﻿---
title: "Enriching results with trait and status data"
output: rmarkdown::html_vignette
vignette: >
  %\VignetteIndexEntry{Enriching results with trait and status data}
  %\VignetteEngine{knitr::rmarkdown}
  %\VignetteEncoding{UTF-8}
---

```{r setup, include = FALSE}
knitr::opts_chunk$set(
  collapse = TRUE,
  comment = "#>",
  eval = FALSE
)
```

Taxonomic name matching is rarely the end goal. Once `taxify()` has resolved
a list of species names against a backbone, the next step is usually joining
ecological trait data, conservation assessments, or geographic range
information to the matched names. This step is where the real analytical
value emerges, and it is also where most workflows hit friction: trait
databases use different taxonomic authorities, store names with or without
authorship strings, treat synonyms inconsistently, and distribute data in
incompatible formats. Manually aligning names between a taxonomic backbone
and a trait database can consume hours even for moderately sized species
lists.

taxify ships with more than sixty enrichment layers that attach published
trait and status datasets to a `taxify()` result in a single pipe call. Each
enrichment is backed by a pre-built `.vtr` file that downloads automatically
on first use and caches locally for all subsequent sessions. The enrichment
system handles the name alignment problem at build time, so the join at
analysis time is a simple, fast, exact-match operation.

This vignette covers the mechanics of how enrichments work, walks through a
representative set of layers with worked examples, and discusses practical
strategies for combining enrichments, interpreting coverage gaps, and
choosing the right layers for a given taxon group. `list_enrichments()` prints
the full current set with versions and coverage. We also discuss the
`add_data()` function for joining custom datasets that go beyond the
built-in enrichments.


## How enrichments work

Every `add_*()` function performs the same underlying operation: a left join
between the `accepted_name` column in a `taxify()` result and the
`canonical_name` column in an enrichment `.vtr` file. Because the join key
is the accepted (resolved) name rather than the original input, synonyms
that were resolved during matching contribute automatically. If the input
contained "Pinus abies" and the backbone resolved it to "Picea abies", the
enrichment join looks up "Picea abies" in the trait database. This means
we never have to worry about whether our species list uses currently accepted
names or outdated synonyms: the backbone resolution step has already
normalized everything.

This design has a deliberate consequence: enrichments only produce values
for rows that were successfully matched by `taxify()`. Rows where
`accepted_name` is `NA` (unmatched names) always receive `NA` in all
enrichment columns. If a species could not be resolved against the backbone,
it cannot be looked up in a trait database either. This is usually the
correct behavior, but it means that improving match rates upstream (by
cleaning names, trying a different backbone, or enabling fuzzy matching)
directly improves enrichment coverage downstream.

### The join in detail

When we call an enrichment function, taxify executes the following steps:

1. Ensures the enrichment `.vtr` file is present on disk (downloading it if
   needed).
2. Extracts the unique `accepted_name` values from the result.

3. Writes those unique names into a temporary `.vtr` file.

4. Performs a vectra `inner_join()` between the temporary names and the
   enrichment `.vtr` on the name column.
5. Uses a vectorized `match()` to fill the new trait columns back into the
   original result. Rows without a match receive `NA`.

The operation is fast because it reduces to a single hash-based lookup per
unique accepted name, not per row. A result with 50,000 rows but 8,000
unique accepted names only does 8,000 lookups. The vectra join exploits
hash indexes on the `canonical_name` column in the enrichment `.vtr`,
making even enrichments with hundreds of thousands of rows resolve in
under a second.

### Cross-backbone name resolution

A subtle but important design decision underlies the enrichment `.vtr`
files: they are built to work with any of taxify's seven backends (WFO,
COL, GBIF, ITIS, NCBI, OTT, WoRMS). Different backbones sometimes accept
different names for the same taxon. WFO might accept "Senecio jacobaea"
while COL accepts "Jacobaea vulgaris" for the same species. If the
enrichment `.vtr` only contained one of these names, it would fail to match
results from the other backbone.

The taxifydb build pipeline solves this by resolving every source
species name against each of the seven backends separately (not as a
fallback chain, which would only return the first match). The union of all
unique `accepted_name` values is collected per source species. Each source
row is then expanded: one enrichment row per distinct accepted name, with
the trait data duplicated. The final `.vtr` is then deduplicated by
`canonical_name` (plus any group column for grouped enrichments).

In practice, backends agree on more than 90% of names, so this expansion
is modest (typically 1.1–1.5x the original row count). The result is that
`add_iucn()` works identically whether the upstream
`taxify()` call used WFO, COL, or GBIF. We do not have to pick enrichments
based on which backbone we used, and we do not have to worry about
backbone-specific name variants falling through the cracks.

### Automatic download and caching

The first time an enrichment is requested in a session, taxify checks
whether a local copy exists on disk. If not, it downloads the pre-built
`.vtr` from GitHub Releases using the URL recorded in the package manifest
(`inst/manifest.json`). A `meta.json` sidecar file is written alongside
the `.vtr`, recording the version string, whether the dataset is static,
and the download date. On subsequent calls within the same R session, the
file path is served from an in-memory cache (a package-level environment),
so the disk is not even touched. Across sessions, the on-disk copy is
reused without any network request.

For enrichments marked as "static" in the manifest (version-locked datasets
like Zanne et al. 2014 or PanTHERIA), version checks are skipped entirely.
These datasets have fixed, published versions that will never change. For
non-static enrichments (IUCN Red List, GRIIS, WCVP, common names), taxify
performs a lightweight version check once per session by comparing the local
`meta.json` version against the manifest's `latest` field. If a newer
version is available, it is downloaded automatically with a console message.
This check adds negligible latency because the manifest itself is cached.

### Fallback chain

If the pre-built `.vtr` download fails (network issues, mirror outage,
transient server errors), taxify does not stop immediately. Instead, it
attempts to build the enrichment from the original source data. Each of
the 18 enrichments has a build recipe in an internal registry
(`.enrichment_build_registry`) that knows how to download the raw CSV, ZIP,
or API response from the upstream source, parse it into a data.frame with
a `canonical_name` column, and produce the `.vtr` file locally. This
build-from-source path is slower (it has to download and parse raw data
rather than a pre-built binary), but it means that enrichments remain
available even if the GitHub Releases mirror is temporarily down.

If the build-from-source also fails (e.g., the upstream source is
unreachable), taxify falls back one more level to an "emergency fallback":
it downloads and parses the source data in memory without writing to disk,
performs the join in-memory using a data.frame rather than a `.vtr`, and
issues a warning explaining the situation. This emergency result is
ephemeral and not cached. If all three paths fail, an error is raised with
a link to the GitHub issue tracker so the failure can be reported.

### ### The enrichment data directory

All enrichment `.vtr` files live under a single root directory, organized
by enrichment name and version:

```
taxify_data_dir()/
  enrichment/
    conservation_status/
      latest/
        conservation_status.vtr
        meta.json
    griis/
      latest/
        griis.vtr
        meta.json
    woodiness/
      latest/
        woodiness.vtr
        meta.json
    ...
```

The `taxify_data_dir()` function returns the platform-appropriate data
directory (typically `~/.local/share/taxify` on Linux/macOS or
`%LOCALAPPDATA%/taxify` on Windows). This directory is also where backbone
`.vtr` files are stored, so a single `taxify_data_dir()` call reveals
where all taxify data lives on the system. Enrichment files are modest in
size: most are between 1 and 20 MB. The full set of 18 enrichments totals
roughly 150-200 MB.


## Discovering enrichments

Before applying enrichments, we may want to see what is available.
`list_enrichments()` queries the taxify manifest and returns a data.frame
summarizing every available enrichment layer. The returned columns are:
`name`, `version`, `nrow` (approximate row count), `static` (whether the
dataset is version-locked), `trait_cols` (comma-separated list of trait
column names), and `source_url` (the upstream data source).

```{r list-enrichments}
library(taxify)

list_enrichments()
#>              name version   nrow static                              trait_cols ...
#> 1 conservation_status  ...  166000   TRUE                   conservation_status ...
#> 2               griis  ...   23000  FALSE                      invasive_status ...
#> 3                wcvp  ...  340000  FALSE                        native_status ...
#> ...
```

The `static` column is worth paying attention to. Static enrichments
(woodiness, PanTHERIA, AmphiBIO, EltonTraits, LEDA, Diaz traits,
FungalTraits, FUNGuild, AlgaeTraits, FISHMORPH, ReptTraits,
LepTraits, AnimalTraits, NW European Arthropods) are based on published,
version-locked datasets that have a single definitive release.
These never trigger version checks, so they add zero network overhead to
a session. Non-static enrichments (conservation_status, GRIIS, WCVP,
common_names) are periodically updated as the upstream source publishes new
releases. For these, taxify checks once per session whether a newer version
is available and updates transparently if so.

The `nrow` column gives a rough sense of enrichment size. Conservation
status has ~166,000 rows (one per assessed species), WCVP has ~340,000
(one per species-region combination), and the smaller enrichments like
LEDA have ~8,000. These numbers include the cross-backbone name expansion
discussed earlier, so they are slightly larger than the original source
row counts.

The `trait_cols` column lists the columns that the enrichment adds to a
result. This is useful for planning which enrichments to apply: if we need
specific leaf area data, scanning the `trait_cols` column reveals that LEDA
provides `sla_mm2_mg`. If we need diet composition data, the
`trait_cols` for `elton_traits` lists all 18 diet, foraging, mass, and
nocturnality columns. The `source_url` column points to the original data
source (Zenodo, Figshare, Dryad, GBIF, etc.) for reference and citation.


## One trait across sources: `add_trait()`

The `add_*()` doors each join a single dataset. When a trait is carried by more
than one source, `add_trait()` gathers them: name the trait and it pulls every
source that provides it, reconciling their vocabularies and units into shared
columns. `list_traits()` shows what is available.

```{r list-traits}
list_traits()
#>          trait              label        kind   unit n_sources    sources
#> 1    woodiness          Woodiness categorical   <NA>         2 zanne, gift
#> 2 plant_height       Plant height     numeric      m         2  diaz, gift
#> 3    seed_mass          Seed mass     numeric     mg         2  diaz, gift
#> 4          sla Specific leaf area     numeric mm2/mg         2  leda, gift
```

By default (`mode = "coalesce"`) `add_trait()` returns one value per row plus the
columns that document it: `<trait>_unit`, `<trait>_sources`, and `<trait>_n`.
Numeric traits are returned in one canonical unit regardless of how each source
stores them. GIFT records seed mass in grams and Diaz et al. in milligrams;
`add_trait("seed_mass")` reconciles both to milligrams and reports the median:

```{r add-trait-coalesce}
taxify("Abies alba") |>
  add_trait("seed_mass")
#> # accepted_name  ... seed_mass seed_mass_unit seed_mass_sources seed_mass_n
#> # Abies alba     ...   67.9748             mg        diaz,gift            2
```

To inspect the sources individually, `mode = "wide"` gives each its own column,
`<trait>_<source>`. Woodiness comes from both Zanne et al. and GIFT, harmonized
to one vocabulary (`woody` / `non-woody` / `variable`):

```{r add-trait-wide}
taxify("Abies alba") |>
  add_trait("woodiness", mode = "wide")
#> # accepted_name  ... woodiness_zanne woodiness_gift
#> # Abies alba     ...           woody          woody
```

When a trait's sources measure it by different methods, `add_trait()` does not
average them. It reports the most complete source and adds a `<trait>_caution`
column explaining the difference. Root diameter, for example, is fine-root in
GRooT but a maximum (including coarse roots) in AusTraits, so the two are not
blended into a value matching neither.

`trait_info()` lists a trait's sources, units, the harmonization applied to each,
and any method caution:

```{r trait-info}
trait_info("seed_mass")
#> Seed mass (numeric, mg)  |  default priority: diaz > gift
#>   source  enrichment       column                   note caution
#> 1   diaz diaz_traits seed_mass_mg            Milligrams.      NA
#> 2   gift        gift gift_seed_mass_mean GIFT grams -> mg.    NA
```

Restrict to particular sources with `sources =`, set the reducer with
`combine =`, and set the source order with `priority =`.

Enrichment doors are named after their source (`add_zanne()`, `add_iucn()`,
`add_griis()`, `add_fishmorph()`, `add_gift()`); trait names belong to
`add_trait()`.


## Pre-downloading enrichments

For workflows that run on computing clusters, in Docker containers, or in
any environment without reliable internet access, we can pre-download
enrichments before the analysis begins. The
`taxify_download_enrichment()` function accepts a character vector of
enrichment names and downloads each one to the local data directory.

```{r pre-download}
# Download a single enrichment
taxify_download_enrichment("conservation_status")

# Download several at once
taxify_download_enrichment(c("woodiness", "eive", "leda"))

# Download all of them
taxify_download_enrichment(c(
  "conservation_status", "griis", "wcvp", "eive",
  "elton_traits", "avonet", "pantheria", "amphibio",
  "common_names", "woodiness", "diaz_traits", "leda",
  "fungal_traits", "funguild", "algae_traits",
  "fish_traits", "fishbase", "repttraits", "anage", "glonaf",
  "leptraits", "animaltraits", "arthropod_traits", "alien_first_records",
  "baseflor", "ecoflora", "floraweb"
))
```

After this step, all subsequent `add_*()` calls for these enrichments will
use the local copies without any network access. This is particularly
useful for reproducible pipelines: pre-downloading enrichments at setup
time guarantees that the analysis always uses the same version of each
dataset, regardless of whether newer versions are published in the
meantime.

The download function prints a confirmation message with the version and
file size for each enrichment. If an enrichment is already present at the
requested version, it is not re-downloaded. The `.vtr` files live in
`taxify_data_dir()/enrichment/{name}/latest/` alongside their `meta.json`
sidecar.

Pre-downloading is also useful for teaching and workshop settings where many
participants share a slow network connection. One person can download the
enrichments, copy the `taxify_data_dir()` contents to a shared drive or USB
stick, and distribute it to all participants. Since the enrichment lookup
path starts with the on-disk check, the copied files will be found
immediately without any network access.


## Simple enrichments

Simple enrichments add one or more columns via a flat join on
`accepted_name`. Eighteen of the twenty-two enrichment layers use this
pattern. They differ only in which columns they add and which taxonomic
groups they cover. We group them below by taxon focus, starting with plants
(which have the most enrichment layers), then conservation status
(cross-taxon), birds, mammals, amphibians, vertebrates, fungi, algae,
fish, reptiles, butterflies, and arthropods.

### Plant enrichments

Plants are the best-served taxon group in the enrichment system, with
dedicated layers covering growth form, ecological niches, seed and height
traits, a broad suite of functional traits, and regional trait compilations
for the British, French, and German floras. This reflects the state of
published plant trait databases: decades of investment in standardized trait
measurement protocols have produced several large, open-access datasets
that are straightforward to integrate.

#### Woodiness (Zanne et al. 2014)

The woodiness enrichment classifies ~50,000 plant species as woody,
herbaceous, or variable. The dataset comes from Zanne et al. (2014), a
landmark study on the radiation of angiosperms into freezing environments,
published in *Nature*. The underlying classification draws on the world's
major herbarium and botanical databases.

```{r woodiness}
plants <- taxify(c(
  "Quercus robur", "Betula pendula", "Arrhenatherum elatius",
  "Festuca rubra", "Salix caprea", "Cornus sanguinea"
))

plants |> add_zanne()
#>               input_name       accepted_name woodiness
#> 1          Quercus robur       Quercus robur     woody
#> 2        Betula pendula      Betula pendula     woody
#> 3 Arrhenatherum elatius Arrhenatherum elatius herbaceous
#> 4         Festuca rubra        Festuca rubra herbaceous
#> 5         Salix caprea        Salix caprea     woody
#> 6    Cornus sanguinea     Cornus sanguinea     woody
```

The three possible values are `"woody"`, `"herbaceous"`, and `"variable"`.
The `"variable"` category applies to species that exhibit both growth forms
depending on environmental conditions or ecotype. Coverage is strongest for
angiosperms (both monocots and dicots) and weaker for ferns, lycophytes, and
bryophytes. The dataset is static (CC0 license, published 2014), so it
never triggers version checks.

Woodiness is a coarse trait, but it is one of the most widely used in
community ecology and macroecology. It separates plant strategies along
a fundamental axis (persistent woody stems vs. annual or perennial
herbaceous growth), making it valuable for community-weighted mean analyses,
functional diversity indices, and biome classification.

#### EIVE ecological indicator values (Dengler et al. 2023)

EIVE 1.0 provides continuous ecological indicator values for ~14,500
European vascular plant species. It supersedes the classic ordinal Ellenberg
indicator values, which were expert-assigned integers on a 1-9 scale, with
statistically derived continuous scores based on species co-occurrence
patterns across thousands of vegetation plots. Five niche axes are covered:
light, temperature, moisture, soil reaction (pH), and nutrients.

```{r eive}
grasses <- taxify(c(
  "Arrhenatherum elatius", "Bromus erectus", "Festuca rubra",
  "Dactylis glomerata", "Lolium perenne", "Poa pratensis"
))

grasses |> add_eive()
#>          input_name eive_light eive_temperature eive_moisture eive_reaction eive_nutrients
#> 1 Arrhenatherum ...       7.2              5.8           4.3           7.1            6.5
#> 2    Bromus erectus       7.6              5.5           3.1           7.8            3.2
#> ...
```

Because EIVE is restricted to the European flora, species from other
continents will receive `NA` in all five columns. The continuous values are
on a scale comparable to the original Ellenberg system (roughly 1-9) but
allow fractional positions. This matters for community-weighted mean (CWM)
calculations: averaging ordinal Ellenberg values treats the intervals
between categories as equal (the difference between 3 and 4 is the same as
between 7 and 8), which is not guaranteed. EIVE's continuous scale makes
CWM calculations statistically cleaner. The five output columns are
prefixed with `eive_` to avoid collision with columns from other sources:
`eive_light`, `eive_temperature`, `eive_moisture`, `eive_reaction`, and
`eive_nutrients`.

The EIVE dataset is licensed under CC BY 4.0 and published on Zenodo. It
is classified as static in the taxify manifest because its version (1.0) is
a fixed publication. The reference is Dengler et al. (2023), *Vegetation
Classification and Survey* 4:7-29.

#### Diaz traits (Diaz et al. 2022)

The Diaz enrichment provides two key functional traits from the TRY
database consortium: seed mass in milligrams and plant height in metres.
These are species-level means compiled from thousands of individual
measurements across multiple primary sources. Coverage spans ~46,000 plant
species globally, making it one of the broader trait datasets available for
plants.

```{r diaz-traits}
trees <- taxify(c(
  "Quercus robur", "Fagus sylvatica", "Picea abies",
  "Pinus sylvestris", "Acer pseudoplatanus"
))

trees |> add_diaz_traits()
#>          input_name seed_mass_mg plant_height_m
#> 1     Quercus robur      3200.0           25.0
#> 2  Fagus sylvatica      2200.0           30.0
#> 3      Picea abies        7.9           40.0
#> 4 Pinus sylvestris        6.5           25.0
#> 5 Acer pseudoplatanus   120.0           25.0
```

Seed mass and plant height sit on the two most important axes of the global
spectrum of plant form and function described by Diaz et al. (2016, *Nature*
529:167-171). Seed mass captures the offspring size / offspring number
trade-off (small-seeded species produce many propagules, large-seeded
species invest in fewer, better-provisioned offspring). Plant height
captures the competitive strategy axis (tall species intercept more light
but invest more in structural tissue). Combining these two traits with EIVE
or LEDA columns produces a reasonably complete functional characterization
for European temperate species.

The output columns are `seed_mass_mg` and `plant_height_m`. Both are
numeric (NA_real_ for missing values). The dataset is licensed under
CC BY 3.0 and distributed via the TRY File Archive.

#### LEDA Traitbase (Kleyer et al. 2008)

LEDA covers ~8,000 NW European plant species with 10 trait columns spanning
life form, dispersal, seed, leaf, and clonality dimensions. It is the most
column-rich of the simple enrichments, providing a broad functional profile
in a single call.

```{r leda}
meadow_spp <- taxify(c(
  "Arrhenatherum elatius", "Trifolium pratense",
  "Leucanthemum vulgare", "Plantago lanceolata",
  "Achillea millefolium", "Centaurea jacea"
))

meadow_spp |> add_leda()
#>          input_name raunkiaer_life_form dispersal_type sla_mm2_mg canopy_height_m ...
#> 1 Arrhenatherum ...  hemicryptophyte     anemochory       25.1            0.90  ...
#> 2 Trifolium pratense hemicryptophyte     zoochory         22.3            0.30  ...
#> ...
```

The full column set includes:

- `raunkiaer_life_form`: the primary Raunkiaer life form
  (phanerophyte, chamaephyte, hemicryptophyte, geophyte, therophyte,
  helophyte, hydrophyte).
- `raunkiaer_variable`: 1 if the species is assigned to multiple life
  forms, 0 otherwise.
- `dispersal_type`: primary dispersal vector (anemochory, zoochory,
  hydrochory, autochory, barochory, dysochory).
- `terminal_velocity_ms`: seed terminal velocity in m/s (species median).

- `seed_mass_mg`: seed mass in mg (species median).

- `canopy_height_m`: canopy height in metres (species median).

- `leaf_mass_mg`: leaf dry mass in mg (species median).

- `sla_mm2_mg`: specific leaf area in mm^2/mg (species median).

- `clonal_growth`: capable of clonal growth (1 = yes, 0 = no).

- `buoyancy`: seed buoyancy classification.

The Raunkiaer life form column classifies plants by where their
perennating buds sit during the unfavorable season. Phanerophytes (trees,
tall shrubs) hold buds more than 25 cm above the soil; chamaephytes (low
shrubs, cushion plants) keep them near the surface. Hemicryptophytes, the
dominant group in temperate grasslands, position buds right at soil level.
Below ground, geophytes store buds as bulbs or rhizomes, while therophytes
skip the problem entirely by surviving as seeds. LEDA provides this
classification at species level for the NW European flora, making it one of
the few trait databases that includes Raunkiaer assignments for several
thousand species.

One column-name collision to be aware of: LEDA's `seed_mass_mg` and the
Diaz enrichment's `seed_mass_mg` share the same output column name. If both
enrichments are stacked in a pipe chain, the second one to run will
overwrite the first. The values may differ slightly because LEDA reports the
species median from its own measurements while Diaz reports the TRY
consortium mean. To keep both, apply one enrichment, rename the column, then
apply the second. Alternatively, choose whichever source is more appropriate
for the study: LEDA for NW European analyses (regional measurements), Diaz
for global analyses (worldwide compilation).

#### Regional plant-trait compilations (Baseflor, Ecoflora, FloraWeb)

Three regional databases add trait detail for the European floras they cover.
Each carries a region suffix on every column (`_uk` for Britain, `_de` for
Germany, and Baseflor's unsuffixed French set), so they can be chained without
clobbering one another or the pan-European layers above.

- **Baseflor** (Julve, Programme Catminat), via `add_baseflor()`: about 8,500
  taxa of the French and neighbouring flora, with flowering months, pollination
  vector, dispersal mode, breeding system, flower colour, fruit type, woody
  growth form, and the continentality and salinity axes absent from EIVE.
- **Ecoflora** (Fitter & Peat 1994), via `add_ecoflora()`: the British Isles
  flora, with canopy height, leaf traits, life form, flowering phenology,
  pollination, seed weight, and British-calibrated Ellenberg values (18 `_uk`
  columns).
- **FloraWeb** (BfN; the BiolFlor data of Klotz, Kuehn & Durka 2002), via
  `add_floraweb()`: the German flora, with morphology, reproductive biology,
  the nine Ellenberg indicator values, ploidy and chromosome number, Grime CSR
  strategy type, and chorological distribution (59 `_de` columns).

```{r regional-plants, eval=FALSE}
taxify(c("Bellis perennis", "Achillea millefolium", "Calluna vulgaris")) |>
  add_ecoflora() |>
  add_floraweb()
```

Because every column is region-suffixed, one chain can attach British, French,
and German trait sets side by side for the same species. FloraWeb and Ecoflora
are bundled as pre-built datasets and work offline; their German and British
trait values are reported as published, and the access date is the dataset
version (neither portal offers a versioned bulk export). Italian Ellenberg-type
indicator values are also available through `add_pignatti()`, which reads the
copy bundled in the TR8 package on demand; those values come from a copyrighted
publication and are not redistributed by taxify.

#### Mycorrhizal type (FungalRoot, Soudzilovskaia et al. 2020)

Most vascular plants form a symbiosis with root fungi, and the *type* of that
symbiosis is one of the most informative functional traits a plant carries: it
governs how the plant acquires nutrients and which soil fungi it depends on.
`add_fungalroot()` attaches the mycorrhizal type from FungalRoot, a global
compilation of more than 36,000 plant-by-site observations published on GBIF.

Unlike the enrichments above, FungalRoot joins on `genus`, not `accepted_name`.
Mycorrhizal type is conserved at the genus level (the resolution FungalRoot
itself recommends for inference), so the value is a per-genus majority consensus
and every species in a covered genus inherits it, whether or not that exact
binomial was observed.

```{r fungalroot}
taxify(c("Quercus robur", "Pinus sylvestris", "Trifolium pratense",
         "Vaccinium myrtillus", "Brassica oleracea")) |>
  add_fungalroot()
#>          input_name     genus mycorrhizal_type mycorrhizal_status mycorrhizal_records
#> 1       Quercus robur   Quercus              EcM        mycorrhizal                 163
#> 2    Pinus sylvestris     Pinus              EcM        mycorrhizal                 500
#> 3  Trifolium pratense Trifolium               AM        mycorrhizal                 193
#> 4 Vaccinium myrtillus Vaccinium              ErM        mycorrhizal                 227
#> 5   Brassica oleracea  Brassica               NM    non-mycorrhizal                  59
```

Three columns are added:

- `mycorrhizal_type`: the genus-level consensus type. `AM` (arbuscular, by far
  the most common, formed by most herbs and many trees), `EcM` (ecto, typical of
  oaks, pines, birches, and other temperate forest trees), `ErM` (ericoid,
  confined to the Ericaceae), `OM` (orchid), `NM` (non-mycorrhizal, e.g. the
  Brassicaceae and many Cyperaceae), the dual types `EcM-AM` / `ErM-EcM` /
  `ErM-AM`, plus `Other` and `uncertain`.
- `mycorrhizal_status`: a coarse roll-up of the type, one of `"mycorrhizal"`,
  `"non-mycorrhizal"`, or `"uncertain"`.
- `mycorrhizal_records`: how many FungalRoot observations support the genus-level
  consensus, so a one-record genus can be told apart from a well-sampled one.

Because the join is on genus, a plant whose genus is not in FungalRoot returns
`NA`, and a genus circumscribed differently across backbones may not line up.
Coverage is plant genera only (about 4,000 genera). The dataset is distributed
under CC BY-NC 4.0; the per-genus consensus is computed by taxify from the
per-observation labels, not FungalRoot's own published genus assignment.

#### Global traits (GIFT, on demand)

GIFT, the Global Inventory of Floras and Traits (Weigelt et al. 2020), aggregates
published plant trait records worldwide into one value per species. `add_gift()`
attaches the traits you ask for, named `gift_<trait>`. Called with no `cols`
argument it uses a convenient default set of well-populated ones: woodiness,
growth form, life cycle, Raunkiaer life form, climbing, epiphytic, parasitic and
aquatic habit, maximum plant height, photosynthetic pathway, mean seed mass,
dispersal syndrome, flowering start and end month, deciduousness, and mean
specific leaf area.

```{r gift, eval=FALSE}
taxify(c("Abies alba", "Quercus robur")) |>
  add_gift()
```

Browse the available columns with `gift_traits()` and request any of them by
name, or pass `cols = "all"`:

```{r gift-select, eval=FALSE}
gift_traits()                                   # available trait columns

taxify(c("Abies alba", "Quercus robur")) |>
  add_gift(cols = c("plant_height_max", "sla_mean", "woodiness_1"))
```

GIFT's API exposes only the subset of its data it is licensed to redistribute
(CC BY 4.0; references whose underlying source is restricted are excluded).
taxifydb fetches that subset once at build time and it ships as a pre-built
`.vtr`, so `add_gift()` joins it offline, with no runtime API calls. Cite GIFT
and, where applicable, the underlying references (`GIFT::GIFT_references()`).

GIFT trait values are aggregated from many source references, each under its own
licence, and are served from a live API rather than an openly-licensed bulk
dump, so taxify does not redistribute them. `add_gift()` fetches them on demand
through the suggested GIFT package: the full trait table is downloaded once per
session and cached, and the values are joined to your result by accepted name.
The first call needs internet access, and you are responsible for citing GIFT
and the underlying references (`GIFT::GIFT_references()`) when you use the
values.

### Conservation status (IUCN Red List)

The conservation status enrichment is the only enrichment that spans all
taxonomic groups equally. Coverage includes ~166,000 species assessed by
the IUCN Red List, with representation across plants, vertebrates,
invertebrates, and fungi. A single column is added: `conservation_status`,
containing the standard IUCN category code.

```{r conservation-status}
species <- taxify(c(
  "Panthera tigris", "Ailuropoda melanoleuca",
  "Gorilla gorilla", "Vulpes vulpes",
  "Passer domesticus", "Quercus robur"
))

species |> add_iucn()
#>            input_name conservation_status
#> 1     Panthera tigris                  EN
#> 2 Ailuropoda melanoleuca               VU
#> 3      Gorilla gorilla                  CR
#> 4        Vulpes vulpes                  LC
#> 5   Passer domesticus                  LC
#> 6       Quercus robur                  LC
```

The seven categories in order of increasing threat are:

- **LC** (Least Concern): population stable, no significant threats.

- **NT** (Near Threatened): close to qualifying for a threatened category.

- **VU** (Vulnerable): facing a high risk of extinction in the wild.

- **EN** (Endangered): facing a very high risk of extinction.

- **CR** (Critically Endangered): facing an extremely high risk.

- **EW** (Extinct in the Wild): survives only in captivity or cultivation.

- **EX** (Extinct): no known living individuals.

Species not yet assessed by the IUCN receive `NA`. The IUCN has assessed
nearly all mammals, birds, amphibians, and reptiles, but only a fraction of
invertebrates, fungi, and plants. For a plant-focused study, coverage rates
are likely to be lower (perhaps 10-30% of the species list) than for a
vertebrate study (where 90-100% coverage is typical). The enrichment also
includes species assessed as DD (Data Deficient), which indicates that the
IUCN has examined the species but lacks sufficient data to assign a threat
category.

The conservation status enrichment is non-static: the IUCN publishes
updated assessments several times per year, and the taxify enrichment is
rebuilt when new assessments become available. The `summary()` output will
show the version string (e.g., "2025.1") so that the exact assessment
vintage can be cited.

### Bird enrichments

Birds are served by two complementary enrichments that together provide a
detailed functional and ecological profile. AVONET covers morphology and
migration strategy; EltonTraits covers diet composition and foraging
behavior. There is intentional overlap in body mass (both provide it), but
the remaining columns are distinct.

#### AVONET (Tobias et al. 2022)

AVONET provides species-level morphological measurements for ~11,000 bird
species worldwide, based on direct measurements of museum specimens and
live birds. The enrichment adds 11 columns covering beak dimensions
(length, depth), wing length, tail length, tarsus length, body mass,
hand-wing index, primary habitat, trophic level, trophic niche, and
migration strategy.

```{r avonet}
birds <- taxify(c(
  "Parus major", "Cyanistes caeruleus", "Erithacus rubecula",
  "Turdus merula", "Falco peregrinus", "Aquila chrysaetos"
))

birds |> add_avonet()
#>        input_name beak_length wing_length avonet_body_mass_g migration trophic_niche ...
#> 1     Parus major        11.2        75.1               18.5 sedentary  Invertivore  ...
#> 2 Cyanistes caeruleus    9.8        67.2               11.0 sedentary  Invertivore  ...
#> 3 Erithacus rubecula    11.5        72.3               17.1   partial  Invertivore  ...
#> 4    Turdus merula      20.8       130.5               95.0   partial    Omnivore   ...
#> 5 Falco peregrinus      15.2       312.0              750.0      full  Vertivore    ...
#> 6 Aquila chrysaetos     37.5       607.0             4000.0   partial  Vertivore    ...
```

The morphological measurements (beak, wing, tail, tarsus) are all in
millimetres, representing species means across measured specimens. The
hand-wing index (`hand_wing_index`) quantifies wing pointedness and
correlates strongly with long-distance flight ability: swifts, falcons, and
shearwaters score high, while wrens, rails, and pheasants sit at the low end
of the spectrum. Dispersal ecology, macroecology, and studies of range
expansion all make heavy use of this index.

The migration column has three possible values: `"sedentary"` (non-
migratory), `"partial"` (some populations migrate), and `"full"` (obligate
long-distance migrant). The trophic_niche column uses categories like
`"Invertivore"`, `"Omnivore"`, `"Vertivore"`, `"Frugivore"`,
`"Granivore"`, `"Nectarivore"`, `"Herbivore aquatic"`, and others.

AVONET is licensed under CC BY 4.0 and published on Figshare. The
reference is Tobias et al. (2022), *Ecology Letters* 25:581-597. The
dataset is classified as static in the taxify manifest.

#### EltonTraits (Wilman et al. 2014)

EltonTraits 1.0 covers both birds and mammals (~15,400 species total),
making it the only enrichment that spans two vertebrate classes. It adds
18 columns organized into three groups: 10 diet composition percentages,
6 foraging stratum percentages, body mass, and nocturnality.

The diet columns express the percentage contribution of each food category
to the species' diet: invertebrates (`diet_inv`), endothermic vertebrates
(`diet_vend`), ectothermic vertebrates (`diet_vect`), fish (`diet_vfish`),
unknown vertebrates (`diet_vunk`), scavenging (`diet_scav`), fruit
(`diet_fruit`), nectar (`diet_nect`), seeds and nuts (`diet_seed`), and
other plant material (`diet_plantother`). The 10 diet percentages sum to
100 for each species.

The foraging columns express where in the vertical habitat structure the
species forages: below water surface (`foraging_water`), on ground
(`foraging_ground`), in understory (`foraging_understory`), in mid to high
vegetation (`foraging_midhigh`), in canopy (`foraging_canopy`), and aerial
(`foraging_aerial`). These 6 percentages also sum to 100.

```{r elton-traits}
birds <- taxify(c(
  "Parus major", "Dendrocopos major", "Alcedo atthis",
  "Tyto alba", "Apus apus"
))

birds |> add_elton_traits()
#>       input_name diet_inv diet_fruit diet_seed foraging_canopy foraging_aerial nocturnal ...
#> 1    Parus major       60         10        20              50               0         0 ...
#> 2 Dendrocopos major    75          5        10              80               0         0 ...
#> 3   Alcedo atthis       0          0         0               0               0         0 ...
#> 4       Tyto alba       10          0         0               0               0         1 ...
#> 5       Apus apus      100          0         0               0             100         0 ...
```

The Common Swift (*Apus apus*) is a textbook example of a species at the
extreme of the foraging and diet axes: 100% invertebrate diet, 100% aerial
foraging, reflecting its life spent almost entirely on the wing. The Barn
Owl (*Tyto alba*) illustrates the nocturnal flag: it is one of the few
species in this example set with `nocturnal = 1`. The `elton_body_mass_g`
column provides body mass in grams from literature compilation.

EltonTraits is particularly valuable for functional diversity analyses
(computing Rao's quadratic entropy or functional richness using diet and
foraging traits as axes), food web construction (using diet percentages to
parameterize trophic links), and macroecological studies of niche breadth.
It is licensed under CC0 and published on Figshare. The reference is
Wilman et al. (2014), *Ecology* 95:2027.

### Mammal enrichments

#### PanTHERIA (Jones et al. 2009)

PanTHERIA covers ~5,400 mammal species with eight life-history and
ecological traits: adult body mass, maximum longevity, mean litter size,
gestation length, weaning age, home range size, diet breadth, and habitat
breadth. It remains the most-cited source of mammalian life-history data in
the ecological literature, despite being published in 2009.

```{r pantheria}
mammals <- taxify(c(
  "Vulpes vulpes", "Canis lupus", "Ursus arctos",
  "Mustela nivalis", "Lutra lutra", "Lynx lynx"
))

mammals |> add_pantheria()
#>      input_name pantheria_body_mass_g longevity_mo litter_size home_range_km2 ...
#> 1  Vulpes vulpes               5480.0          144         5.0           8.55 ...
#> 2   Canis lupus              31757.0          192         5.4         242.00 ...
#> 3  Ursus arctos             139000.0          396         2.0         488.00 ...
#> 4 Mustela nivalis               67.0           72         5.5           0.03 ...
#> 5   Lutra lutra               8000.0          180         2.3          15.00 ...
#> 6     Lynx lynx              20500.0          252         2.6         168.00 ...
```

The body mass column is named `pantheria_body_mass_g` to distinguish it
from AVONET's `avonet_body_mass_g` and EltonTraits' `elton_body_mass_g`.
This prefixing convention prevents column-name collisions when stacking
multiple enrichments on the same result.

The Least Weasel (*Mustela nivalis*) in the example above illustrates the
dynamic range of mammalian traits: at 67 g body mass and a home range of
0.03 km^2, it sits at the opposite end of the spectrum from the Brown Bear
(*Ursus arctos*) at 139,000 g and 488 km^2. These allometric scaling
relationships (body mass predicting home range, longevity, gestation, etc.)
are a major reason PanTHERIA is so widely cited.

Because PanTHERIA was published in 2009, species described or taxonomically
split after that date will appear as `NA`. The dataset is static (CC0
license), so it never triggers version checks. The reference is Jones et al.
(2009), *Ecology* 90:2648.

### Amphibian enrichments

#### AmphiBIO (Oliveira et al. 2017)

AmphiBIO covers ~6,800 amphibian species with 13 trait columns. The
continuous traits are body size (snout-vent length in mm), age at maturity
(days), longevity (days), clutch/litter size, reproductive output per year,
and offspring size (mm). The binary traits encode habitat and activity
patterns: direct development (0/1), larval stage (0/1), aquatic habitat
(0/1), fossorial habitat (0/1), arboreal habitat (0/1), diurnal activity
(0/1), and nocturnal activity (0/1).

```{r amphibio}
amphibians <- taxify(c(
  "Bufo bufo", "Rana temporaria", "Salamandra salamandra",
  "Triturus cristatus", "Hyla arborea", "Bombina variegata"
))

amphibians |> add_amphibio()
#>           input_name body_size_mm arboreal aquatic direct_development nocturnal_amphibio ...
#> 1          Bufo bufo        150.0        0       0                  0                  1 ...
#> 2    Rana temporaria        110.0        0       1                  0                  0 ...
#> 3 Salamandra salamandra    200.0        0       0                  0                  1 ...
#> 4  Triturus cristatus      160.0        0       1                  0                  1 ...
#> 5       Hyla arborea         50.0        1       0                  0                  1 ...
#> 6  Bombina variegata         50.0        0       1                  0                  0 ...
```

The nocturnality column is named `nocturnal_amphibio` rather than
`nocturnal` to avoid colliding with EltonTraits' `nocturnal` column.
While it is unusual to stack both AmphiBIO and EltonTraits on the same
result (EltonTraits covers birds and mammals, not amphibians), the
precaution prevents surprises in mixed-taxon workflows where both
enrichments are applied to a single data.frame.

The binary trait columns use integer values (0/1) rather than logical
(`TRUE`/`FALSE`), following the original dataset's encoding. This means
filtering syntax uses `== 1L` rather than bare column names:
`result[result$arboreal == 1L, ]`.

AmphiBIO is one of the few large-scale trait databases for amphibians, a
taxon group that is relatively data-poor compared to birds and mammals.
Coverage spans anurans (frogs and toads), urodeles (salamanders and newts),
and caecilians. It is licensed under CC BY 4.0 and published on
*Scientific Data*. The reference is Oliveira et al. (2017), *Scientific
Data* 4:170123.

### Fungal enrichments

Fungi have historically been underrepresented in trait databases compared
to plants and animals, but two complementary datasets now provide detailed
ecological and functional information. FungalTraits classifies genera by
lifestyle, growth form, and interaction capabilities, while FUNGuild
provides a guild-based trophic classification. Together they offer a
reasonably complete functional profile for macrofungi and many microfungi.

#### FungalTraits (Polme et al. 2020)

FungalTraits is a genus-level database covering ~10,200 fungal genera with
nine trait columns. Unlike the species-level enrichments discussed above,
FungalTraits joins on genus rather than `accepted_name`. This reflects the
reality of fungal trait data: most functional traits (lifestyle, growth form,
decay strategy) are conserved at the genus level, and the enormous diversity
of described fungal species (~150,000) makes species-level trait compilation
impractical for many attributes. The genus-level join means that all species
within a genus receive the same trait values, which is ecologically
reasonable for the traits covered.

```{r fungal-traits}
fungi <- taxify(c(
  "Amanita muscaria", "Boletus edulis", "Trametes versicolor",
  "Agaricus bisporus", "Cantharellus cibarius"
))

fungi |> add_fungal_traits()
#>          input_name primary_lifestyle  growth_form fruitbody_type decay_substrate ...
#> 1  Amanita muscaria   ectomycorrhizal     agaricoid      agaricoid            <NA> ...
#> 2    Boletus edulis   ectomycorrhizal       boletoid       boletoid            <NA> ...
#> 3 Trametes versicolor      saprotroph  polyporoid      polyporoid           wood  ...
#> 4 Agaricus bisporus       saprotroph     agaricoid      agaricoid          litter ...
#> 5 Cantharellus cibarius ectomycorrhizal cantharelloid cantharelloid          <NA> ...
```

The nine trait columns capture complementary facets of fungal ecology:

- `primary_lifestyle`: the dominant trophic strategy (ectomycorrhizal,
  saprotroph, plant pathogen, animal parasite, lichen, endophyte, etc.).
- `secondary_lifestyle`: an additional lifestyle where applicable (many
  genera have a single lifestyle, so this is frequently `NA`).
- `growth_form`: the vegetative morphology (agaricoid, boletoid,
  polyporoid, corticioid, clavarioid, gasteroid, etc.).
- `fruitbody_type`: the reproductive structure type.

- `decay_substrate`: the primary substrate for saprotrophic genera (wood,
  litter, dung, soil).
- `plant_pathogenic_capacity`: a coarse classification of pathogenic
  potential for plant-associated genera.
- `animal_biotrophic_capacity`: analogous classification for animal
  associations.
- `endophytic_interaction_capability`: whether the genus includes
  endophytic species.
- `ectomycorrhiza_exploration_type`: for ectomycorrhizal genera, the
  exploration type of the mycelium (contact, short-distance, medium-
  distance, long-distance). This is ecologically important because
  exploration type governs nutrient acquisition strategy and competitive
  dynamics among ectomycorrhizal fungi.

The `primary_lifestyle` column is the single most informative trait for
broad ecological analyses. It separates ectomycorrhizal fungi (mutualists
that form nutrient-exchange networks with plant roots) from saprotrophs
(decomposers that drive nutrient cycling) and pathogens (agents of disease
and mortality). These three groups have fundamentally different roles in
ecosystem functioning, and knowing which lifestyle a genus belongs to
determines how it should be interpreted in community analyses, food web
models, and carbon cycling studies.

FungalTraits is licensed under CC BY 4.0 and published in *Fungal
Diversity*. The reference is Polme et al. (2020), *Fungal Diversity*
105:1-16. The dataset is classified as static in the taxify manifest.

#### FUNGuild (Nguyen et al. 2016)

FUNGuild provides trophic and guild classifications for ~13,000 fungal
taxa at both genus and species levels. Where FungalTraits describes what
a genus does ecologically (lifestyle, growth form, substrate preference),
FUNGuild classifies taxa into guild categories that describe their
functional role in the ecosystem. The two datasets are complementary: a
genus like *Trametes* might be classified as "saprotroph" with "polyporoid"
growth form in FungalTraits, and as "Wood Saprotroph" guild with
"Saprotroph" trophic mode in FUNGuild. The FUNGuild classification is
coarser but more directly interpretable for guild-based community analyses.

```{r funguild}
fungi <- taxify(c(
  "Amanita muscaria", "Boletus edulis", "Trametes versicolor",
  "Agaricus bisporus", "Cantharellus cibarius"
))

fungi |> add_funguild()
#>          input_name     trophic_mode                   guild funguild_growth_form confidence_ranking
#> 1  Amanita muscaria       Symbiotroph       Ectomycorrhizal            Agaricoid            Highly Probable
#> 2    Boletus edulis       Symbiotroph       Ectomycorrhizal             Boletoid            Highly Probable
#> 3 Trametes versicolor      Saprotroph        Wood Saprotroph           Polyporoid            Highly Probable
#> 4 Agaricus bisporus       Saprotroph      Litter Saprotroph            Agaricoid            Highly Probable
#> 5 Cantharellus cibarius   Symbiotroph       Ectomycorrhizal        Cantharelloid            Highly Probable
```

The four output columns provide a hierarchical classification:

- `trophic_mode`: the broadest category (Saprotroph, Symbiotroph,
  Pathotroph, or combinations like Saprotroph-Symbiotroph for genera with
  multiple trophic strategies).
- `guild`: a finer classification within each trophic mode (Wood
  Saprotroph, Litter Saprotroph, Ectomycorrhizal, Arbuscular Mycorrhizal,
  Plant Pathogen, Animal Pathogen, Lichenized, etc.).
- `funguild_growth_form`: the morphological category, named with the
  `funguild_` prefix to avoid collision with FungalTraits' `growth_form`
  column.
- `confidence_ranking`: how confident the guild assignment is (Highly
  Probable, Probable, or Possible). This column deserves attention:
  assignments at the "Possible" level are based on limited evidence and
  should be treated with caution in quantitative analyses. Filtering to
  "Highly Probable" and "Probable" assignments reduces coverage but
  improves reliability.

FUNGuild is particularly valuable for soil mycobiome studies, where
operational taxonomic units (OTUs) from metabarcoding are classified into
ecological guilds. The trophic mode and guild columns map directly onto the
functional group categories used in fungal community ecology: the ratio of
saprotrophs to symbiotrophs, or the proportion of pathotrophs in a
community, are common response variables in studies of land use change,
nutrient cycling, and plant-soil feedbacks.

FUNGuild is published in *Fungal Ecology*. The reference is Nguyen et al.
(2016), *Fungal Ecology* 20:241-248. The dataset is classified as static
in the taxify manifest.

### Algae enrichments

#### AlgaeTraits (Vranken et al. 2023)

AlgaeTraits provides morphological and ecological traits for ~1,745
European macroalgae species (seaweeds). Macroalgae are the dominant primary
producers in coastal rocky ecosystems, yet they are conspicuously absent
from the major plant trait databases (TRY, LEDA, EIVE) that focus
exclusively on vascular plants. AlgaeTraits fills this gap for the
European coastline, covering green algae (Chlorophyta), brown algae
(Phaeophyceae), and red algae (Rhodophyta) with eight trait columns
spanning morphology, habitat, and environmental tolerances.

```{r algae-traits}
seaweeds <- taxify(c(
  "Fucus vesiculosus", "Ulva lactuca", "Laminaria digitata",
  "Chondrus crispus", "Sargassum muticum"
))

seaweeds |> add_algae_traits()
#>          input_name algae_body_size_cm algae_growth_form algae_calcification algae_tidal_zone ...
#> 1 Fucus vesiculosus               60.0          foliose               none         intertidal ...
#> 2      Ulva lactuca               30.0          foliose               none         intertidal ...
#> 3 Laminaria digitata             200.0          foliose               none         subtidal   ...
#> 4    Chondrus crispus              15.0          foliose               none         intertidal ...
#> 5  Sargassum muticum             300.0          foliose               none         subtidal   ...
```

All eight columns are prefixed with `algae_` to clearly distinguish them
from terrestrial plant traits:

- `algae_body_size_cm`: maximum thallus length in centimetres.

- `algae_growth_form`: the morphological category (filamentous, foliose,
  corticated, leathery, calcareous, crustose, etc.).
- `algae_calcification`: whether the species produces calcium carbonate
  structures (none, articulated, crustose). Calcifying algae like
  coralline species play a critical role in reef construction and are
  particularly sensitive to ocean acidification.
- `algae_life_span`: the typical life span category (annual, perennial,
  pseudoperennial).
- `algae_tidal_zone`: the primary tidal zone (supralittoral, intertidal,
  subtidal).
- `algae_wave_exposure`: the preferred wave exposure regime (sheltered,
  moderately exposed, exposed).
- `algae_environment`: the salinity regime (marine, brackish, freshwater).

- `algae_substrate`: the preferred substrate type (rock, sand, epiphytic,
  free-living).

The body size column spans three orders of magnitude, from millimetre-scale
filamentous algae to kelps exceeding 3 metres. This variation underpins the
structural complexity of rocky shore communities: large canopy-forming
species like *Laminaria digitata* create habitat for hundreds of associated
species, while small turf-forming species dominate in disturbed or
nutrient-enriched conditions. The growth form and tidal zone columns
together define the ecological niche of each species along the shore
gradient, making AlgaeTraits directly useful for intertidal community
analyses, climate change impact assessments, and marine protected area
planning.

The geographic scope is European, so species from other coastlines will
receive `NA` in all columns. The dataset is licensed under CC BY 4.0 and
published in *Scientific Data*. The reference is Vranken et al. (2023),
*Scientific Data* 10:826. The dataset is classified as static in the
taxify manifest.

### Fish enrichments

Fish ecology has produced two large, complementary trait databases.
FISHMORPH focuses on morphological measurements of freshwater species,
while FishBase provides broader ecological and life-history data for both
freshwater and marine fish. Together they provide detailed functional
profiles for ichthyological studies.

#### FISHMORPH (Brosse et al. 2021)

FISHMORPH provides morphological trait data for ~8,300 freshwater fish
species worldwide, based on standardized measurements from photographs
and museum specimens. The 10 morphological traits capture the key axes of
fish body shape variation that determine swimming performance, feeding
mode, and habitat use.

```{r fish-traits}
freshwater_fish <- taxify(c(
  "Salmo trutta", "Esox lucius", "Cyprinus carpio",
  "Perca fluviatilis", "Silurus glanis"
))

freshwater_fish |> add_fishmorph()
#>        input_name fish_body_elongation fish_eye_size fish_oral_gape_position fish_body_lateral_shape ...
#> 1    Salmo trutta                 0.22          0.08                    0.42                    0.18 ...
#> 2    Esox lucius                  0.18          0.06                    0.50                    0.15 ...
#> 3  Cyprinus carpio                0.35          0.05                    0.38                    0.25 ...
#> 4 Perca fluviatilis               0.30          0.07                    0.40                    0.22 ...
#> 5   Silurus glanis                0.15          0.03                    0.48                    0.12 ...
```

All columns are prefixed with `fish_` and express dimensionless
morphological ratios normalized by body length. The 10 traits are:

- `fish_body_elongation`: body depth relative to standard length. High
  values indicate deep-bodied species (cyprinids), low values indicate
  elongated species (eels, pike).
- `fish_eye_size`: eye diameter relative to head length. Large-eyed
  species tend to be visual predators in clear water.
- `fish_oral_gape_position`: the vertical position of the mouth, from
  ventral (benthic feeders) to dorsal (surface feeders).
- `fish_body_lateral_shape`: the lateral compression of the body.

- `fish_pectoral_fin_size`: pectoral fin area, associated with
  manoeuvrability and braking ability.
- `fish_pectoral_fin_position`: the vertical insertion of the pectoral
  fin on the body.
- `fish_caudal_peduncle_throttling`: the narrowing of the caudal
  peduncle, associated with sustained swimming efficiency.
- `fish_caudal_fin_shape`: the aspect ratio of the caudal fin. High
  values (forked tails) indicate cruising swimmers; low values (rounded
  tails) indicate ambush predators or benthic species.
- `fish_fin_surface_ratio`: total fin area relative to body area.

- `fish_max_body_length_cm`: the maximum recorded standard length in
  centimetres.

These morphological ratios are ecomorphological indicators: they predict
how a species interacts with its physical environment. Body elongation and
caudal fin shape together separate benthic, slow-moving species from
pelagic, fast-cruising species. Oral gape position separates surface
feeders from bottom feeders. Eye size and pectoral fin size relate to
sensory ecology and manoeuvrability, respectively. The combination of
these traits places each species in morphological space, making FISHMORPH
directly useful for functional diversity calculations (Rao's Q, functional
richness, functional divergence) in freshwater fish community ecology.

The dataset covers freshwater fish only; marine species receive `NA`. It
is licensed under CC BY 4.0 and published in *Global Ecology and
Biogeography*. The reference is Brosse et al. (2021), *Global Ecology
and Biogeography* 30:2330-2345. The dataset is classified as static in
the taxify manifest.

#### FishBase (Froese & Pauly 2024)

FishBase is the most comprehensive fish database in the world, covering
~35,000 species across both freshwater and marine environments. The taxify
enrichment extracts eight key ecological and life-history traits from the
FishBase dataset, providing a broad functional profile that complements
FISHMORPH's morphological focus.

```{r fishbase}
fish <- taxify(c(
  "Gadus morhua", "Thunnus thynnus", "Hippocampus hippocampus",
  "Squalus acanthias", "Salmo trutta"
))

fish |> add_fishbase()
#>              input_name fb_body_length_cm fb_body_mass_g fb_trophic_level fb_depth_min_m fb_depth_max_m ...
#> 1          Gadus morhua            132.0        55500.0              4.4            0.0          600.0 ...
#> 2      Thunnus thynnus            458.0       684000.0              4.2            0.0         1000.0 ...
#> 3 Hippocampus hippocampus          15.0             NA              3.1            1.0           60.0 ...
#> 4    Squalus acanthias            160.0         11000.0              4.3           16.0          900.0 ...
#> 5         Salmo trutta            140.0        50000.0              3.4            0.0          332.0 ...
```

The eight columns are all prefixed with `fb_`:

- `fb_body_length_cm`: maximum total length in centimetres.

- `fb_body_mass_g`: maximum recorded body mass in grams.

- `fb_trophic_level`: the trophic level (continuous, typically 2.0-5.0).
  Herbivorous fish sit near 2.0, planktivores around 3.0, piscivores
  around 4.0-4.5, and apex predators above 4.5.
- `fb_depth_min_m` and `fb_depth_max_m`: the minimum and maximum depth
  range in metres. Together these define the vertical habitat envelope.
- `fb_vulnerability`: the intrinsic vulnerability index (0-100), a
  composite score based on maximum size, age, fecundity, and other
  life-history parameters. High values indicate species that are
  inherently more susceptible to overexploitation.
- `fb_habitat`: the primary habitat category (pelagic, demersal,
  bathydemersal, bathypelagic, reef-associated, etc.).
- `fb_importance`: the economic importance category (commercial,
  subsistence, minor commercial, gamefish, etc.).

The trophic level and vulnerability columns are particularly valuable for
fisheries ecology and marine conservation. Trophic level quantifies the
position of each species in the food web, and the well-documented pattern
of "fishing down the food web" (declining mean trophic level of catches
over time) is diagnosed using exactly this variable. Vulnerability
provides a quick assessment of which species in a community are most at
risk from fishing pressure, complementing the IUCN conservation status
with a mechanistic, trait-based risk metric.

Note that FishBase is licensed under CC BY-NC 3.0 (non-commercial use).
This is more restrictive than the CC BY 4.0 license used by most other
enrichments. Users intending to use FishBase data in commercial
applications should consult the FishBase terms of use. The reference is
Froese, R. and D. Pauly (2024), FishBase, www.fishbase.org. The dataset
is classified as non-static in the taxify manifest because FishBase is
updated periodically.

### Reptile enrichments

#### ReptTraits (Oskyrko et al. 2024)

ReptTraits covers 12,060 reptile species across all reptile groups: snakes,
lizards, amphisbaenians, turtles, crocodiles, and the tuatara. It is built
on the Reptile Database taxonomy, so it joins cleanly against the
`reptiledb` backbone. Alongside body-size and life-history traits it carries
a per-species distribution signal: biogeographic realm, elevation range, and
mean climate.

```{r repttraits}
reptiles <- taxify(c(
  "Pogona vitticeps", "Python regius", "Chelonia mydas",
  "Naja naja", "Crocodylus niloticus"
), backend = "reptiledb")

reptiles |> add_repttraits()
#>             input_name biogeographic_realm habitat_type elevation_max_m body_mass_g  svl_mm reproductive_mode ...
#> 1     Pogona vitticeps     Australo-Pacific      Desert/...             612       575.4   250         oviparous ...
#> 2        Python regius          Afrotropic         Forest            1200      1610.6  1125         oviparous ...
#> 3       Chelonia mydas              Marine       Wetlands              NA    230000.0  1500         oviparous ...
#> 4            Naja naja            Oriental         Forest            1009      1683.5  1570         oviparous ...
#> 5 Crocodylus niloticus          Afrotropic       Wetlands              NA    750000.0    NA         oviparous ...
```

The distribution and environment columns are the per-species range signal:

- `biogeographic_realm`: the main biogeographic realm (Neotropic, Oriental,
  Australo-Pacific, Afrotropic, Palearctic, Nearctic, Saharo-Sindian,
  Madagascan, or Marine).
- `microhabitat`: microhabitat use (terrestrial, saxicolous, arboreal,
  fossorial, aquatic, and combinations).
- `habitat_type`: broad habitat type(s) (forest, desert, grassland,
  shrubland, savanna, wetlands).
- `elevation_min_m`, `elevation_max_m`: recorded elevation range in metres.

- `mean_annual_temp_c`: mean annual temperature across the range, degrees
  Celsius.
- `insular_endemic`: whether the species is insular/endemic.

This realm-level range is coarse. It is a useful filter for "where does this
species broadly occur", but it is not a fine-grained (TDWG-level) range like
the plant ranges that drive the `region` constraint in `taxify()`.

The morphology and life-history columns follow:

- `body_mass_g`: maximum body mass in grams.

- `svl_mm`: maximum snout-vent length (straight carapace length for
  turtles) in millimetres.
- `total_length_mm`: maximum total length in millimetres.

- `longevity_yr`: maximum recorded longevity in years.

- `diet`: diet category (carnivorous, herbivorous, omnivorous).

- `reproductive_mode`: oviparous, viviparous, or ovoviviparous.

- `clutch_size`: mean clutch or litter size.

- `active_time`: activity period (diurnal, nocturnal, cathemeral).

- `foraging_mode`: foraging strategy (active, ambush, mixed).

Species absent from ReptTraits receive `NA` in all columns. It is licensed
under CC BY 4.0 and published in *Scientific Data*. The reference is Oskyrko,
Mi, Meiri & Du (2024), *Scientific Data* 11:243. The dataset is classified
as static in the taxify manifest.


### Vertebrate enrichments (cross-class)

#### AnAge longevity and life-history (Tacutu et al. 2018)

AnAge is a curated database of aging and longevity records for ~4,700
vertebrate species spanning mammals, birds, reptiles, amphibians, and
fish. It provides maximum longevity, body mass, metabolic rate, maturity
age, gestation/incubation time, litter/clutch size, birth mass, growth
rate, and body temperature. The unique value of AnAge over taxon-specific
databases like PanTHERIA is its cross-class coverage: longevity and
metabolic data can be compared directly across vertebrate classes.

```{r anage}
vertebrates <- taxify(c(
  "Vulpes vulpes", "Aquila chrysaetos", "Crocodylus niloticus",
  "Bufo bufo", "Salmo salar"
), backend = c("col", "gbif"))

vertebrates |> add_anage()
#>              input_name max_longevity_yr anage_body_mass_g metabolic_rate_w ...
#> 1         Vulpes vulpes             15.2            5480.0            10.41 ...
#> 2   Aquila chrysaetos              46.0            4210.0             8.94 ...
#> 3 Crocodylus niloticus             44.0          242500.0               NA ...
#> 4            Bufo bufo             36.0              48.0               NA ...
#> 5         Salmo salar              13.0            3400.0               NA ...
```

All columns use the `anage_` prefix for body mass and litter size to
distinguish them from PanTHERIA equivalents. The `max_longevity_yr` column
is the maximum recorded lifespan in years — the most widely used parameter
for cross-species aging comparisons.

The dataset is compiled from the Human Ageing Genomic Resources (HAGR) and
is freely available under CC BY. The reference is Tacutu et al. (2018),
*Nucleic Acids Research* 46:D1083-D1090.


#### AnimalTraits body mass and metabolic rate (Hebert et al. 2022)

AnimalTraits is a curated database of body mass and metabolic rate
measurements covering ~2,000 species across arthropods (~1,700 species),
vertebrates, molluscs, and annelids. Unlike taxon-specific databases, it
provides a unified framework for cross-taxon allometric comparisons —
particularly valuable for arthropods, which are underrepresented in other
trait databases.

```{r animaltraits}
arthropods <- taxify(c(
  "Drosophila melanogaster", "Apis mellifera",
  "Tenebrio molitor", "Gryllus campestris"
), backend = c("col", "gbif"))

arthropods |> add_animaltraits()
#>                input_name animaltraits_body_mass_kg animaltraits_metabolic_rate_w
#> 1 Drosophila melanogaster              0.000001030                    0.000000218
#> 2         Apis mellifera              0.000100000                    0.000012600
#> 3       Tenebrio molitor              0.000140000                    0.000004850
#> 4    Gryllus campestris              0.000800000                           NA
```

The data is stored as individual-level observations in the source CSV;
taxify's parse function aggregates these to species-level medians. Body
mass is in kilograms and metabolic rate in watts (both in SI units, as
published). The `animaltraits_` prefix avoids collision with body mass
columns from other enrichments.

The dataset is licensed under CC0 (public domain) and published on Zenodo.
The reference is Hebert et al. (2022), *Scientific Data* 9:265.


### Butterfly enrichments

#### LepTraits butterfly traits (Shirey et al. 2022)

LepTraits 1.0 is the most comprehensive open butterfly trait database,
covering ~12,400 species of Papilionoidea globally. It provides wingspan,
voltinism, diapause stage, four habitat affinity dimensions, host plant
data, and adult flight phenology.

```{r leptraits}
butterflies <- taxify(c(
  "Vanessa cardui", "Pieris rapae", "Papilio machaon",
  "Lycaena phlaeas", "Colias crocea"
), backend = c("col", "gbif"))

butterflies |> add_leptraits()
#>        input_name wingspan_mm voltinism diapause_stage canopy_affinity ...
#> 1   Vanessa cardui        62.5       3.0             NA    Open canopy ...
#> 2     Pieris rapae        47.5       4.0           pupa    Open canopy ...
#> 3  Papilio machaon        75.0       2.0           pupa    Open canopy ...
#> 4  Lycaena phlaeas        30.0       3.0          larva    Open canopy ...
#> 5    Colias crocea        48.5       3.0          adult    Open canopy ...
```

The wingspan is computed as the midpoint of the lower and upper bounds
reported in the dataset. Voltinism indicates the number of generations per
year. The four habitat affinities (canopy, edge, moisture, disturbance) are
categorical variables describing the species' preferred environmental
context. The `flight_months` column counts the number of months with
recorded adult flight activity.

The dataset is licensed under CC0 and published on Figshare. The reference
is Shirey et al. (2022), *Scientific Data* 9:398.


### Arthropod enrichments

#### NW European Arthropod life-history traits (Logghe et al. 2025)

This dataset provides 28 life-history and ecological traits for ~4,900
arthropod species from Northwestern Europe, covering 10 orders including
Coleoptera, Hemiptera, Orthoptera, Araneae, Diptera, Hymenoptera, and
Lepidoptera. It is the most comprehensive open arthropod trait compilation
for this region.

```{r arthropod-traits}
insects <- taxify(c(
  "Abax parallelepipedus", "Pterostichus melanarius",
  "Chorthippus parallelus", "Araneus diadematus"
), backend = c("col", "gbif"))

insects |> add_arthropod_traits()
#>               input_name arthropod_body_size_mm arthropod_dispersal arthropod_voltinism arthropod_feeding_guild ...
#> 1 Abax parallelepipedus                   18.5                0.01                 1.0               carnivore ...
#> 2 Pterostichus melanarius                 15.0                0.32                 1.0               carnivore ...
#> 3 Chorthippus parallelus                  17.0                0.10                 1.0               herbivore ...
#> 4   Araneus diadematus                    13.0                0.45                 1.0               carnivore ...
```

All columns are prefixed with `arthropod_`. The quantitative traits
include body size (mm), dispersal ability (0-1 ratio within order),
mean voltinism, fecundity, development time (days), lifespan (days), and
thermal niche mean (°C). The categorical traits include diurnality,
feeding guild, and trophic range.

Because this dataset is geographically scoped to NW Europe (Belgium,
Luxembourg, Netherlands, northern France, UK, western Germany), species
from other regions will have `NA` values. The dataset is particularly
strong for Coleoptera, Hemiptera, and Orthoptera, with near-complete
coverage of the regional fauna in those orders.

The dataset is licensed under CC BY-NC and published in *Biodiversity Data
Journal*. The reference is Logghe et al. (2025), *Biodiversity Data
Journal* 13:e146785.


## Group-based enrichments

Five enrichments filter by a grouping variable (country code, TDWG
botanical region code, GloNAF region code, or language code) and pivot
the result to wide format. The mechanics are the same across all of them:
when a single group
value is requested, the output column uses the base name (e.g.,
`invasive_status`). When multiple group values are requested, each output
column gets a suffix derived from the group value (e.g.,
`invasive_status_AT`, `invasive_status_DE`). Passing `"all"` as the group
value expands to every group present in the enrichment dataset.

This design keeps the output tidy for the common case (one country, one
region, one language) while still supporting comparative analyses across
multiple groups without reshaping the data manually. Internally, the
group-based join performs one `match()` call per group value, so requesting
10 countries costs roughly 10 times the computation of a single country.
This is still fast for typical use cases (sub-second for results with tens
of thousands of rows), but requesting `"all"` on a large result may take a
few seconds because it iterates over all group values in the enrichment
(196 countries for GRIIS, dozens of TDWG regions for WCVP).

### Invasive species status (GRIIS)

The Global Register of Introduced and Invasive Species (GRIIS) classifies
species as native, introduced, or invasive on a per-country basis. The
dataset covers 196 countries with ~23,000 species-country combinations. The
`country` argument takes ISO 3166-1 alpha-2 codes (e.g., `"AT"` for
Austria, `"DE"` for Germany, `"GB"` for Great Britain).

#### Single country

```{r invasive-single}
plants <- taxify(c(
  "Robinia pseudoacacia", "Ailanthus altissima",
  "Impatiens glandulifera", "Quercus robur",
  "Reynoutria japonica", "Solidago canadensis"
))

plants |> add_griis(country = "AT")
#>            input_name invasive_status
#> 1 Robinia pseudoacacia        invasive
#> 2  Ailanthus altissima        invasive
#> 3 Impatiens glandulifera      invasive
#> 4        Quercus robur          native
#> 5  Reynoutria japonica        invasive
#> 6 Solidago canadensis        invasive
```

With a single country code, the output column is simply `invasive_status`
without any suffix. The three possible values are `"native"`, `"introduced"`,
and `"invasive"`. Species not recorded in the GRIIS dataset for the
requested country receive `NA`. Note that `NA` does not mean "native"; it
means "no record" in the GRIIS database. Many native species are simply
not listed because GRIIS focuses on introduced and invasive taxa.

#### Multiple countries

When comparing invasive status across countries, pass a vector of codes.
Each output column is suffixed with the corresponding country code.

```{r invasive-multi}
plants |> add_griis(country = c("AT", "DE", "GB"))
#>            input_name invasive_status_AT invasive_status_DE invasive_status_GB
#> 1 Robinia pseudoacacia         invasive           invasive           invasive
#> 2  Ailanthus altissima         invasive           invasive         introduced
#> 3 Impatiens glandulifera       invasive           invasive           invasive
#> 4        Quercus robur           native             native             native
#> 5  Reynoutria japonica         invasive           invasive           invasive
#> 6 Solidago canadensis         invasive           invasive         introduced
```

This layout makes cross-country comparisons straightforward. Filtering for
species that differ in status between countries is a matter of subsetting
columns. The example below finds species classified as invasive in Austria
but not (yet) classified as invasive in Germany:

```{r invasive-filter}
result <- plants |> add_griis(country = c("AT", "DE"))
# Species invasive in Austria but not in Germany
result[result$invasive_status_AT == "invasive" &
       result$invasive_status_DE != "invasive", ]
```

This pattern is useful for identifying species that may be expanding their
invasive range, or for comparing the regulatory status of non-native
species across neighboring countries.

#### All countries

Passing `country = "all"` expands the result with one column per country
in the GRIIS dataset (196 countries). This produces a wide data.frame with
196 additional columns, so it is best reserved for full-scale screening
exercises where the complete geographic profile of each species matters.

```{r invasive-all}
plants |> add_griis(country = "all")
# Adds invasive_status_AD, invasive_status_AE, ..., invasive_status_ZW
```

The resolution of `"all"` to the full list of country codes is done
efficiently: if the manifest contains an `available_groups` field for the
GRIIS enrichment (which it normally does), the codes are read from there in
O(1) time without scanning the `.vtr` file. This makes even the `"all"`
case fast to set up, though the subsequent join across 196 groups
naturally takes longer than a single-country join.

### Alien species first records (Seebens et al.)

The Global Alien Species First Record Database (Seebens et al. 2017)
records the year each alien species was first documented in a given country
or territory. Unlike GRIIS (which records current status), this enrichment
provides a historical timeline of alien species arrivals. The dataset
covers all taxa (plants, animals, fungi) with ~77,000 species-country
combinations across 241 countries. The `country` argument takes ISO 3166-1
alpha-2 codes, same as `add_griis()`.

#### Single country

```{r alien-fr-single}
aliens <- taxify(c(
  "Robinia pseudoacacia", "Ailanthus altissima",
  "Impatiens glandulifera", "Quercus robur",
  "Ambrosia artemisiifolia", "Solidago canadensis"
))

aliens |> add_alien_first_records(country = "AT")
#>              input_name alien_first_record alien_first_record_source alien_first_record_reference
#> 1   Robinia pseudoacacia               1850                   NOBANIS                      NOBANIS
#> 2    Ailanthus altissima               1870                   NOBANIS                      NOBANIS
#> 3 Impatiens glandulifera               1900                   NOBANIS                      NOBANIS
#> 4          Quercus robur                 NA                      <NA>                         <NA>
#> 5 Ambrosia artemisiifolia              1863                   NOBANIS                      NOBANIS
#> 6  Solidago canadensis                 1850                   NOBANIS                      NOBANIS
```

Each row gets three columns: `alien_first_record` (the year as an integer),
`alien_first_record_source` (the database that contributed this record,
e.g., "NOBANIS", "GAVIA", "FishBase"), and `alien_first_record_reference`
(the original citation). Native species like *Quercus robur* receive `NA`
because they are not in the alien first records database.

The source and reference columns provide row-level provenance. This
matters because a second first-records source (GBIF occurrence-based
records) will be added in a future version, and the `source` column will
distinguish which database contributed each record.

#### Multiple countries

```{r alien-fr-multi}
aliens |> add_alien_first_records(country = c("AT", "DE", "GB"))
#>              input_name alien_first_record_AT alien_first_record_DE alien_first_record_GB ...
#> 1   Robinia pseudoacacia                  1850                  1630                  1640 ...
#> 2    Ailanthus altissima                  1870                  1780                  1751 ...
#> 3 Impatiens glandulifera                  1900                  1839                  1855 ...
```

With multiple countries, each of the three value columns gets a country
suffix: `alien_first_record_AT`, `alien_first_record_source_AT`,
`alien_first_record_reference_AT`, etc. This makes cross-country
comparisons of invasion history straightforward.

#### Reshaping to long format

When working with multiple countries, the wide format can be unwieldy for
modelling, mapping, or timeline analyses. The `taxify_long()` helper
reshapes any group-based enrichment columns back to long format:

```{r alien-fr-long}
aliens |>
  add_alien_first_records(country = c("AT", "DE", "GB")) |>
  taxify_long()
#>              input_name country_code alien_first_record alien_first_record_source ...
#> 1   Robinia pseudoacacia           AT               1850                   NOBANIS ...
#> 2    Ailanthus altissima           AT               1870                   NOBANIS ...
#> ...
#> 7   Robinia pseudoacacia           DE               1630              Long (2003) ...
#> ...
```

When `cols` and `group_col` are omitted, `taxify_long()` auto-detects them
from metadata stamped by the `add_*()` functions. The result has one row
per species per country, with the base column names (no suffix) and a new
`country_code` column. The `drop_na = TRUE` argument removes rows where
all value columns are `NA` (e.g., native species with no alien first record
in any queried country).

`taxify_long()` works with any group-based enrichment, not just alien first
records. It can reshape `invasive_status`, `native_status`, or
`common_name` columns just as easily:

```{r taxify-long-griis}
aliens |>
  add_griis(country = c("AT", "DE")) |>
  taxify_long()
```

When multiple grouped enrichments share the same group column, they are
reshaped together. If an enrichment covers different groups than another
(e.g., GRIIS for AT/DE but first records for AT/DE/CH), the missing
combinations are padded with `NA`:

```{r taxify-long-combined}
aliens |>
  add_griis(country = c("AT", "DE")) |>
  add_alien_first_records(country = c("AT", "DE", "CH")) |>
  taxify_long()
```

You can still provide `cols` and `group_col` explicitly to override
auto-detection or to rename the group column.

### Native range by botanical region (WCVP)

The World Checklist of Vascular Plants (WCVP) from the Royal Botanic
Gardens, Kew, classifies ~340,000 plant species as native, introduced, or
extinct in TDWG Level 2 botanical regions. TDWG (Taxonomic Databases
Working Group, now TDWG Biodiversity Information Standards) defined a
hierarchical system of geographic regions for recording plant
distributions. Level 2 regions are continent-scale units.

The `region` argument takes TDWG Level 2 codes. Common codes include:

- `EUR` (Europe)

- `NAM` (Northern America)

- `SAM` (Southern America)

- `AFR` (Africa)

- `AUS` (Australasia)

- `ASI` (Asia-Temperate)

- `AST` (Asia-Tropical)

- `PAC` (Pacific)

- `ANT` (Antarctica)

```{r wcvp-single}
trees <- taxify(c(
  "Quercus robur", "Quercus suber", "Eucalyptus globulus",
  "Nothofagus pumilio", "Sequoiadendron giganteum"
))

trees |> add_wcvp(region = "EUR")
#>              input_name native_status
#> 1          Quercus robur        native
#> 2          Quercus suber        native
#> 3    Eucalyptus globulus            NA
#> 4    Nothofagus pumilio            NA
#> 5 Sequoiadendron giganteum          NA
```

*Eucalyptus globulus* returns `NA` for Europe because it is native to
Australia, not because it is absent from the WCVP dataset. The dataset
records where a species is natively distributed, not where it has been
planted or naturalized. This is an important distinction: many cultivated
species will show `NA` in regions where they are widespread in gardens and
plantations.

Querying multiple regions reveals each species' native continental range:

```{r wcvp-multi}
trees |> add_wcvp(region = c("EUR", "AUS", "SAM"))
#>              input_name native_status_EUR native_status_AUS native_status_SAM
#> 1          Quercus robur           native                NA                NA
#> 2          Quercus suber           native                NA                NA
#> 3    Eucalyptus globulus               NA            native                NA
#> 4    Nothofagus pumilio               NA                NA            native
#> 5 Sequoiadendron giganteum              NA                NA                NA
```

*Sequoiadendron giganteum* (Giant Sequoia) returns `NA` for all three
regions because it is native to western North America (`NAM`), which was
not included in the query. This illustrates that the absence of a region
code from the query does not mean the species lacks native range data; it
means we did not ask about the right region.

The full list of available TDWG codes can be retrieved programmatically
from the manifest (the `available_groups` field for the `wcvp` enrichment),
or from the TDWG geographic standard documentation. WCVP is non-static:
Kew updates the checklist periodically, and the taxify enrichment is
rebuilt when new versions are published.

### Naturalized alien flora by region (GloNAF)

The Global Naturalized Alien Flora (GloNAF) records which plant species
are naturalized in ~1,300 regions worldwide. Unlike GRIIS (which classifies
species as native/introduced/invasive per country), GloNAF provides a
binary naturalization flag per region with finer geographic resolution,
using TDWG-compatible codes extended with dot notation for sub-national
units (e.g., `"USA.CA"` for California).

```{r glonaf}
plants <- taxify(c(
  "Robinia pseudoacacia", "Ailanthus altissima",
  "Impatiens glandulifera", "Quercus robur"
))

plants |> add_glonaf(region = "EUR")
#>              input_name naturalized
#> 1   Robinia pseudoacacia           1
#> 2    Ailanthus altissima           1
#> 3 Impatiens glandulifera           1
#> 4          Quercus robur          NA
```

The output column `naturalized` is `1` if the species is recorded as
naturalized in the queried region, and `NA` otherwise. Multiple regions
produce suffixed columns (`naturalized_EUR`, `naturalized_NAM`). The
`region = "all"` option expands to all ~1,300 regions.

GloNAF complements GRIIS: GRIIS provides the invasion status dimension
(native/introduced/invasive), while GloNAF provides the geographic
coverage dimension (where has this species established self-sustaining
populations?). Combining both gives a fuller picture of alien plant
distributions.

The dataset is licensed under CC BY 4.0. The reference is van Kleunen et
al. (2019), *Ecology* 100:e02542 (v1.0) and Davis et al. (2025), *Ecology*
e70245 (v2.0). GloNAF is classified as static in the taxify manifest.


### Common (vernacular) names (GBIF)

The common names enrichment draws on GBIF's vernacular name database, which
aggregates names from many national and regional nomenclature sources. It
is the most multilingual of the enrichments, covering dozens of languages.
The `lang` argument takes ISO 639-1 two-letter language codes.

```{r common-names-en}
species <- taxify(c(
  "Quercus robur", "Parus major", "Vulpes vulpes",
  "Bufo bufo", "Picea abies"
))

species |> add_common_names()
#>     input_name common_name
#> 1 Quercus robur   Pedunculate Oak
#> 2   Parus major    Great Tit
#> 3  Vulpes vulpes    Red Fox
#> 4     Bufo bufo    Common Toad
#> 5   Picea abies    Norway Spruce
```

The default language is English (`lang = "en"`). Switching to another
language is a matter of changing the `lang` argument:

```{r common-names-de}
species |> add_common_names(lang = "de")
#>     input_name common_name
#> 1 Quercus robur   Stieleiche
#> 2   Parus major    Kohlmeise
#> 3  Vulpes vulpes    Rotfuchs
#> 4     Bufo bufo    Erdkroete
#> 5   Picea abies    Gemeine Fichte
```

When multiple common names exist for a species in the requested language,
the first (most commonly used) entry is returned. Coverage varies
substantially by language: English and German have the broadest coverage
(most European and widespread species have entries). French, Spanish,
Portuguese, and Dutch also have good coverage. Less widely spoken languages
or languages with limited digital biodiversity infrastructure may have
gaps, resulting in `NA` for species that do have common names in those
languages but that have not been digitized in GBIF's aggregation.

The common names enrichment is non-static (GBIF updates its backbone
periodically) and licensed under CC0. When a single language is requested,
the output column is `common_name`. If multiple languages were supported in
a single call, they would follow the group-based suffix pattern, but in
practice the common usage pattern is one language per call.


## Stacking enrichments

The `add_*()` functions return the same data.frame class (`taxify_result`)
they receive, preserving all attributes including the metadata used by
`summary()`. This means they compose naturally with the pipe operator. A
typical workflow chains `taxify()` with several enrichment calls, building
up the desired set of columns incrementally.

```{r stacking-plants}
library(taxify)

plant_result <- taxify(c(
  "Quercus robur", "Fagus sylvatica", "Picea abies",
  "Arrhenatherum elatius", "Festuca rubra", "Plantago lanceolata"
)) |>
  add_iucn() |>
  add_zanne() |>
  add_eive() |>
  add_diaz_traits()
```

Each enrichment appends its columns to the right of the data.frame. The
result of this chain has the original 16 taxify columns plus
`conservation_status`, `woodiness`, the five EIVE columns (`eive_light`,
`eive_temperature`, `eive_moisture`, `eive_reaction`, `eive_nutrients`),
and the two Diaz columns (`seed_mass_mg`, `plant_height_m`). That is 25
columns total. Order within the chain does not affect the output because
each enrichment operates independently on the `accepted_name` column. The
only case where order matters is the column-name collision between LEDA and
Diaz (`seed_mass_mg`), discussed earlier.

Here is a similar chain for birds, combining morphological measurements
with diet data and vernacular names:

```{r stacking-birds}
bird_result <- taxify(c(
  "Parus major", "Cyanistes caeruleus", "Erithacus rubecula",
  "Turdus merula", "Falco peregrinus"
)) |>
  add_iucn() |>
  add_avonet() |>
  add_elton_traits() |>
  add_common_names()
```

This produces 16 (base) + 1 (conservation) + 11 (AVONET) + 18
(EltonTraits) + 1 (common name) = 47 columns. Both AVONET and EltonTraits
contribute body mass, but in distinct columns (`avonet_body_mass_g` and
`elton_body_mass_g`), so there is no overwriting.

And for mammals, combining life-history traits from PanTHERIA with diet
data from EltonTraits and German common names:

```{r stacking-mammals}
mammal_result <- taxify(c(
  "Vulpes vulpes", "Canis lupus", "Ursus arctos",
  "Lutra lutra", "Lynx lynx"
)) |>
  add_iucn() |>
  add_pantheria() |>
  add_elton_traits() |>
  add_common_names(lang = "de")
```

Both EltonTraits and PanTHERIA cover mammals, so both contribute data to
the mammal chain. EltonTraits provides diet composition percentages and
foraging strata; PanTHERIA provides life-history traits like longevity,
litter size, and home range. The combination gives a multidimensional view
of each species' ecology without any manual data assembly.

The same pattern works for fungi, combining lifestyle traits from
FungalTraits with guild classifications from FUNGuild:

```{r stacking-fungi}
fungal_result <- taxify(c(
  "Amanita muscaria", "Boletus edulis", "Trametes versicolor"
)) |>
  add_iucn() |>
  add_fungal_traits() |>
  add_funguild()
```

FungalTraits provides the detailed ecological traits (lifestyle, growth
form, substrate, mycorrhizal exploration type), while FUNGuild adds the
trophic mode and guild classification. The two enrichments have
complementary column sets, so there is no overwriting except for growth
form, which is distinguished by the `funguild_growth_form` prefix in
FUNGuild. The `confidence_ranking` column from FUNGuild is a useful
quality filter: restricting to "Highly Probable" assignments before
downstream analysis reduces noise.

Fish analyses can similarly combine morphological and ecological
enrichments:

```{r stacking-fish}
fish_result <- taxify(c(
  "Salmo trutta", "Esox lucius", "Gadus morhua"
)) |>
  add_iucn() |>
  add_fishmorph() |>
  add_fishbase()
```

FISHMORPH provides the morphological ratios (body elongation, fin shape,
eye size) that define the ecomorphological profile of each species, while
FishBase adds the ecological and life-history context (trophic level,
depth range, vulnerability). Note that *Gadus morhua* (Atlantic Cod) will
have `NA` values in all FISHMORPH columns because FISHMORPH covers
freshwater species only, but it will be fully populated by FishBase. This
kind of partial coverage across complementary enrichments is expected and
easy to diagnose from the `summary()` output.

Enrichment chains can be as long as needed. Performance is linear in the
number of enrichments: each `add_*()` call performs one join, regardless of
how many enrichments have already been applied. A chain of 10 enrichments
on a 50,000-row result completes in seconds. The enrichment files themselves
are loaded via vectra's memory-mapped I/O, so even enrichments with hundreds
of thousands of rows (like WCVP at ~340,000) do not consume large amounts of
RAM.

The pipe chain pattern also plays well with reproducibility workflows. The
entire analysis, from raw species list to fully enriched table, is captured
in a single, readable expression. Saving this code alongside the session
info (including taxify version and enrichment versions from `summary()`)
gives a complete record of which data was used to produce the results.


## Coverage patterns

Not all species appear in all enrichments. Each dataset has a taxonomic
scope (plants, birds, mammals, amphibians, vertebrates, butterflies,
arthropods, fungi, algae, fish, reptiles, or cross-taxon) and a geographic
scope (global, European, NW European). When
an enrichment has no
data for a species, the corresponding columns contain `NA`. Understanding
coverage patterns is essential for interpreting enriched results correctly
and for choosing which enrichments to apply.

```{r coverage-example}
mixed <- taxify(c(
  "Quercus robur",     # plant
  "Parus major",       # bird
  "Vulpes vulpes",     # mammal
  "Bufo bufo",         # amphibian
  "Amanita muscaria",  # fungus
  "Salmo trutta"       # fish
))

mixed |>
  add_zanne() |>
  add_avonet() |>
  add_pantheria() |>
  add_amphibio() |>
  add_fungal_traits() |>
  add_fishbase()
#>        input_name woodiness beak_length pantheria_body_mass_g body_size_mm primary_lifestyle fb_trophic_level ...
#> 1   Quercus robur     woody          NA                    NA           NA              <NA>               NA ...
#> 2     Parus major        NA        11.2                    NA           NA              <NA>               NA ...
#> 3   Vulpes vulpes        NA          NA                5480.0           NA              <NA>               NA ...
#> 4       Bufo bufo        NA          NA                    NA        150.0              <NA>               NA ...
#> 5 Amanita muscaria       NA          NA                    NA           NA   ectomycorrhizal               NA ...
#> 6    Salmo trutta        NA          NA                    NA           NA              <NA>              3.4 ...
```

Each species populates only the columns from enrichments that cover its
taxon group. The `NA` values are not errors or data quality problems; they
reflect the scope of the underlying datasets. *Quercus robur* has a
woodiness value but no beak length, body mass, body size, fungal traits, or
fish data. *Amanita muscaria* has a primary lifestyle but no plant, bird,
mammal, amphibian, or fish traits. *Salmo trutta* has FishBase data but
nothing from the other taxon-specific enrichments. This is expected
behavior.

### Approximate coverage rates by enrichment

The following table summarizes the approximate species coverage of each
enrichment, its taxonomic scope, and its geographic scope. Numbers are
approximate because enrichments are updated periodically and because
coverage depends somewhat on the backbone used (different backbones accept
slightly different sets of names).

| Enrichment | Taxon scope | Geographic scope | ~Species |
|---|---|---|---|
| conservation_status | all groups | global | 166,000 |
| woodiness | plants | global | 50,000 |
| eive | plants | European | 14,500 |
| diaz_traits | plants | global | 46,000 |
| leda | plants | NW European | 8,000 |
| elton_traits | birds + mammals | global | 15,400 |
| avonet | birds | global | 11,000 |
| pantheria | mammals | global | 5,400 |
| amphibio | amphibians | global | 6,800 |
| fungal_traits | fungi | global | 10,200 genera |
| funguild | fungi | global | 13,000 |
| algae_traits | macroalgae | European | 1,745 |
| fish_traits | freshwater fish | global | 8,300 |
| fishbase | all fish | global | 35,000 |
| repttraits | reptiles | global | 12,060 |
| anage | vertebrates | global | 4,700 |
| animaltraits | cross-taxon (arthropods+) | global | 2,000 |
| leptraits | butterflies | global | 12,400 |
| arthropod_traits | arthropods | NW European | 4,900 |
| griis | all groups | per country | 23,000 combos |
| glonaf | plants | global by region | 16,000 × 1,300 |
| wcvp | plants | global by region | 340,000 |
| common_names | all groups | multi-language | varies |

For a European plant survey, the enrichment with the highest absolute
coverage is WCVP (~340,000 species), followed by conservation status
(~166,000), woodiness (~50,000), Diaz traits (~46,000), EIVE (~14,500), and
LEDA (~8,000). However, for a specifically NW European dataset, LEDA's
~8,000 species may actually cover a larger fraction of the species list
than the Diaz dataset, because LEDA is geographically focused on the same
region.

### Interpreting NA columns

When an entire column is `NA` for all rows in a result, the most likely
explanation is a taxon-scope mismatch. Woodiness covers vascular plants, so
a bird dataset will have `NA` in every row of that column. The reverse holds
for AVONET against a plant list, or PanTHERIA against amphibians. This is
expected behavior: the enrichment data simply does not include species from
that taxon group.

A partially populated column (some rows `NA`, others filled) means the
enrichment covers the taxon group but the specific species is not in the
source dataset. Common reasons for per-species `NA` include:

1. **Source dataset incomplete.** No trait database covers 100% of
   described species. PanTHERIA covers ~5,400 of the ~6,500 described
   mammal species; roughly 1,100 mammals will have `NA` values.
2. **Recently described species.** Species described or split after the
   dataset's publication date will be absent. PanTHERIA (2009) misses
   all species described since 2009.
3. **Name alignment failure.** Rare, but possible for taxa with ongoing
   taxonomic revisions where the backbone and the enrichment source use
   different name variants that the cross-backbone resolution did not
   capture. If a species consistently fails to match, filing a GitHub
   issue helps us improve the name alignment pipeline.
4. **Infraspecific taxa.** Most enrichments operate at the species level.
   If the taxify result contains subspecies or varieties (e.g.,
   "Quercus robur subsp. robur"), the enrichment may not have a
   matching entry at that rank.

It is worth noting that coverage is not the same as data quality. An
enrichment might cover 95% of the species in a result, but the trait values
for some of those species could be based on few measurements, extrapolated
from congeners, or derived from captive rather than wild populations. The
enrichment system does not expose confidence intervals or sample sizes for
individual trait values; that level of detail lives in the original source
databases. For analyses that require measurement-level metadata (sample
size, measurement uncertainty, geographic origin of measurements), consult
the original source cited on the `add_*()` help page.

To check the overall enrichment rate for a result, the `summary()` output
reports the number of matched rows per enrichment. We can also compute it
directly:

```{r coverage-check}
result <- taxify(species_list) |> add_zanne()
# Fraction of matched species with woodiness data
mean(!is.na(result$woodiness[!is.na(result$accepted_name)]))
```


## The enrichment register in `summary()` output

Every `add_*()` call records metadata about the enrichment in an attribute
(`taxify_meta`) on the result data.frame. This metadata includes the
enrichment name, source label, version string, and the count of rows that
received non-`NA` trait values. Calling `summary()` on a taxify result
displays this information alongside the standard match statistics, providing
a compact overview of the entire analysis pipeline.

```{r summary-enrichments}
result <- taxify(c("Quercus robur", "Fagus sylvatica", "Pinus sylvestris")) |>
  add_iucn() |>
  add_zanne() |>
  add_eive()

summary(result)
#> -- taxify results --------------------------------------------------------
#>   backend: WFO v2024.12  |  3 names submitted
#>
#>   matched       3  (exact: 3, case-insensitive: 0, fuzzy: 0)
#>   --------------------------------------------------------
#>   taxon groups: plant: 3
#>
#>   enrichments:
#>     conservation_status  (IUCN Red List 2025.1)     -- 3 of 3 matched
#>     woodiness            (Zanne et al. 2014 1.0)    -- 3 of 3 matched
#>     eive                 (EIVE 1.0 2023.1)          -- 3 of 3 matched
```

The enrichment register lists each applied enrichment with its source name,
version, and the fraction of successfully matched names. In this example,
all three enrichments achieved 100% coverage (3 of 3 matched), which is
expected for well-known European tree species. On a larger dataset with a
broader taxonomic scope, we would typically see lower fractions, especially
for enrichments with narrow geographic or taxonomic coverage.

The register is cumulative: applying more enrichments adds more lines. This
makes `summary()` a useful diagnostic at the end of a pipe chain. If one
enrichment shows unexpectedly low coverage (e.g., "2 of 500 matched" for
EIVE on a dataset that we expected to be European plants), it signals a
problem worth investigating. Common causes include the species list
containing non-plant taxa, non-European species, or names at ranks other
than species.

The version strings in the register provide exact provenance information
for the methods section of a paper. Rather than writing "we used the IUCN
Red List" (which version? downloaded when?), we can report the version
string directly from `summary()` (e.g., "IUCN Red List v2025.1 as
distributed by taxify enrichment conservation_status v2025.04").


## Practical guidance: which enrichments for which taxa

The choice of enrichments depends on the taxonomic scope and geographic
focus of the analysis. Below are recommended enrichment stacks for common
use cases, with brief notes on what each enrichment contributes.

### Vascular plants (European)

European plant ecology benefits from the richest set of enrichments. A
full stack combines conservation status, growth form, ecological niche
position, global functional traits, regional functional traits, native
range, and vernacular names.

```{r guide-euro-plants}
result <- taxify(species_list, backend = "wfo") |>
  add_iucn() |>
  add_zanne() |>
  add_fungalroot() |>
  add_eive() |>
  add_diaz_traits() |>
  add_leda() |>
  add_wcvp(region = "EUR") |>
  add_common_names()
```

EIVE and LEDA both cover European plants, but their trait columns are
complementary. EIVE provides niche position along five environmental
gradients (where does this species grow?). LEDA provides morphological and
dispersal traits (what does this species look like, how does it
disperse?). The combination produces a detailed functional profile suitable
for community-weighted mean analyses, trait-based ordinations, and
functional diversity calculations. The Diaz traits add a global perspective
on seed mass and plant height that complements LEDA's regional
measurements.

The `seed_mass_mg` collision between LEDA and Diaz was discussed earlier.
In this stack, LEDA runs before Diaz, so the Diaz `seed_mass_mg` will be
the value in the final result. If the LEDA value is preferred, reverse the
order or omit `add_diaz_traits()`.

### Vascular plants (global)

Outside Europe, EIVE and LEDA coverage drops to near zero. The global plant
stack relies on the wider-coverage datasets and omits the regional
enrichments.

```{r guide-global-plants}
result <- taxify(species_list, backend = "wfo") |>
  add_iucn() |>
  add_zanne() |>
  add_fungalroot() |>
  add_diaz_traits() |>
  add_wcvp(region = c("NAM", "SAM", "AFR")) |>
  add_common_names()
```

Woodiness, Diaz traits, and FungalRoot mycorrhizal type all have global
coverage, so they contribute useful data regardless of the geographic origin
of the species list. WCVP can be queried for any TDWG region, providing native
range information for the continents relevant to the study.

### Birds

Birds are covered by two complementary enrichments: AVONET for morphology
and migration, EltonTraits for diet and foraging. Together they provide a
detailed functional profile spanning body plan, habitat use, dietary niche,
and movement ecology.

```{r guide-birds}
result <- taxify(species_list, backend = "col") |>
  add_iucn() |>
  add_avonet() |>
  add_elton_traits() |>
  add_common_names()
```

Both AVONET and EltonTraits include body mass, stored in separate columns
(`avonet_body_mass_g` from specimen measurements and `elton_body_mass_g`
from literature compilation). Small discrepancies between the two are
expected and can be informative: large discrepancies for a species may
indicate measurement error in one source or sexually dimorphic species
where the two sources sampled different sexes.

### Mammals

Mammals are covered by PanTHERIA (life-history traits) and EltonTraits
(diet and foraging behavior). The combination provides body mass from two
independent sources (`pantheria_body_mass_g` and `elton_body_mass_g`),
which can serve as a cross-validation of the mass data.

```{r guide-mammals}
result <- taxify(species_list, backend = "col") |>
  add_iucn() |>
  add_pantheria() |>
  add_elton_traits() |>
  add_common_names()
```

PanTHERIA contributes life-history variables that EltonTraits does not
cover (longevity, litter size, gestation, weaning age, home range, diet
breadth, habitat breadth). EltonTraits contributes the detailed diet
composition percentages and foraging stratum data that PanTHERIA does not
provide. There is no redundancy except body mass.

### Amphibians

AmphiBIO is the sole dedicated amphibian enrichment. It can be combined
with conservation status and common names.

```{r guide-amphibians}
result <- taxify(species_list, backend = "col") |>
  add_iucn() |>
  add_amphibio() |>
  add_common_names()
```

Amphibians are the most threatened vertebrate class, with roughly 40% of
assessed species listed in threatened categories (VU, EN, or CR) according
to the IUCN. Conservation status is therefore particularly informative for
amphibian analyses. The combination of AmphiBIO habitat traits (aquatic,
fossorial, arboreal) with IUCN status can reveal associations between
habitat specialization and extinction risk.

### Fish

Fish are covered by two complementary enrichments: FISHMORPH for
morphological traits of freshwater species, and FishBase for ecological
and life-history traits across all fish (freshwater + marine). The WoRMS
backend provides authoritative taxonomy for marine fish; COL and GBIF
cover both freshwater and marine species.

```{r guide-fish}
result <- taxify(species_list, backend = "worms") |>
  add_iucn() |>
  add_fishmorph() |>
  add_fishbase() |>
  add_common_names()
```

For freshwater fish community studies, both enrichments contribute data.
FISHMORPH provides the ecomorphological ratios used in functional diversity
calculations, while FishBase adds trophic level, depth range, and
vulnerability. For marine fish studies, only FishBase will contribute data
(FISHMORPH covers freshwater species only). The `fb_vulnerability` column
from FishBase is particularly useful alongside IUCN conservation status for
prioritizing species in fisheries management and marine spatial planning.

### Reptiles

Reptiles are covered by the `reptiledb` backbone (the Reptile Database) and
the ReptTraits enrichment, which provides life-history, morphological, and
distribution traits for 12,060 species across all reptile groups. Combined
with conservation status, it gives a functional profile suitable for reptile
community analyses and conservation assessments.

```{r guide-reptiles}
result <- taxify(species_list, backend = "reptiledb") |>
  add_iucn() |>
  add_repttraits() |>
  add_common_names()
```

For cross-class longevity and metabolic comparisons, `add_anage()` covers
reptiles alongside mammals, birds, amphibians, and fish.

### Butterflies

LepTraits is the dedicated butterfly enrichment, providing wingspan,
voltinism, habitat affinities, and host plant data for ~12,400 species
globally. For European butterfly ecology, it can be combined with the
NW European Arthropod traits for additional life-history variables.

```{r guide-butterflies}
result <- taxify(species_list, backend = "col") |>
  add_iucn() |>
  add_leptraits() |>
  add_common_names()
```

### Arthropods (NW European)

For arthropod community studies in NW Europe, the arthropod traits
enrichment provides the most comprehensive trait coverage. It can be
combined with AnimalTraits for cross-taxon body mass comparisons and with
LepTraits for additional butterfly-specific traits.

```{r guide-arthropods}
result <- taxify(species_list, backend = c("col", "gbif")) |>
  add_iucn() |>
  add_arthropod_traits() |>
  add_animaltraits() |>
  add_common_names()
```

For arthropod studies outside NW Europe, AnimalTraits provides body mass
for ~1,700 arthropod species globally, though with fewer trait dimensions
than the Logghe et al. dataset.

### Fungi

Fungi are covered by two enrichments: FungalTraits for genus-level
ecological traits and FUNGuild for trophic guild classifications. The COL
and GBIF backends provide fungal taxonomy.

```{r guide-fungi}
result <- taxify(species_list, backend = "col") |>
  add_iucn() |>
  add_fungal_traits() |>
  add_funguild() |>
  add_common_names()
```

FungalTraits provides the lifestyle, growth form, and interaction
capability traits that describe what each genus does ecologically.
FUNGuild adds the trophic mode and guild classification used in fungal
community ecology. The `confidence_ranking` column from FUNGuild allows
filtering to high-confidence assignments, which is important for
quantitative analyses where guild misclassification would introduce
systematic bias.

### Macroalgae (European)

European macroalgae are covered by AlgaeTraits, which provides
morphological and ecological traits for ~1,745 species. The WoRMS backend
is recommended for marine algae taxonomy.

```{r guide-algae}
result <- taxify(species_list, backend = "worms") |>
  add_iucn() |>
  add_algae_traits() |>
  add_common_names()
```

AlgaeTraits is geographically scoped to European coastlines. For
non-European macroalgae studies, the `add_data()` function can join
custom datasets. The key advantage of AlgaeTraits over general plant
trait databases is that it provides marine-specific traits (tidal zone,
wave exposure, calcification) that are not captured by terrestrial plant
databases like LEDA or EIVE.

### Mixed-taxon datasets

When a dataset spans multiple kingdoms (e.g., a biodiversity survey with
plants, birds, and mammals), there are two strategies.

The first is to apply all relevant enrichments to the full result and
accept `NA` values where taxonomic scope does not overlap:

```{r guide-mixed-all}
result <- taxify(species_list) |>
  add_iucn() |>
  add_zanne() |>
  add_avonet() |>
  add_pantheria() |>
  add_amphibio() |>
  add_elton_traits()
```

This produces a wide data.frame where most cells in any given row are `NA`
(a plant row has woodiness data but `NA` for beak length, body mass, etc.).
The advantage is simplicity: one data.frame, one `summary()` call, no
manual splitting.

The second strategy is to split the result by taxon group, enrich each
subset with the appropriate stack, and recombine:

```{r guide-mixed-split}
result <- taxify(species_list)

plants  <- result[result$kingdom == "Plantae", ]
birds   <- result[result$family %in% bird_families, ]
mammals <- result[result$family %in% mammal_families, ]

plants  <- plants |> add_zanne() |> add_eive()
birds   <- birds |> add_avonet() |> add_elton_traits()
mammals <- mammals |> add_pantheria() |> add_elton_traits()
```

The second approach avoids wide data.frames with many `NA` columns and
produces cleaner trait matrices for downstream analyses that treat columns
as features (ordination, clustering, machine learning). The disadvantage is
more code and the need to maintain separate data.frames for each group.

The choice depends on the analysis goal. For a summary table in a paper
(e.g., "species, conservation status, key traits"), the first approach
works well. For functional diversity calculations or trait-based models
that expect a complete trait matrix, the second approach typically produces
better inputs because it avoids rows with structurally missing values
(values that are missing by design, not by data limitation).

A middle ground is to apply `add_iucn()` and
`add_common_names()` to the full dataset (since both cover all taxon
groups), then split by group for the taxon-specific enrichments. This
gives us conservation data and vernacular names for every species in a
single data.frame, while keeping the taxon-specific trait matrices clean.


## Joining custom data

Beyond the built-in enrichments, `add_data()` joins any external
dataset to a taxify result. It accepts a file path (CSV, CSV.GZ, XLSX,
SQLite/DB, or VTR) or an in-memory data.frame. The function identifies the
species name column (automatically by running the first 10 rows of each
character column through `taxify()` and selecting the column with the
highest match rate, or via an explicit `species_col` argument), resolves
those names through the same backbone(s) used in the original `taxify()`
call, and joins on `accepted_id`.

```{r add-data-csv}
result <- taxify(c("Quercus robur", "Pinus sylvestris", "Fagus sylvatica"))

# From a CSV file (auto-detect species column)
result |> add_data("my_traits.csv")
```

```{r add-data-df}
# From a data.frame with explicit species column
my_traits <- data.frame(
  species = c("Quercus robur", "Pinus sylvestris", "Fagus sylvatica"),
  bark_thickness_mm = c(25, 15, 8),
  shade_tolerance = c(0.6, 0.3, 0.8)
)
result |> add_data(my_traits, species_col = "species")
```

Because `add_data()` resolves names through the backbone before joining, it
handles synonyms correctly. If the external data uses "Pinus abies" and the
backbone resolves it to "Picea abies", the join still works. This is the
recommended way to integrate local field data, unpublished trait
measurements, or datasets from sources not covered by the built-in
enrichments.

The `cols` argument can restrict which columns are joined from the external
data. If the external data has 50 columns but we only need two, passing
`cols = c("bark_thickness_mm", "shade_tolerance")` avoids cluttering the
result with unwanted columns. The `fuzzy` argument (default `TRUE`) enables
fuzzy matching for names in the external data that do not exact-match the
backbone; `fuzzy_threshold` controls the maximum allowed string distance.

Column names from the external data that collide with existing columns in
the taxify result are automatically prefixed with `"data_"` to prevent
overwriting. If multiple rows in the external data resolve to the same
`accepted_id` with identical trait values, they are deduplicated.
If they resolve to the same `accepted_id` with conflicting values (e.g.,
two different height measurements for the same species), `add_data()` raises
an error asking the user to resolve the ambiguity before joining. This
strict handling of duplicates prevents the row duplication that a plain
`merge()` would produce.

The `add_data()` function also supports SQLite databases via the `table`
argument, and `.vtr` files directly (useful for sharing pre-built
enrichments between collaborators). For XLSX files, the openxlsx2 package
is required (listed in Suggests).


## Data provenance and citation

Each enrichment draws on published, peer-reviewed datasets with their own
licenses and citation requirements. Citing the correct source and version
is a professional obligation when using these data in publications. The
`summary()` output includes the source and version for each applied
enrichment, providing a starting point for the methods section. The original
references are listed in each `add_*()` function's help page (accessible
via `?add_avonet`, `?add_leda`, `?add_pantheria`, etc.).

For reproducibility, the version recorded in `meta.json` pins the exact
build of each enrichment `.vtr` file that was used. Static enrichments
(Zanne 2014, PanTHERIA 2009, EltonTraits 2014, AmphiBIO 2017, LEDA 2008,
Diaz 2022, Seebens 2017, FungalTraits 2020, FUNGuild 2016, AlgaeTraits
2023, FISHMORPH 2021, Meiri 2018, LepTraits 2022, AnimalTraits 2022,
NW European Arthropods 2025, GloNAF 2019) have fixed versions that never
change. Non-static enrichments
(IUCN, GRIIS, WCVP, common names) are updated when the upstream source
publishes a new release, and the version in `meta.json` reflects which
release was used. Reporting the enrichment version in a publication ensures
that results can be reproduced even if the upstream data is later revised
or corrected.

The licenses of the source datasets range from CC0 (EltonTraits, PanTHERIA,
woodiness, common names, LepTraits, AnimalTraits) to CC BY 4.0 (EIVE,
AmphiBIO, AVONET, GRIIS, GloNAF, FungalTraits, AlgaeTraits, FISHMORPH,
ReptTraits), CC BY (AnAge), CC BY-NC (NW European Arthropods),
CC BY 3.0 (Diaz traits), and CC BY-NC 3.0 (FishBase). LEDA and WCVP have
their own terms published on their respective websites. The taxify package itself does not redistribute
these datasets in their original form; the `.vtr` files are built from
publicly available sources and distributed via GitHub Releases. When using
enrichment data in a publication, cite the original source (the reference
on the `?add_*` help page) and optionally note the taxify enrichment
version for reproducibility.

A minimal methods paragraph citing enrichments might read:

> Taxonomic names were resolved against the WFO backbone (v2024.12) using
> taxify (v0.x.x). Conservation status was obtained from the IUCN Red List
> (v2025.1) via `add_iucn()`. Woodiness classification
> followed Zanne et al. (2014). Ecological indicator values were sourced
> from EIVE 1.0 (Dengler et al. 2023). All enrichment versions are
> recorded in the taxify result metadata and available via `summary()`.


## Summary

taxify's enrichment system turns taxonomic name matching into a gateway to
ecological trait data. The 22 built-in enrichments cover conservation status,
growth form, ecological niches, functional traits, diet, morphology,
life-history, geographic ranges, invasive status, and vernacular names
across plants, birds, mammals, amphibians, vertebrates, butterflies,
arthropods, fungi, algae, fish, and reptiles. All enrichments share the same underlying join mechanics,
download automatically on first use, cache locally for subsequent sessions,
and compose freely with the pipe operator.

The cross-backbone name resolution built into the `.vtr` files means we
do not have to worry about which backbone we used: enrichments work
identically with WFO, COL, GBIF, ITIS, NCBI, OTT, or WoRMS results. The
`summary()` method tracks which enrichments have been applied, their source
versions, and their coverage rates, supporting both exploratory analysis and
reproducible reporting.

For taxa or traits not covered by the built-in layers, `add_data()`
integrates any external dataset using the same backbone-resolved name
matching. Between the built-in enrichments and the `add_data()` escape hatch, most
common ecological analyses can go from raw species lists to trait-enriched
analytical tables in a single pipe chain.

The key properties of the enrichment system, to recap, are: automatic
download and caching (no manual data management), cross-backbone
compatibility (enrichments work regardless of which backend produced the
result), version tracking (the `summary()` method documents exactly which
data versions were used), and compositional design (enrichments stack
freely via the pipe operator without side effects or ordering constraints).
These properties together aim to make the path from species names to
trait-enriched analyses as short and reproducible as possible.
