---
title: "Examples of additional tidymodels features"
output: 
  rmarkdown::html_vignette:
    toc: true
  
#output: rmarkdown::pdf_document
vignette: >
  %\VignetteIndexEntry{Examples of additional tidymodels features}
  %\VignetteEngine{knitr::rmarkdown}
  %\VignetteEncoding{UTF-8}
---

```{r, include = FALSE}
knitr::opts_chunk$set(
  collapse = TRUE,
  comment = "#>"
)
# xgboost uses data.table
data.table::setDTthreads(2)
RhpcBLASctl::blas_set_num_threads(2)
RhpcBLASctl::omp_set_num_threads(2)

download_data <- FALSE
# note that data were created in the overview vignette
```


In this vignette, we illustrate how a number of features from `tidymodels` can
be used to enhance a conventional SDM pipeline. We recommend users first become familiar with `tidymodels`;
there are a number of excellent tutorials (both introductory and advanced) on its dedicated [website](https://www.tidymodels.org/)
We reuse the example on the Iberian lizard that we used
in the 
[`tidysdm` overview](https://evolecolgroup.github.io/tidysdm/articles/a0_tidysdm_overview.html) article.



# Exploring models with `DALEX`

An issue with machine learning algorithms is that it is not easy to understand the
role of different variables in giving the final prediction. A number of packages
have been created to explore and explain the behaviour of ML algorithms, such as those
used in `tidysdm`. In the [`tidysdm` overview](https://evolecolgroup.github.io/tidysdm/articles/a0_tidysdm_overview.html) article, we illustrated how to use `recipes` to create profiles.

Here we demonstrate how to use [DALEX](https://modeloriented.github.io/DALEX/), an excellent package
that has methods to deal with `tidymodels`. `tidysdm` contains additional functions that
allow use to use the DALEX functions directly on `tidysdm` ensembles. 

We will use a simple ensemble that we built in the overview vignette.

```{r}
library(tidysdm)
lacerta_ensemble
```

The first step in DALEX is to create an explainer object, which can then be
queried by different functions in the package, to turn the explainer into an
explanation (following the DALEX lingo). As a first step, we use the
custom function `explain_tidysdm` to generate our explainer:
```{r}
explainer_lacerta_ens <- explain_tidysdm(lacerta_ensemble)
```
Now that we have our explainer, we can explore variable importance for the ensemble:

```{r vip, fig.width=6, fig.height=4}
library(DALEX)
vip_ensemble <- model_parts(explainer = explainer_lacerta_ens)
plot(vip_ensemble)
```

Or generate partial dependency plots for a given variable (e.g. bio05):
```{r pdp, fig.width=6, fig.height=4}
pdp_bio05 <- model_profile(explainer_lacerta_ens, N = 500, variables = "bio05")
plot(pdp_bio05)
```

There are many other functions in DALEX that can be applied to the explainer to
further explore the behaviour of the model; see
several tutorial on https://modeloriented.github.io/DALEX/

It is also possible to explore the individual models that make up the ensemble:
```{r}
explainer_list <- explain_tidysdm(tidysdm::lacerta_ensemble, by_workflow = TRUE)
```

The resulting list can be then used to build lists of explanations, which can
then be plotted.

```{r profile, fig.width=6, fig.height=4}
profile_list <- lapply(explainer_list, model_profile,
  N = 500,
  variables = "bio05"
)
plot(profile_list)
```



# The initial split

The standard approach in `tidymodels` is to make an initial split of the data
into a test and a training set. We will use retain 20% of the data (1/5) for the testing set, and
use the rest for training.

We start by loading a set of presences and absences and their associated climate,
analogous to the one that we generated in the [`tidysdm` overview](https://evolecolgroup.github.io/tidysdm/articles/a0_tidysdm_overview.html) article:

```{r}
library(tidysdm)
library(sf)
lacerta_thin <- readRDS(system.file("extdata/lacerta_thin_all_vars.rds",
  package = "tidysdm"
))
```

We then use `spatial_initial_split` to do the split, using a `spatial_block_cv`
scheme to partition the data:

```{r initial_split, fig.width=6, fig.height=4}
set.seed(1005)
lacerta_initial <- spatial_initial_split(lacerta_thin,
  prop = 1 / 5, spatial_block_cv
)
autoplot(lacerta_initial)
```

And check the balance of presences vs pseudoabsences:
```{r}
check_splits_balance(lacerta_initial, class)
```


We can now extract the training set from our `lacerta_initial` split, and sample
folds to set up cross validation (note that we set the `cellsize` and `offset`
based on the full dataset, `lacerta_thin`; this allows us to use the same grid 
we used for the `initial_split`). In this example, we also have add a very small number
to the offset to avoid an error in the `spatial_block_cv` function arising from
some points falling on the boundary of the grid cells). This is often not necessary,
so only introduce this if you encounter an error.
```{r training_cv, fig.width=6, fig.height=4}
set.seed(1005)
lacerta_training <- training(lacerta_initial)
lacerta_cv <- spatial_block_cv(lacerta_training,
  v = 5,
  cellsize = grid_cellsize(lacerta_thin),
  offset = grid_offset(lacerta_thin) + 0.00001
)
autoplot(lacerta_cv)
```

And check the balance in the dataset:
```{r}
check_splits_balance(lacerta_cv, class)
```

# Different recipes for certain models

Only certain type of models (e.g. glm, svm) struggle with correlated variables;
other algorithms, such as random forests, can handle correlated variables. So,
we will create two recipes, one with all variables, and one only with the
variables that are uncorrelated:

```{r recipe}
lacerta_rec_all <- recipe(lacerta_thin, formula = class ~ .)
lacerta_rec_uncor <- lacerta_rec_all %>%
  step_rm(all_of(c(
    "bio01", "bio02", "bio03", "bio04", "bio07", "bio08",
    "bio09", "bio10", "bio11", "bio12", "bio14", "bio16",
    "bio17", "bio18", "bio19", "altitude"
  )))

lacerta_rec_uncor
```

And now use these two recipes in a `workflowset` (we will keep it small for computational time),
selecting the appropriate recipe for each model. We will include a model (polynomial
support vector machines, or SVM) which does not have a wrapper in `tidysdm`
for creating a model specification. However, we can use a standard model spec from
`yardstick`:

```{r workflow_set}
lacerta_models <-
  # create the workflow_set
  workflow_set(
    preproc = list(
      uncor = lacerta_rec_uncor, # recipe for the glm
      all = lacerta_rec_all, # recipe for the random forest
      all = lacerta_rec_uncor # recipe for svm
    ),
    models = list(
      # the standard glm specs
      glm = sdm_spec_glm(),
      # rf specs with tuning
      rf = sdm_spec_rf(),
      # svm specs with tuning
      svm = parsnip::svm_poly(
        cost = tune::tune(),
        degree = tune::tune()
      ) %>%
        parsnip::set_engine("kernlab") %>%
        parsnip::set_mode("classification")
    ),
    # make all combinations of preproc and models,
    cross = FALSE
  ) %>%
  # tweak controls to store information needed later to create the ensemble
  # note that we use the bayes version as we will use a Bayes search (see later)
  option_add(control = stacks::control_stack_bayes())
```


We can now use the block CV folds to
tune and assess the models. Note that there are multiple tuning approaches,
besides the standard grid method. Here we will use `tune_bayes` from the
`tune` package (see its
help page to see how a Gaussian Process model is used to choose parameter
combinations).


This tuning method (as opposed to use a standard grid) does not allow for
hyper-parameters with unknown limits, but
`mtry` for random forest is undefined as its upper range depends on the number of 
variables in the dataset. So, before tuning, we need to finalise `mtry` by 
informing the set dials with the actual data:

```{r}
rf_param <- lacerta_models %>%
  # extract the rf workflow
  extract_workflow("all_rf") %>%
  # extract its parameters dials (used to tune)
  extract_parameter_set_dials() %>%
  # give it the predictors to finalize mtry
  finalize(x = st_drop_geometry(lacerta_thin) %>% select(-class))

# now update the workflowset with the new parameter info
lacerta_models <- lacerta_models %>%
  option_add(param_info = rf_param, id = "all_rf")
```


And now we can tune the models:
```{r tune_grid}
set.seed(1234567)
lacerta_models <-
  lacerta_models %>%
  workflow_map("tune_bayes",
    resamples = lacerta_cv, initial = 8,
    metrics = sdm_metric_set(), verbose = TRUE
  )
```

We can have a look at the performance of our models with:

```{r}
autoplot(lacerta_models)
```

# Stack ensembles

Instead of building a simple ensemble with the best version of each model type, we
can build a stack ensemble, as implemented in the package `stacks`. Stacking
uses a meta-learning algorithm to learn how to best combine multiple models, including
multiple versions of the same algorithm with different hyper-parameters.

```{r build_stack, fig.width=6, fig.height=4}
library(stacks)
set.seed(1005)
lacerta_stack <-
  # initialize the stack
  stacks() %>%
  # add candidate members
  add_candidates(lacerta_models) %>%
  # determine how to combine their predictions
  blend_predictions() %>%
  # fit candidates with non-zero weights (i.e. non-zero stacking coefficients)
  fit_members()

autoplot(lacerta_stack, type = "weights")
```

We can see that three versions of the SVM and one of the random forests were selected;
the stacking coefficients give an indication of the weight each model carries
within the ensemble. We can now use the ensemble to make predictions about the
testing data:

```{r predict_test}
lacerta_testing <- testing(lacerta_initial)

lacerta_test_pred <-
  lacerta_testing %>%
  bind_cols(predict(lacerta_stack, ., type = "prob"))
```

And look at the goodness of fit using some commonly used sdm metrics. Note that
`sdm_metric_set` is first invoked to generate a function (with empty `()`) that is then used
on the data.

```{r assess_test}
sdm_metric_set()(data = lacerta_test_pred, truth = class, .pred_presence)
```

We can now make predictions with this stacked ensemble. We start by extracting the climate for the variables of interest

```{r eval=download_data}
download_dataset("WorldClim_2.1_10m")
climate_vars <- lacerta_rec_all$var_info %>%
  filter(role == "predictor") %>%
  pull(variable)

climate_present <- pastclim::region_slice(
  time_ce = 1985,
  bio_variables = climate_vars,
  data = "WorldClim_2.1_10m",
  crop = iberia_poly
)
```

```{r echo=FALSE, results='hide', eval=!download_data}
climate_present <- terra::readRDS(
  system.file("extdata/lacerta_climate_present_10m.rds", package = "tidysdm")
)
climate_vars <- lacerta_rec_all$var_info %>%
  filter(role == "predictor") %>%
  pull(variable)
if (!all(climate_vars %in% names(climate_present))) {
  stop("mismatched variables in the raster")
}
```


```{r plot_present, fig.width=6, fig.height=4}
prediction_present <- predict_raster(lacerta_stack, climate_present,
  type = "prob"
)
library(tidyterra)
ggplot() +
  geom_spatraster(data = prediction_present, aes(fill = .pred_presence)) +
  scale_fill_terrain_c() +
  # plot presences used in the model
  geom_sf(data = lacerta_thin %>% filter(class == "presence"))
```

# Using multi-level factors as predictors

Most machine learning algorithms do not natively use multilevel factors as predictors.
The solution is to create dummy variables, which are binary variables that represent
the levels of the factor. In `tidymodels`, this is done using the `step_dummy` function.

Let's create a factor variable with 3 levels based on altitude.
```{r}
library(tidysdm)
# load the dataset
lacerta_thin <- readRDS(system.file("extdata/lacerta_thin_all_vars.rds",
  package = "tidysdm"
))
# create a topography variable with 3 levels based on altitude
lacerta_thin$topography <- cut(lacerta_thin$altitude,
  breaks = c(-Inf, 200, 800, Inf),
  labels = c("plains", "hills", "mountains")
)
table(lacerta_thin$topography)
```

We then create the recipe by adding a step to create dummy variables for the `topography` variable.
```{r}
# subset to variable of interest
lacerta_thin <- lacerta_thin %>% select(
  class, bio05, bio06, bio12,
  bio15, topography
)

lacerta_rec <- recipe(lacerta_thin, formula = class ~ .) %>%
  step_dummy(topography)
lacerta_rec
```

Let's us see what this does:
```{r}
lacerta_prep <- prep(lacerta_rec)
summary(lacerta_prep)
```
We have added two "derived" variables, *topography_hills* and *topography_mountains*, which are binary
variables that 
allow us to code topography (with plains
being used as the reference level, which is coded by both hills and mountains being 0 for a given location).
We can look at the first few rows of the data to see the new variables by baking the recipe:

```{r}
lacerta_bake <- bake(lacerta_prep, new_data = lacerta_thin)
glimpse(lacerta_bake)
```

We can now run the sdm as usual:
```{r}
# define the models
lacerta_models <-
  # create the workflow_set
  workflow_set(
    preproc = list(default = lacerta_rec),
    models = list(
      # the standard glm specs
      glm = sdm_spec_glm(),
      # rf specs with tuning
      rf = sdm_spec_rf()
    ),
    # make all combinations of preproc and models,
    cross = TRUE
  ) %>%
  # tweak controls to store information needed later to create the ensemble
  option_add(control = control_ensemble_grid())
# tune
set.seed(100)
lacerta_cv <- spatial_block_cv(lacerta_thin, v = 3)
lacerta_models <-
  lacerta_models %>%
  workflow_map("tune_grid",
    resamples = lacerta_cv, grid = 3,
    metrics = sdm_metric_set(), verbose = TRUE
  )
# fit the ensemble
lacerta_ensemble <- simple_ensemble() %>%
  add_member(lacerta_models, metric = "boyce_cont")
```

We can now verify that the dummy variables were used by extracting the model fit from
one of the models in the ensemble:
```{r}
lacerta_ensemble$workflow[[1]] %>% extract_fit_parsnip()
```

We can see that we have coefficients for *topography_hills* and *topography_mountains*.

Let us now predict the presence of the lizard in the Iberian Peninsula using the ensemble. Note that,
for `predict_raster()` to work, the name and levels for a categorical variable need to match with those used
when training the models (i.e. in the recipe with `step_dummy()`):
```{r}
climate_present <- terra::readRDS(
  system.file("extdata/lacerta_climate_present_10m.rds",
    package = "tidysdm"
  )
)
# first we add a topography variable to the climate data
climate_present$topography <- climate_present$altitude
climate_present$topography <- terra::classify(climate_present$topography,
  rcl = c(-Inf, 200, 800, Inf),
  include.lowest = TRUE,
  brackets = TRUE
)
library(terra)
levels(climate_present$topography) <-
  data.frame(ID = c(0, 1, 2), topography = c("plains", "hills", "mountains"))
# now we can predict
predict_factor <- predict_raster(lacerta_ensemble, climate_present)
plot(predict_factor)
```