_ID", palette = "Set1")

Since these polygons do not belong to the same ref_ID, they are kept if by_ref_ID = TRUE but are removed if by_ref_ID = FALSE.

6. Species

All the plant species present in the GIFT database can be retrieved using GIFT_species().

species <- GIFT_species()

To add additional information, like their order or family, we can call GIFT_taxgroup().

# Add Family
species$Family <- GIFT_taxgroup(
  as.numeric(species$work_ID), taxon_lvl = "family", return_ID = FALSE, 
  species = species)

Order or higher levels can also be retrieved.

GIFT_taxgroup(as.numeric(species$work_ID[1:5]), taxon_lvl = "order",
              return_ID = FALSE)
GIFT_taxgroup(as.numeric(species$work_ID[1:5]),
              taxon_lvl = "higher_lvl", return_ID = FALSE,
              species = species)


As mentioned above, plant species names may vary from the original sources they come from to the final work_species name they get, due to the taxonomic harmonization procedure. Looking up a species and the different steps of taxonomic harmonization is possible with the GIFT_species_lookup() function.

Fagus <- GIFT_species_lookup(genus = "Fagus", epithet = "sylvatica",
                             namesmatched = TRUE)

In this table, we can see that the first entry Fagus silvatica was later changed to the accepted name Fagus sylvatica.


6.2. Retrieve work_IDs for external species list

sp_list <- c("Anemone nemorosa", "Fagus sylvatica")

gift_sp <- GIFT_species()

sapply(sp_list, function(x) grep(x, gift_sp$work_species))
gift_sp[sapply(sp_list, function(x) grep(x, gift_sp$work_species)), ]

# With fuzzy matching
# library("fuzzyjoin")
# library("dplyr")
sp_list <- data.frame(work_species = c("Anemona nemorosa", "Fagus sylvaticaaa"))

fuzz <- stringdist_join(sp_list, gift_sp,
                        by = "work_species",
                        mode = "left",
                        ignore_case = FALSE, 
                        method = "jw", 
                        max_dist = 99, 
                        distance_col = "dist") 

fuzz %>%
  group_by(work_species.x) %>%
  slice_min(order_by = dist, n = 1)

7. Taxonomy

The taxonomy used in GIFT database can be downloaded using GIFT_taxonomy().

taxo <- GIFT_taxonomy()


8. Overlap_GloNAF tables (and others)

Since other global databases of plant diversity exist and may be based on different polygons, we provide a function GIFT_overlap() than can look at the spatial overlap between GIFT polygons and polygons coming from other databases.
So far, only two resources are available: glonaf and gmba. glonaf stands for Global Naturalized Alien Flora and gmba for Global Mountain Biodiversity Assessment.

GIFT_overlap() returns the spatial overlap in percent for each pairwise combination of polygons between GIFT and the other resource.

Let’s illustrate this with the GMBA shapefile.

gmba_overlap <- GIFT_overlap(resource = "gmba")

kable(gmba_overlap[1:5, ], "html") %>%
  kable_styling(full_width = FALSE)
entity_ID gmba_ID overlap12 overlap21
12094 12159 0.1783509 0.7623728
12094 11134 0.0060051 0.9985861
12094 12218 0.1398757 0.7948085
12094 16791 0.0301742 0.9385561
12094 16809 0.0036777 0.9566831

We see that two overlap columns are returned: overlap12 and overlap21.
The first column returns the overlap between the GIFT region and the other resource. The second column returns the overlap between the other resource and the GIFT region.
For example, if we look at the polygon 11861 of GIFT:

gmba_overlap[which(gmba_overlap$entity_ID == 11861 &
                     gmba_overlap$gmba_ID == 731), ]
## [1] entity_ID gmba_ID   overlap12 overlap21
## <0 rows> (or 0-length row.names)

The corresponding region is the Aisen province in Chile and it overlaps at 95% with the GMBA polygon number 731.
At the same time the GMBA polygon 731 only overlaps at 13% with the Aisen province of Chile.
This is because the corresponding mountain region is larger than the GIFT region and encompasses it as we can see on this plot (the dark polygon is the GIFT region):


References

Denelle, P., Weigelt, P., & Kreft, H. (2023). GIFT—An R package to access the Global Inventory of Floras and Traits. Methods in Ecology and Evolution, 00, 1–11. https://doi.org/10.1111/2041-210X.14213.

Weigelt, P., König, C. & Kreft, H. (2020) GIFT – A Global Inventory of Floras and Traits for macroecology and biogeography. Journal of Biogeography, https://doi.org/10.1111/jbi.13623.