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butcher

library(butcher)
library(parsnip)

One of the benefits of working in R is the ease with which you can implement complex models and implement challenging data analysis pipelines. Take, for example, the parsnip package; with the installation of a few associated libraries and a few lines of code, you can fit something as sophisticated as a boosted tree:

fitted_model <- boost_tree(mode = "regression") %>%
  fit(mpg ~ ., data = mtcars)

Yet, while this code is compact, the underlying fitted result may not be. Since parsnip works as a wrapper for many modeling packages, its fitted model objects inherit the same properties as those that arise from the original modeling package. A straightforward example is the lm() function from the base stats package. Whether you leverage parsnip or not, you get the same result:

parsnip_lm <- linear_reg() %>% 
  fit(mpg ~ ., data = mtcars) 
parsnip_lm
#> parsnip model object
#> 
#> 
#> Call:
#> stats::lm(formula = mpg ~ ., data = data)
#> 
#> Coefficients:
#> (Intercept)          cyl         disp           hp         drat           wt  
#>    12.30337     -0.11144      0.01334     -0.02148      0.78711     -3.71530  
#>        qsec           vs           am         gear         carb  
#>     0.82104      0.31776      2.52023      0.65541     -0.19942

Using just lm():

old_lm <- lm(mpg ~ ., data = mtcars) 
old_lm
#> 
#> Call:
#> lm(formula = mpg ~ ., data = mtcars)
#> 
#> Coefficients:
#> (Intercept)          cyl         disp           hp         drat           wt  
#>    12.30337     -0.11144      0.01334     -0.02148      0.78711     -3.71530  
#>        qsec           vs           am         gear         carb  
#>     0.82104      0.31776      2.52023      0.65541     -0.19942

Let’s say we take this familiar old_lm approach in building a custom in-house modeling pipeline. Such a pipeline might entail wrapping lm() in other function, but in doing so, we may end up carrying around some unnecessary junk.

in_house_model <- function() {
  some_junk_in_the_environment <- runif(1e6) # we didn't know about
  lm(mpg ~ ., data = mtcars) 
}

The linear model fit that exists in our custom modeling pipeline is then:

library(lobstr)
obj_size(in_house_model())
#> 8.02 MB

But it is functionally the same as our old_lm, which only takes up:

obj_size(old_lm)
#> 22.22 kB

Ideally, we want to avoid saving this new in_house_model() on disk, when we could have something like old_lm that takes up less memory. But what the heck is going on here? We can examine possible issues with a fitted model object using the butcher package:

big_lm <- in_house_model()
weigh(big_lm, threshold = 0, units = "MB")
#> # A tibble: 25 × 2
#>    object            size
#>    <chr>            <dbl>
#>  1 terms         8.01    
#>  2 qr.qr         0.00666 
#>  3 residuals     0.00286 
#>  4 fitted.values 0.00286 
#>  5 effects       0.0014  
#>  6 coefficients  0.00109 
#>  7 call          0.000728
#>  8 model.mpg     0.000304
#>  9 model.cyl     0.000304
#> 10 model.disp    0.000304
#> # ℹ 15 more rows

The problem here is in the terms component of big_lm. Because of how lm() is implemented in the base stats package (relying on intermediate forms of the data from model.frame and model.matrix) the environment in which the linear fit was created is carried along in the model output.

We can see this with the env_print() function from the rlang package:

library(rlang)
env_print(big_lm$terms)
#> <environment: 0x14276b4c8>
#> Parent: <environment: global>
#> Bindings:
#> • some_junk_in_the_environment: <dbl>

To avoid carrying possible junk around in our production pipeline, whether it be associated with an lm() model (or something more complex), we can leverage axe_env() from the butcher package:

cleaned_lm <- axe_env(big_lm, verbose = TRUE)
#> ✔ Memory released: 8.00 MB

Comparing it against our old_lm, we find:

weigh(cleaned_lm, threshold = 0, units = "MB")
#> # A tibble: 25 × 2
#>    object            size
#>    <chr>            <dbl>
#>  1 terms         0.00771 
#>  2 qr.qr         0.00666 
#>  3 residuals     0.00286 
#>  4 fitted.values 0.00286 
#>  5 effects       0.0014  
#>  6 coefficients  0.00109 
#>  7 call          0.000728
#>  8 model.mpg     0.000304
#>  9 model.cyl     0.000304
#> 10 model.disp    0.000304
#> # ℹ 15 more rows

And now it takes the same memory on disk:

weigh(old_lm, threshold = 0, units = "MB")
#> # A tibble: 25 × 2
#>    object            size
#>    <chr>            <dbl>
#>  1 terms         0.00763 
#>  2 qr.qr         0.00666 
#>  3 residuals     0.00286 
#>  4 fitted.values 0.00286 
#>  5 effects       0.0014  
#>  6 coefficients  0.00109 
#>  7 call          0.000728
#>  8 model.mpg     0.000304
#>  9 model.cyl     0.000304
#> 10 model.disp    0.000304
#> # ℹ 15 more rows

Axing the environment, however, is not the only functionality of butcher. This package provides five S3 generics that include:

In our case here with lm(), if we are only interested in prediction as the end product of our modeling pipeline, we could free up a lot of memory if we execute all the possible axe functions at once. To do so, we simply run butcher():

butchered_lm <- butcher(big_lm)
predict(butchered_lm, mtcars[, 2:11])
#>           Mazda RX4       Mazda RX4 Wag          Datsun 710      Hornet 4 Drive 
#>            22.59951            22.11189            26.25064            21.23740 
#>   Hornet Sportabout             Valiant          Duster 360           Merc 240D 
#>            17.69343            20.38304            14.38626            22.49601 
#>            Merc 230            Merc 280           Merc 280C          Merc 450SE 
#>            24.41909            18.69903            19.19165            14.17216 
#>          Merc 450SL         Merc 450SLC  Cadillac Fleetwood Lincoln Continental 
#>            15.59957            15.74222            12.03401            10.93644 
#>   Chrysler Imperial            Fiat 128         Honda Civic      Toyota Corolla 
#>            10.49363            27.77291            29.89674            29.51237 
#>       Toyota Corona    Dodge Challenger         AMC Javelin          Camaro Z28 
#>            23.64310            16.94305            17.73218            13.30602 
#>    Pontiac Firebird           Fiat X1-9       Porsche 914-2        Lotus Europa 
#>            16.69168            28.29347            26.15295            27.63627 
#>      Ford Pantera L        Ferrari Dino       Maserati Bora          Volvo 142E 
#>            18.87004            19.69383            13.94112            24.36827

Alternatively, we can pick and choose specific axe functions, removing only those parts of the model object that we are no longer interested in characterizing.

butchered_lm <- big_lm %>%
  axe_env() %>% 
  axe_fitted()
predict(butchered_lm, mtcars[, 2:11])
#>           Mazda RX4       Mazda RX4 Wag          Datsun 710      Hornet 4 Drive 
#>            22.59951            22.11189            26.25064            21.23740 
#>   Hornet Sportabout             Valiant          Duster 360           Merc 240D 
#>            17.69343            20.38304            14.38626            22.49601 
#>            Merc 230            Merc 280           Merc 280C          Merc 450SE 
#>            24.41909            18.69903            19.19165            14.17216 
#>          Merc 450SL         Merc 450SLC  Cadillac Fleetwood Lincoln Continental 
#>            15.59957            15.74222            12.03401            10.93644 
#>   Chrysler Imperial            Fiat 128         Honda Civic      Toyota Corolla 
#>            10.49363            27.77291            29.89674            29.51237 
#>       Toyota Corona    Dodge Challenger         AMC Javelin          Camaro Z28 
#>            23.64310            16.94305            17.73218            13.30602 
#>    Pontiac Firebird           Fiat X1-9       Porsche 914-2        Lotus Europa 
#>            16.69168            28.29347            26.15295            27.63627 
#>      Ford Pantera L        Ferrari Dino       Maserati Bora          Volvo 142E 
#>            18.87004            19.69383            13.94112            24.36827

The butcher package provides tooling to axe parts of the fitted output that are no longer needed, without sacrificing much functionality from the original model object.

These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.