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The goal of burgle is to “steal” only the necessary parts of model objects for applications in simuation.
install.packages("burgle")
Or you can install the development version of burgle like so:
::install_github("ClevelandClinicQHS/burgle") devtools
burgle
set.seed(287453)
library(burgle)
<- lm(Sepal.Length ~., data = iris)
fit <- burgle(fit)
bfit ::object_size(fit)
pryr#> 39.43 kB
::object_size(bfit)
pryr#> 2.88 kB
as.numeric(pryr::object_size(bfit)/pryr::object_size(fit))*100
#> [1] 7.303713
Our burgle_lm
is roughly 7.3% the size of the original
lm
object, the iris dataset has 150 observations and 5
columns.
Another example is the using the nycflights13::flights
dataset.
<- lm(arr_delay ~ as.factor(month) + dep_delay + origin + distance + hour, data = nycflights13::flights)
fit2 <- burgle(fit2)
b_fit2
as.numeric(pryr::object_size(b_fit2)/pryr::object_size(fit2))*100
#> [1] 0.008213793
Our burgle_lm
is roughly 0.01% the size of the original
lm
object. This dataset has 336776 observations and our
model has used 5 of the 19 columns as predictors.
Here one can see a simulated dataset of 10 million data points with 3 random covariates.
<- 1e7
N <- data.frame(y = rnorm(N), x1 = runif(N), x2 = runif(N, -1, 1), x3 = runif(N, -2, 2))
df <- lm(y~., data = df)
mfit <- burgle(mfit)
b_mfit
<- pryr::object_size(mfit)
m0 print(m0, units = "Gb")
#> 1.60 GB
::object_size(b_mfit)
pryr#> 2.15 kB
The lm
is 1.6 Gb while the burgle_lm
object
is 2152 bytes. A reduction of size by 10^6!
The new predict methods for our burgle
objects allow for
one to easily predict new values and multiple simluated responses of
newdata
. The structure is as follows:
newdata
draws
set to 1 by default)sims
set
to 1 by default)If one wants to predict using the original model simply set
original = TRUE
.
Depending on the model object there are different types of
predictions. By default it will return the linear predictor
(lp)
. If one wants to see the response
(type = "response"
), which makes more sense when using
glm
objects and survival models. The se = FALSE
is an argument on whether to include the standard error of the model
when simluating responses. TRUE
means to use the model
standard error when sampling. We recommend setting it to TRUE when doing
more than one simulation or when setting
type = "response"
.
predict(bfit, newdata = head(iris), original = TRUE, draws = 1, se = FALSE, type = "lp")
#> [,1]
#> 1 5.004788
#> 2 4.756844
#> 3 4.773097
#> 4 4.889357
#> 5 5.054377
#> 6 5.388886
predict(bfit, newdata = head(iris), original = FALSE, draws = 5, type = "lp")
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 5.056657 5.007215 4.961257 4.932543 5.050141
#> [2,] 4.790295 4.746012 4.713736 4.754813 4.785725
#> [3,] 4.822688 4.775977 4.736837 4.739272 4.814687
#> [4,] 4.917719 4.872770 4.839147 4.876992 4.915412
#> [5,] 5.109929 5.059456 5.010762 4.968089 5.103024
#> [6,] 5.454726 5.424994 5.301047 5.286944 5.422597
## These two should be similar
predict(bfit, newdata = head(iris), original = FALSE, draws = 5, sims = 5, se = TRUE, type = "response")
#> [[1]]
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 5.188335 5.064758 4.528114 5.460978 4.938227
#> [2,] 4.301446 4.554181 4.743173 4.829344 4.793417
#> [3,] 4.441790 4.637052 4.831230 4.536184 4.383245
#> [4,] 4.739983 4.891668 4.808410 4.820148 5.297950
#> [5,] 4.470888 5.130100 4.996598 5.327621 5.217366
#> [6,] 5.012921 5.122429 5.258801 4.947419 5.906721
#>
#> [[2]]
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 4.617066 5.588269 4.633249 4.743949 5.383410
#> [2,] 4.956657 4.558627 4.992207 4.682602 4.068407
#> [3,] 4.600649 4.620536 4.568879 4.919372 4.894229
#> [4,] 4.550183 4.777452 5.177517 4.658162 5.435255
#> [5,] 5.061492 4.952346 4.724817 4.587407 4.911647
#> [6,] 5.589748 5.249421 5.258343 5.781827 4.594522
#>
#> [[3]]
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 4.654951 5.018870 5.111338 4.881092 5.267062
#> [2,] 4.979906 5.620321 4.146499 5.021050 4.759204
#> [3,] 4.666988 4.154987 5.114534 4.697866 4.957075
#> [4,] 4.611058 4.369505 4.767237 4.834120 4.395112
#> [5,] 4.653835 5.552697 5.733886 4.925832 4.933249
#> [6,] 5.918499 5.859100 5.146537 5.276244 5.499586
#>
#> [[4]]
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 4.957008 5.086826 5.090159 4.612207 5.024133
#> [2,] 4.917264 4.299553 4.726446 4.003881 4.799311
#> [3,] 5.164780 4.434195 5.413705 4.613030 4.858791
#> [4,] 4.609427 5.069844 4.472140 4.443499 4.939135
#> [5,] 4.441486 4.840654 5.358090 4.544883 4.997390
#> [6,] 5.557312 5.554476 5.046674 5.480583 5.295779
#>
#> [[5]]
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 5.306194 4.787267 4.607056 5.086712 4.689726
#> [2,] 4.593383 4.595724 4.741960 4.961092 4.503969
#> [3,] 4.868304 5.384595 4.949947 5.243014 4.305317
#> [4,] 4.795677 4.308122 5.015002 4.419806 5.059970
#> [5,] 5.347532 5.804453 5.136792 4.602399 4.960713
#> [6,] 6.070301 5.485667 5.432137 4.758103 5.662043
The framework should work with all glm
family options,
just the binomial example is demonstrated below.
<- burgle(glm(I(Species == "versicolor") ~ ., family = "binomial", data = iris))
b_glm
predict(b_glm, head(iris), original = FALSE, se = TRUE, draws = 5, type = "lp")
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 1.1931513 0.8544506 -0.9125312 -4.449063 -5.371412
#> [2,] 2.2506299 1.8325844 -1.2188106 -2.859110 -5.147537
#> [3,] -1.2826411 1.7282266 -2.2889517 -2.672046 -3.255157
#> [4,] -0.5582609 0.2016295 -3.3602143 -2.508221 -1.622880
#> [5,] -2.6288233 -4.6355719 -2.9090909 -2.429126 -2.970703
#> [6,] 1.1098697 -5.8229683 -2.4733745 -3.157545 -6.473457
predict(b_glm, head(iris), original = FALSE, se = TRUE, draws = 5, type = "response")
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 0 1 0 0 1
#> [2,] 0 1 0 0 1
#> [3,] 1 0 0 0 1
#> [4,] 0 1 0 0 0
#> [5,] 1 0 0 0 0
#> [6,] 0 0 0 0 0
library(survival)
<- survival::lung
lung $status <- lung$status - 1
lung
<- coxph(Surv(time, status) ~ age + sex + ph.ecog + ph.karno + pat.karno, data = lung)
cox <- coxph(Surv(time, status) ~ age + sex + ph.ecog + ph.karno + pat.karno, data = lung, x = FALSE, y = FALSE)
cox_sm
<- burgle(cox)
b_cox ::object_size(cox)
pryr#> 36.02 kB
::object_size(cox_sm)
pryr#> 31.21 kB
::object_size(b_cox)
pryr#> 5.59 kB
as.numeric(pryr::object_size(b_cox)/pryr::object_size(cox))*100
#> [1] 15.52643
as.numeric(pryr::object_size(b_cox)/pryr::object_size(cox_sm))*100
#> [1] 17.91848
Our burgle_coxph
model is 17.92% the size of the
original Cox proportional hazards model even after setting
x=FALSE
and y= FALSE
. The lung dataset has 228
observations.
One way to further reduce the size of the burgle_coxph
is to reduce the number of unique time points in the data, since the it
contains the baseline hazard of the model. The lung dataset as 186
unique values. If we were to round these to the nearest 14 days that
would reduce the number of timepoints to 58.
$time2 <- plyr::round_any(lung$time, 14)
lung<- coxph(Surv(time2, status) ~ age + sex + ph.ecog + ph.karno + pat.karno, data = lung, x = TRUE, y = FALSE)
cox2 <- burgle(cox2)
b_cox2
::object_size(cox2)
pryr#> 42.50 kB
::object_size(b_cox2)
pryr#> 3.87 kB
as.numeric(pryr::object_size(b_cox2)/pryr::object_size(cox2))*100
#> [1] 9.109731
This reduce the size to 9.11% of the original coxph
object.
Predictions are a slightly different structure for survival or
longitudinal models if type = "response"
or
"risk"
, since a time point is required. If
type = "response"
the returned results is a simulated 1 or
0 if the event has been experienced or not at a given time point(s). The
structure is as follows:
newdata
draws
)predict(b_cox, newdata = head(lung), original = TRUE, draws = 1, type = "lp")
#> [,1]
#> [1,] 1.2620217
#> [2,] 0.7293038
#> [3,] 0.5927067
#> [4,] 1.4729644
#> [5,] 0.7967660
#> [6,] 0.8301417
predict(b_cox, newdata = head(lung), original = TRUE, draws = 1, type = "risk", times = 500)
#> [,1]
#> [1,] 0.8051989
#> [2,] 0.6171886
#> [3,] 0.5672583
#> [4,] 0.8673345
#> [5,] 0.6420013
#> [6,] 0.6542671
predict(b_cox, newdata = head(lung), original = TRUE, draws = 1, type = "risk", times = c(500, 1000))
#> Warning in predict.burgle_coxph(b_cox, newdata = head(lung), original = TRUE, :
#> times has a value of 1000 which is larger than the maximum time value of 883
#> [,1] [,2]
#> [1,] 0.8051989 0.9851588
#> [2,] 0.6171886 0.9155426
#> [3,] 0.5672583 0.8842068
#> [4,] 0.8673345 0.9944786
#> [5,] 0.6420013 0.9289231
#> [6,] 0.6542671 0.9350234
predict(b_cox, newdata = head(lung), original = TRUE, draws = 1, type = "response", times = c(500, 1000))
#> Warning in predict.burgle_coxph(b_cox, newdata = head(lung), original = TRUE, :
#> times has a value of 1000 which is larger than the maximum time value of 883
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 0 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 1 1
#> [6,] 1 1
predict(b_cox, newdata = head(lung), original = FALSE, draws = 5, sims = 2, type = "response", times = c(500, 1000))
#> Warning in predict.burgle_coxph(b_cox, newdata = head(lung), original = FALSE,
#> : times has a value of 1000 which is larger than the maximum time value of 883
#> [[1]]
#> [[1]][[1]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 0 1
#> [6,] 1 1
#>
#> [[1]][[2]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 0 1
#> [4,] 1 1
#> [5,] 1 1
#> [6,] 0 1
#>
#>
#> [[2]]
#> [[2]][[1]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 0 0
#> [4,] 1 1
#> [5,] 1 1
#> [6,] 1 1
#>
#> [[2]][[2]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 1 1
#> [6,] 1 1
#>
#>
#> [[3]]
#> [[3]][[1]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 1 1
#> [6,] 1 1
#>
#> [[3]][[2]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 1 1
#> [6,] 1 1
#>
#>
#> [[4]]
#> [[4]][[1]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 1 1
#> [6,] 1 1
#>
#> [[4]][[2]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 1 1
#> [6,] 1 1
#>
#>
#> [[5]]
#> [[5]][[1]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 0 1
#> [6,] 1 1
#>
#> [[5]][[2]]
#> [,1] [,2]
#> [1,] 1 1
#> [2,] 1 1
#> [3,] 1 1
#> [4,] 1 1
#> [5,] 0 1
#> [6,] 1 1
## The original model at time 500
predict(b_cox, newdata = head(lung), original = TRUE, draws = 1, type = "risk", times = c(500))
#> [,1]
#> [1,] 0.8051989
#> [2,] 0.6171886
#> [3,] 0.5672583
#> [4,] 0.8673345
#> [5,] 0.6420013
#> [6,] 0.6542671
## Doing 1000 simulations from the original model and calculating the death rate
<- predict(b_cox, newdata = head(lung), original = TRUE, draws = 1, sims = 1000, type = "response", times = c(500)) |>
a0 ::list_flatten() |>
purrrReduce(f = cbind, x = _) |>
apply(1, mean)
a0#> [1] 0.829 0.610 0.553 0.862 0.661 0.635
## Average survival death rate based on 1000 different models
<- predict(b_cox, newdata = head(lung), original = FALSE, draws = 1000, type = "response", times = c(500)) |>
a1 ::list_flatten() |>
purrrReduce(f = cbind, x = _) |>
apply(1, mean)
a1#> [1] 0.705 0.579 0.573 0.758 0.603 0.610
## Average survival rate based on 100 simlutions for each of the 1000 models
<- predict(b_cox, newdata = head(lung), original = FALSE, draws = 1000, sims = 100, type = "response", times = c(500))
a2
### Average death per model
<- lapply(a2, function(x) apply(Reduce(cbind, x), 1, mean))
a3
## Median death rate across 1000 models and 100 simulations for each model
Reduce(rbind, a3) |>
apply(2, median)
#> [1] 0.810 0.625 0.570 0.870 0.645 0.660
This structure has also been implemented for
riskRegression::CSC
and flexsurv::flexsurvreg
objects and numerous others on the works and the plan is to also
incorporate rstan
objects, and an overall
predict.burgle_default
method and which will only a mean
and covariance matrix as inputs.
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.