---
title: "collapse and data.table"
subtitle: "Harmony and High Performance"
author: "Sebastian Krantz"
date: "2021-06-27"
output:
rmarkdown::html_vignette:
toc: true
vignette: >
%\VignetteIndexEntry{collapse and data.table}
%\VignetteEngine{knitr::rmarkdown}
%\VignetteEncoding{UTF-8}
---
This vignette focuses on using *collapse* with the popular *data.table* package by Matt Dowle and Arun Srinivasan. In contrast to *dplyr* and *plm* whose methods ('grouped_df', 'pseries', 'pdata.frame') *collapse* supports, the integration between *collapse* and *data.table* is hidden in the 'data.frame' methods and *collapse*'s C code.
From version 1.6.0 *collapse* seamlessly handles *data.tables*, permitting reference operations (`set*`, `:=`) on data tables created with collapse (`qDT`) or returned from *collapse*'s data manipulation functions (= all functions except `.FAST_FUN`, `.OPERATOR_FUN`, `BY` and `TRA`, see the [NEWS]() for details on the low-level integration). Apart from *data.table* reference semantics, both packages work similarly on the C/C++ side of things, and nicely complement each other in functionality.
## Overview of Both Packages
Both *data.table* and *collapse* are high-performance packages that work well together. For effective co-use it is helpful to understand where each has its strengths, what one can do what the other cannot, and where they overlap. Therefore this small comparison:
* *data.table* offers an enhanced data frame based class to contain data (including list columns). For this class it provides a concise data manipulation syntax which also includes fast aggregation / slit-apply-combine computing, (rolling, non-equi) joins, keying, reshaping, some time-series functionality like lagging and rolling statistics, set operations on tables and a number of very useful other functions like the fast csv reader, fast switches, list-transpose etc.. *data.table* makes data management, and computations on data very easy and scalable, supporting huge datasets in a very memory efficient way. The package caters well to the end user by compressing an enormous amount of functionality into two square brackets `[]`. Some of the exported functions are great for programming and also support other classes, but a lot of the functionality and optimization of *data.table* happens under the hood and can only be accessed through the non-standard evaluation table `[i, j, by]` syntax. This syntax has a cost of about 1-3 milliseconds for each call. Memory efficiency and thread-parallelization make *data.table* the star performer on huge data.
* *collapse* is class-agnostic in nature, supporting vectors, matrices, data frames and non-destructively handling most R classes and objects. It focuses on advanced statistical computing, proving fast column-wise grouped and weighted statistical functions, fast and complex data aggregation and transformations, linear fitting, time series and panel data computations, advanced summary statistics, and recursive processing of lists of data objects. It also includes powerful functions for data manipulation, grouping / factor generation, recoding, handling outliers and missing values. The package default for missing values is `na.rm = TRUE`, which is implemented efficiently in C/C++ in all functions. *collapse* supports both *tidyverse* (piped) and base R / standard evaluation programming. It makes accessible most of it's internal C/C++ based functionality (like grouping objects). *collapse*'s R functions are simple and strongly optimized, i.e. they access the serial C/C++ code quickly, resulting in baseline execution speeds of 10-50 microseconds. All of this makes *collapse* ideal for advanced statistical computing on matrices and larger datasets, and tasks requiring fast programs with repeated function executions.
## Interoperating and some Do's and Dont's
Applying *collapse* functions to a data.table always gives a data.table back e.g.
```r
library(collapse)
library(magrittr)
library(data.table)
DT <- qDT(wlddev) # collapse::qDT converts objects to data.table using a shallow copy
DT %>% gby(country) %>% gv(9:13) %>% fmean
# country PCGDP LIFEEX GINI ODA POP
#
# 1: Afghanistan 483.8351 49.19717 NA 1487548499 18362258.22
# 2: Albania 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: Algeria 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: American Samoa 10071.0659 NA NA NA 43115.10
# 5: Andorra 40083.0911 NA NA NA 51547.35
# ---
# 212: Virgin Islands (U.S.) 35629.7336 73.71292 NA NA 92238.53
# 213: West Bank and Gaza 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: Yemen, Rep. 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: Zambia 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: Zimbabwe 1219.4360 54.53360 45.93333 397104997 9402160.33
# Same thing, but notice that fmean give's NA's for missing countries
DT[, lapply(.SD, mean, na.rm = TRUE), keyby = country, .SDcols = 9:13]
# Key:
# country PCGDP LIFEEX GINI ODA POP
#
# 1: Afghanistan 483.8351 49.19717 NaN 1487548499 18362258.22
# 2: Albania 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: Algeria 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: American Samoa 10071.0659 NaN NaN NaN 43115.10
# 5: Andorra 40083.0911 NaN NaN NaN 51547.35
# ---
# 212: Virgin Islands (U.S.) 35629.7336 73.71292 NaN NaN 92238.53
# 213: West Bank and Gaza 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: Yemen, Rep. 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: Zambia 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: Zimbabwe 1219.4360 54.53360 45.93333 397104997 9402160.33
# This also works without magrittr pipes with the collap() function
collap(DT, ~ country, fmean, cols = 9:13)
# country PCGDP LIFEEX GINI ODA POP
#
# 1: Afghanistan 483.8351 49.19717 NA 1487548499 18362258.22
# 2: Albania 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: Algeria 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: American Samoa 10071.0659 NA NA NA 43115.10
# 5: Andorra 40083.0911 NA NA NA 51547.35
# ---
# 212: Virgin Islands (U.S.) 35629.7336 73.71292 NA NA 92238.53
# 213: West Bank and Gaza 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: Yemen, Rep. 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: Zambia 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: Zimbabwe 1219.4360 54.53360 45.93333 397104997 9402160.33
```
By default, *collapse* orders groups in aggregations, which is equivalent to using `keyby` with *data.table*. `gby / fgroup_by` has an argument `sort = FALSE` to yield an unordered grouping equivalent to *data.table*'s `by` on character data^[Grouping on numeric variables in *collapse* is always ordered.].
At this data size *collapse* outperforms *data.table* (which might reverse as data size grows, depending in your computer, the number of *data.table* threads used, and the function in question):
```r
library(microbenchmark)
microbenchmark(collapse = DT %>% gby(country) %>% get_vars(9:13) %>% fmean,
data.table = DT[, lapply(.SD, mean, na.rm = TRUE), keyby = country, .SDcols = 9:13])
# Unit: microseconds
# expr min lq mean median uq max neval
# collapse 203.073 212.7285 223.4156 217.1565 225.6230 475.559 100
# data.table 758.623 777.4010 929.5450 793.1655 854.4605 2292.515 100
```
It is critical to never do something like this:
```r
DT[, lapply(.SD, fmean), keyby = country, .SDcols = 9:13]
# Key:
# country PCGDP LIFEEX GINI ODA POP
#
# 1: Afghanistan 483.8351 49.19717 NA 1487548499 18362258.22
# 2: Albania 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: Algeria 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: American Samoa 10071.0659 NA NA NA 43115.10
# 5: Andorra 40083.0911 NA NA NA 51547.35
# ---
# 212: Virgin Islands (U.S.) 35629.7336 73.71292 NA NA 92238.53
# 213: West Bank and Gaza 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: Yemen, Rep. 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: Zambia 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: Zimbabwe 1219.4360 54.53360 45.93333 397104997 9402160.33
```
The reason is that *collapse* functions are S3 generic with methods for vectors, matrices and data frames among others. So you incur a method-dispatch for every column and every group the function is applied to.
```r
fmean
# function (x, ...)
# UseMethod("fmean")
#
#
methods(fmean)
# [1] fmean.data.frame* fmean.default* fmean.grouped_df* fmean.list* fmean.matrix*
# [6] fmean.units* fmean.zoo*
# see '?methods' for accessing help and source code
```
You may now contend that `base::mean` is also S3 generic, but in this `DT[, lapply(.SD, mean, na.rm = TRUE), by = country, .SDcols = 9:13]` code *data.table* does not use `base::mean`, but `data.table:::gmean`, an internal optimized mean function which is efficiently applied over those groups (see `?data.table::GForce`). `fmean` works similar, and includes this functionality explicitly.
```r
args(fmean.data.frame)
# function (x, g = NULL, w = NULL, TRA = NULL, na.rm = .op[["na.rm"]],
# use.g.names = TRUE, drop = TRUE, nthreads = .op[["nthreads"]],
# ...)
# NULL
```
Here we can see the `x` argument for the data, the `g` argument for grouping vectors, a weight vector `w`, different options `TRA` to transform the original data using the computed means, and some functionality regarding missing values (default: removed / skipped), group names (which are added as row-names to a data frame, but not to a *data.table*) etc. So we can also do
```r
fmean(gv(DT, 9:13), DT$country)
# PCGDP LIFEEX GINI ODA POP
#
# 1: 483.8351 49.19717 NA 1487548499 18362258.22
# 2: 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: 10071.0659 NA NA NA 43115.10
# 5: 40083.0911 NA NA NA 51547.35
# ---
# 212: 35629.7336 73.71292 NA NA 92238.53
# 213: 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: 1219.4360 54.53360 45.93333 397104997 9402160.33
# Or
g <- GRP(DT, "country")
add_vars(g[["groups"]], fmean(gv(DT, 9:13), g))
# country PCGDP LIFEEX GINI ODA POP
#
# 1: Afghanistan 483.8351 49.19717 NA 1487548499 18362258.22
# 2: Albania 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: Algeria 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: American Samoa 10071.0659 NA NA NA 43115.10
# 5: Andorra 40083.0911 NA NA NA 51547.35
# ---
# 212: Virgin Islands (U.S.) 35629.7336 73.71292 NA NA 92238.53
# 213: West Bank and Gaza 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: Yemen, Rep. 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: Zambia 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: Zimbabwe 1219.4360 54.53360 45.93333 397104997 9402160.33
```
To give us the same result obtained through the high-level functions `gby / fgroup_by` or `collap`. This is however not what *data.table* is doing in `DT[, lapply(.SD, fmean), by = country, .SDcols = 9:13]`. Since `fmean` is not a function it recognizes and is able to optimize, it does something like this,
```r
BY(gv(DT, 9:13), g, fmean) # using collapse::BY
# PCGDP LIFEEX GINI ODA POP
#
# 1: 483.8351 49.19717 NA 1487548499 18362258.22
# 2: 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: 10071.0659 NA NA NA 43115.10
# 5: 40083.0911 NA NA NA 51547.35
# ---
# 212: 35629.7336 73.71292 NA NA 92238.53
# 213: 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: 1219.4360 54.53360 45.93333 397104997 9402160.33
```
which applies `fmean` to every group in every column of the data.
More generally, it is very important to understand that *collapse* is not based around applying functions to data by groups using some universal mechanism: The *dplyr* `data %>% group_by(...) %>% summarize(...) / mutate(...)` and *data.table* `[i, j, by]` syntax are essentially universal mechanisms to apply any function to data by groups.
*data.table* additionally internally optimizes some functions (`min, max, mean, median, var, sd, sum, prod, first, last, head, tail`) which they called GForce, `?data.table::GForce`.
*collapse* instead provides grouped statistical and transformation functions where all grouped computation is done efficiently in C++, and some supporting mechanisms (`fgroup_by`, `collap`) to operate them. In *data.table* words, everything^[Apart from `collapse::BY` which is only an auxiliary function written in base R to perform flexible split-apply combine computing on vectors, matrices and data frames.] in *collapse*, the *Fast Statistical Functions*, data transformations, time series etc. is GForce optimized.
The full set of optimized grouped statistical and transformation functions in *collapse* is:
```r
.FAST_FUN
# [1] "fmean" "fmedian" "fmode" "fsum" "fprod" "fsd" "fvar"
# [8] "fmin" "fmax" "fnth" "ffirst" "flast" "fnobs" "fndistinct"
# [15] "fcumsum" "fscale" "fbetween" "fwithin" "fhdbetween" "fhdwithin" "flag"
# [22] "fdiff" "fgrowth"
```
Additional optimized grouped functions include `TRA`, `qsu`, `varying`, `fFtest`, `psmat`, `psacf`, `pspacf`, `psccf`.
The nice thing about those GForce (fast) functions provided by *collapse* is that they can be accessed explicitly and programmatically without any overhead as incurred through *data.table*, they cover a broader range of statistical operations (such as mode, distinct values, order statistics), support sampling weights, operate in a class-agnostic way on vectors, matrices, data.frame's and many related classes, and cover transformations (replacing and sweeping, scaling, (higher order) centering, linear fitting) and time series functionality (lags, differences and growth rates, including irregular time series and unbalanced panels).
So if we would want to use `fmean` inside the *data.table*, we should do something like this:
```r
# This does not save the grouping columns, we are simply passing a grouping vector to g
# and aggregating the subset of the data table (.SD).
DT[, fmean(.SD, country), .SDcols = 9:13]
# PCGDP LIFEEX GINI ODA POP
#
# 1: 483.8351 49.19717 NA 1487548499 18362258.22
# 2: 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: 10071.0659 NA NA NA 43115.10
# 5: 40083.0911 NA NA NA 51547.35
# ---
# 212: 35629.7336 73.71292 NA NA 92238.53
# 213: 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: 1219.4360 54.53360 45.93333 397104997 9402160.33
# If we want to keep the grouping columns, we need to group .SD first.
DT[, fmean(gby(.SD, country)), .SDcols = c(1L, 9:13)]
# country PCGDP LIFEEX GINI ODA POP
#
# 1: Afghanistan 483.8351 49.19717 NA 1487548499 18362258.22
# 2: Albania 2819.2400 71.68027 31.41111 312928126 2708297.17
# 3: Algeria 3532.2714 63.56290 34.36667 612238500 25305290.68
# 4: American Samoa 10071.0659 NA NA NA 43115.10
# 5: Andorra 40083.0911 NA NA NA 51547.35
# ---
# 212: Virgin Islands (U.S.) 35629.7336 73.71292 NA NA 92238.53
# 213: West Bank and Gaza 2388.4348 71.60780 34.52500 1638581462 3312289.13
# 214: Yemen, Rep. 1069.6596 52.53707 35.46667 859950996 13741375.82
# 215: Zambia 1318.8627 51.09263 52.68889 734624330 8614972.38
# 216: Zimbabwe 1219.4360 54.53360 45.93333 397104997 9402160.33
```
Needless to say this kind of programming seems a bit arcane, so there is actually not that great of a scope to use collapse's *Fast Statistical Functions* for aggregations inside *data.table*. I drive this point home with a benchmark:
```r
microbenchmark(collapse = DT %>% gby(country) %>% get_vars(9:13) %>% fmean,
data.table = DT[, lapply(.SD, mean, na.rm = TRUE), keyby = country, .SDcols = 9:13],
data.table_base = DT[, lapply(.SD, base::mean, na.rm = TRUE), keyby = country, .SDcols = 9:13],
hybrid_bad = DT[, lapply(.SD, fmean), keyby = country, .SDcols = 9:13],
hybrid_ok = DT[, fmean(gby(.SD, country)), .SDcols = c(1L, 9:13)])
# Unit: microseconds
# expr min lq mean median uq max neval
# collapse 207.419 234.9915 322.3994 255.6760 283.6790 1685.305 100
# data.table 755.630 845.7685 1029.9024 904.6650 962.1060 2409.529 100
# data.table_base 2795.257 3148.4310 4034.2081 3349.8025 3561.9570 37919.916 100
# hybrid_bad 2198.994 2481.3815 3737.1102 2650.5680 2909.4215 62158.747 100
# hybrid_ok 374.699 451.1025 564.6873 484.9275 542.8605 2082.554 100
```
It is evident that *data.table* has some overhead, so there is absolutely no need to do this kind of syntax manipulation.
There is more scope to use *collapse* transformation functions inside *data.table*.
Below some basic examples:
```r
# Computing a column containing the sum of ODA received by country
DT[, sum_ODA := sum(ODA, na.rm = TRUE), by = country]
# Same using fsum; "replace_fill" overwrites missing values, "replace" keeps the
DT[, sum_ODA := fsum(ODA, country, TRA = "replace_fill")]
# Same: A native collapse solution using settransform (or its shortcut form)
settfm(DT, sum_ODA = fsum(ODA, country, TRA = "replace_fill"))
# settfm may be more convenient than `:=` for multiple column modifications,
# each involving a different grouping:
# This computes the percentage of total ODA distributed received by
# each country both over time and within a given year
settfm(DT, perc_c_ODA = fsum(ODA, country, TRA = "%"),
perc_y_ODA = fsum(ODA, year, TRA = "%"))
```
The `TRA` argument is available to all *Fast Statistical Functions* (see the macro `.FAST_STAT_FUN`) and offers 10 different replacing and sweeping operations. Note that `TRA()` can also be called directly to replace or sweep with a previously aggregated *data.table*. A set of operators `%rr%`, `%r+%`, `%r-%`, `%r*%`, `%r/%`, `%cr%`, `%c+%`, `%c-%`, `%c*%`, `%c/%` additionally facilitate row- or column-wise replacing or sweeping out vectors of statistics or other *data.table*'s.
Similarly, we can use the following vector valued functions
```r
setdiff(.FAST_FUN, .FAST_STAT_FUN)
# [1] "fcumsum" "fscale" "fbetween" "fwithin" "fhdbetween" "fhdwithin" "flag"
# [8] "fdiff" "fgrowth"
```
for very efficient data transformations:
```r
# Centering GDP
DT[, demean_PCGDP := PCGDP - mean(PCGDP, na.rm = TRUE), by = country]
DT[, demean_PCGDP := fwithin(PCGDP, country)]
# Lagging GDP
DT[order(year), lag_PCGDP := shift(PCGDP, 1L), by = country]
DT[, lag_PCGDP := flag(PCGDP, 1L, country, year)]
# Computing a growth rate
DT[order(year), growth_PCGDP := (PCGDP / shift(PCGDP, 1L) - 1) * 100, by = country]
DT[, lag_PCGDP := fgrowth(PCGDP, 1L, 1L, country, year)] # 1 lag, 1 iteration
# Several Growth rates
DT[order(year), paste0("growth_", .c(PCGDP, LIFEEX, GINI, ODA)) := (.SD / shift(.SD, 1L) - 1) * 100,
by = country, .SDcols = 9:13]
# Same thing using collapse
DT %<>% tfm(gv(., 9:13) %>% fgrowth(1L, 1L, country, year) %>% add_stub("growth_"))
# Or even simpler using settransform and the Growth operator
settfmv(DT, 9:13, G, 1L, 1L, country, year, apply = FALSE)
head(DT)
# country iso3c date year decade region income OECD PCGDP LIFEEX GINI
#
# 1: Afghanistan AFG 1961-01-01 1960 1960 South Asia Low income FALSE NA 32.446 NA
# 2: Afghanistan AFG 1962-01-01 1961 1960 South Asia Low income FALSE NA 32.962 NA
# 3: Afghanistan AFG 1963-01-01 1962 1960 South Asia Low income FALSE NA 33.471 NA
# 4: Afghanistan AFG 1964-01-01 1963 1960 South Asia Low income FALSE NA 33.971 NA
# 5: Afghanistan AFG 1965-01-01 1964 1960 South Asia Low income FALSE NA 34.463 NA
# 6: Afghanistan AFG 1966-01-01 1965 1960 South Asia Low income FALSE NA 34.948 NA
# ODA POP sum_ODA perc_c_ODA perc_y_ODA demean_PCGDP lag_PCGDP growth_PCGDP
#
# 1: 116769997 8996973 89252909923 0.1308305 0.4441407 NA NA NA
# 2: 232080002 9169410 89252909923 0.2600251 0.7356654 NA NA NA
# 3: 112839996 9351441 89252909923 0.1264272 0.3494956 NA NA NA
# 4: 237720001 9543205 89252909923 0.2663443 0.7003399 NA NA NA
# 5: 295920013 9744781 89252909923 0.3315522 0.8570540 NA NA NA
# 6: 341839996 9956320 89252909923 0.3830015 0.8992630 NA NA NA
# growth_LIFEEX growth_GINI growth_ODA growth_POP G1.PCGDP G1.LIFEEX G1.GINI G1.ODA G1.POP
#
# 1: NA NA NA NA NA NA NA NA NA
# 2: 1.590335 NA 98.74969 1.916611 NA 1.590335 NA 98.74969 1.916611
# 3: 1.544202 NA -51.37884 1.985199 NA 1.544202 NA -51.37884 1.985199
# 4: 1.493830 NA 110.66998 2.050636 NA 1.493830 NA 110.66998 2.050636
# 5: 1.448294 NA 24.48259 2.112246 NA 1.448294 NA 24.48259 2.112246
# 6: 1.407306 NA 15.51770 2.170793 NA 1.407306 NA 15.51770 2.170793
```
Since transformations (`:=` operations) are not highly optimized in *data.table*, *collapse* will be faster in most circumstances. Also time series functionality in *collapse* is significantly faster as it does not require data to be ordered or balanced to compute. For example `flag` computes an ordered lag without sorting the entire data first.
```r
# Lets generate a large dataset and benchmark this stuff
DT_large <- replicate(1000, qDT(wlddev), simplify = FALSE) %>%
lapply(tfm, country = paste(country, rnorm(1))) %>%
rbindlist
# 12.7 million Obs
fdim(DT_large)
# [1] 13176000 13
microbenchmark(
S1 = DT_large[, sum_ODA := sum(ODA, na.rm = TRUE), by = country],
S2 = DT_large[, sum_ODA := fsum(ODA, country, TRA = "replace_fill")],
S3 = settfm(DT_large, sum_ODA = fsum(ODA, country, TRA = "replace_fill")),
W1 = DT_large[, demean_PCGDP := PCGDP - mean(PCGDP, na.rm = TRUE), by = country],
W2 = DT_large[, demean_PCGDP := fwithin(PCGDP, country)],
L1 = DT_large[order(year), lag_PCGDP := shift(PCGDP, 1L), by = country],
L2 = DT_large[, lag_PCGDP := flag(PCGDP, 1L, country, year)],
L3 = DT_large[, lag_PCGDP := shift(PCGDP, 1L), by = country], # Not ordered
L4 = DT_large[, lag_PCGDP := flag(PCGDP, 1L, country)], # Not ordered
times = 5
)
# Unit: milliseconds
# expr min lq mean median uq max neval
# S1 343.03396 347.18443 391.7494 364.51431 379.7866 524.2279 5
# S2 100.52544 101.72645 165.8369 128.76042 153.6818 344.4906 5
# S3 98.48249 104.80830 120.3499 114.20591 127.0192 157.2335 5
# W1 913.00883 1009.29930 1071.0633 1035.74446 1104.7680 1292.4957 5
# W2 99.48199 99.69654 110.0907 113.95884 118.5229 118.7931 5
# L1 1812.59987 1822.58026 1896.8809 1905.67377 1942.9434 2000.6074 5
# L2 110.36056 128.45845 135.0995 133.80219 139.1405 163.7357 5
# L3 611.28392 665.22123 768.0616 718.38679 803.7170 1041.6991 5
# L4 64.26369 66.99006 105.7952 84.26537 106.1809 207.2758 5
rm(DT_large)
gc()
# used (Mb) gc trigger (Mb) limit (Mb) max used (Mb)
# Ncells 3113072 166.3 8413097 449.4 NA 8413097 449.4
# Vcells 7897587 60.3 324289364 2474.2 16384 405361681 3092.7
```
## Further *collapse* features supporting *data.table*'s
As mentioned, `qDT` is a flexible and very fast function to create / column-wise convert R objects to *data.table*'s. You can also row-wise convert a matrix to data.table using `mrtl`:
```r
# Creating a matrix from mtcars
m <- qM(mtcars)
str(m)
# num [1:32, 1:11] 21 21 22.8 21.4 18.7 18.1 14.3 24.4 22.8 19.2 ...
# - attr(*, "dimnames")=List of 2
# ..$ : chr [1:32] "Mazda RX4" "Mazda RX4 Wag" "Datsun 710" "Hornet 4 Drive" ...
# ..$ : chr [1:11] "mpg" "cyl" "disp" "hp" ...
# Demonstrating another nice feature of qDT
qDT(m, row.names.col = "car") %>% head
# car mpg cyl disp hp drat wt qsec vs am gear carb
#
# 1: Mazda RX4 21.0 6 160 110 3.90 2.620 16.46 0 1 4 4
# 2: Mazda RX4 Wag 21.0 6 160 110 3.90 2.875 17.02 0 1 4 4
# 3: Datsun 710 22.8 4 108 93 3.85 2.320 18.61 1 1 4 1
# 4: Hornet 4 Drive 21.4 6 258 110 3.08 3.215 19.44 1 0 3 1
# 5: Hornet Sportabout 18.7 8 360 175 3.15 3.440 17.02 0 0 3 2
# 6: Valiant 18.1 6 225 105 2.76 3.460 20.22 1 0 3 1
# Row-wise conversion to data.table
mrtl(m, names = TRUE, return = "data.table") %>% head(2)
# Mazda RX4 Mazda RX4 Wag Datsun 710 Hornet 4 Drive Hornet Sportabout Valiant Duster 360 Merc 240D
#
# 1: 21 21 22.8 21.4 18.7 18.1 14.3 24.4
# 2: 6 6 4.0 6.0 8.0 6.0 8.0 4.0
# Merc 230 Merc 280 Merc 280C Merc 450SE Merc 450SL Merc 450SLC Cadillac Fleetwood
#
# 1: 22.8 19.2 17.8 16.4 17.3 15.2 10.4
# 2: 4.0 6.0 6.0 8.0 8.0 8.0 8.0
# Lincoln Continental Chrysler Imperial Fiat 128 Honda Civic Toyota Corolla Toyota Corona
#
# 1: 10.4 14.7 32.4 30.4 33.9 21.5
# 2: 8.0 8.0 4.0 4.0 4.0 4.0
# Dodge Challenger AMC Javelin Camaro Z28 Pontiac Firebird Fiat X1-9 Porsche 914-2 Lotus Europa
#
# 1: 15.5 15.2 13.3 19.2 27.3 26 30.4
# 2: 8.0 8.0 8.0 8.0 4.0 4 4.0
# Ford Pantera L Ferrari Dino Maserati Bora Volvo 142E
#
# 1: 15.8 19.7 15 21.4
# 2: 8.0 6.0 8 4.0
```
The computational efficiency of these functions makes them very useful to use in *data.table* based workflows.
```r
# Benchmark
microbenchmark(qDT(m, "car"), mrtl(m, TRUE, "data.table"))
# Unit: microseconds
# expr min lq mean median uq max neval
# qDT(m, "car") 4.838 5.043 6.16230 5.3300 6.437 20.049 100
# mrtl(m, TRUE, "data.table") 3.608 3.854 4.23981 3.9975 4.182 15.908 100
```
For example we could regress the growth rate of GDP per capita on the Growth rate of life expectancy in each country and save results in a *data.table*:
```r
library(lmtest)
wlddev %>% fselect(country, PCGDP, LIFEEX) %>%
# This counts missing values on PCGDP and LIFEEX only
na_omit(cols = -1L) %>%
# This removes countries with less than 20 observations
fsubset(fnobs(PCGDP, country, "replace_fill") > 20L) %>%
qDT %>%
# Run estimations by country using data.table
.[, qDT(coeftest(lm(G(PCGDP) ~ G(LIFEEX))), "Coef"), keyby = country] %>% head
# Key:
# country Coef Estimate Std. Error t value Pr(>|t|)
#
# 1: Albania (Intercept) -3.6146411 2.371885 -1.5239527 0.136023086
# 2: Albania G(LIFEEX) 22.1596308 7.288971 3.0401591 0.004325856
# 3: Algeria (Intercept) 0.5973329 1.740619 0.3431726 0.732731107
# 4: Algeria G(LIFEEX) 0.8412547 1.689221 0.4980134 0.620390703
# 5: Angola (Intercept) -3.3793976 1.540330 -2.1939445 0.034597175
# 6: Angola G(LIFEEX) 4.2362895 1.402380 3.0207852 0.004553260
```
If we only need the coefficients, not the standard errors, we can also use `collapse::flm` together with `mrtl`:
```r
wlddev %>% fselect(country, PCGDP, LIFEEX) %>%
na_omit(cols = -1L) %>%
fsubset(fnobs(PCGDP, country, "replace_fill") > 20L) %>%
qDT %>%
.[, mrtl(flm(fgrowth(PCGDP)[-1L],
cbind(Intercept = 1,
LIFEEX = fgrowth(LIFEEX)[-1L])), TRUE),
keyby = country] %>% head
# Key:
# country Intercept LIFEEX
#
# 1: Albania -3.61464113 22.1596308
# 2: Algeria 0.59733291 0.8412547
# 3: Angola -3.37939760 4.2362895
# 4: Antigua and Barbuda -3.11880717 18.8700870
# 5: Argentina 1.14613567 -0.2896305
# 6: Armenia 0.08178344 11.5523992
```
... which provides a significant speed gain here:
```r
microbenchmark(
A = wlddev %>% fselect(country, PCGDP, LIFEEX) %>%
na_omit(cols = -1L) %>%
fsubset(fnobs(PCGDP, country, "replace_fill") > 20L) %>%
qDT %>%
.[, qDT(coeftest(lm(G(PCGDP) ~ G(LIFEEX))), "Coef"), keyby = country],
B = wlddev %>% fselect(country, PCGDP, LIFEEX) %>%
na_omit(cols = -1L) %>%
fsubset(fnobs(PCGDP, country, "replace_fill") > 20L) %>%
qDT %>%
.[, mrtl(flm(fgrowth(PCGDP)[-1L],
cbind(Intercept = 1,
LIFEEX = fgrowth(LIFEEX)[-1L])), TRUE),
keyby = country]
)
# Unit: milliseconds
# expr min lq mean median uq max neval
# A 58.914253 60.063381 68.770933 60.865217 73.507813 241.594509 100
# B 3.145766 3.293715 3.463643 3.377006 3.503983 5.378995 100
```
Another feature to highlight at this point are *collapse*'s list processing functions, in particular `rsplit`, `rapply2d`, `get_elem` and `unlist2d`. `rsplit` is an efficient recursive generalization of `split`:
```r
DT_list <- rsplit(DT, country + year + PCGDP + LIFEEX ~ region + income)
# Note: rsplit(DT, year + PCGDP + LIFEEX ~ region + income, flatten = TRUE)
# would yield a simple list with interacted categories (like split)
str(DT_list, give.attr = FALSE)
# List of 7
# $ East Asia & Pacific :List of 3
# ..$ High income :Classes 'data.table' and 'data.frame': 793 obs. of 4 variables:
# .. ..$ country: chr [1:793] "Australia" "Australia" "Australia" "Australia" ...
# .. ..$ year : int [1:793] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:793] 19378 19469 19246 20053 21036 ...
# .. ..$ LIFEEX : num [1:793] 70.8 71 70.9 70.9 70.9 ...
# ..$ Lower middle income:Classes 'data.table' and 'data.frame': 793 obs. of 4 variables:
# .. ..$ country: chr [1:793] "Cambodia" "Cambodia" "Cambodia" "Cambodia" ...
# .. ..$ year : int [1:793] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:793] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:793] 41.2 41.4 41.5 41.7 41.9 ...
# ..$ Upper middle income:Classes 'data.table' and 'data.frame': 610 obs. of 4 variables:
# .. ..$ country: chr [1:610] "American Samoa" "American Samoa" "American Samoa" "American Samoa" ...
# .. ..$ year : int [1:610] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:610] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:610] NA NA NA NA NA NA NA NA NA NA ...
# $ Europe & Central Asia :List of 4
# ..$ High income :Classes 'data.table' and 'data.frame': 2257 obs. of 4 variables:
# .. ..$ country: chr [1:2257] "Andorra" "Andorra" "Andorra" "Andorra" ...
# .. ..$ year : int [1:2257] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:2257] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:2257] NA NA NA NA NA NA NA NA NA NA ...
# ..$ Low income :Classes 'data.table' and 'data.frame': 61 obs. of 4 variables:
# .. ..$ country: chr [1:61] "Tajikistan" "Tajikistan" "Tajikistan" "Tajikistan" ...
# .. ..$ year : int [1:61] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:61] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:61] 50.6 50.9 51.2 51.5 51.9 ...
# ..$ Lower middle income:Classes 'data.table' and 'data.frame': 244 obs. of 4 variables:
# .. ..$ country: chr [1:244] "Kyrgyz Republic" "Kyrgyz Republic" "Kyrgyz Republic" "Kyrgyz Republic" ...
# .. ..$ year : int [1:244] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:244] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:244] 56.1 56.6 57 57.4 57.9 ...
# ..$ Upper middle income:Classes 'data.table' and 'data.frame': 976 obs. of 4 variables:
# .. ..$ country: chr [1:976] "Albania" "Albania" "Albania" "Albania" ...
# .. ..$ year : int [1:976] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:976] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:976] 62.3 63.3 64.2 64.9 65.5 ...
# $ Latin America & Caribbean :List of 4
# ..$ High income :Classes 'data.table' and 'data.frame': 1037 obs. of 4 variables:
# .. ..$ country: chr [1:1037] "Antigua and Barbuda" "Antigua and Barbuda" "Antigua and Barbuda" "Antigua and Barbuda" ...
# .. ..$ year : int [1:1037] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:1037] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:1037] 62 62.5 63 63.5 64 ...
# ..$ Low income :Classes 'data.table' and 'data.frame': 61 obs. of 4 variables:
# .. ..$ country: chr [1:61] "Haiti" "Haiti" "Haiti" "Haiti" ...
# .. ..$ year : int [1:61] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:61] 1512 1439 1523 1466 1414 ...
# .. ..$ LIFEEX : num [1:61] 41.8 42.2 42.6 43 43.4 ...
# ..$ Lower middle income:Classes 'data.table' and 'data.frame': 244 obs. of 4 variables:
# .. ..$ country: chr [1:244] "Bolivia" "Bolivia" "Bolivia" "Bolivia" ...
# .. ..$ year : int [1:244] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:244] 1005 1007 1042 1091 1112 ...
# .. ..$ LIFEEX : num [1:244] 41.8 42.1 42.5 42.8 43.2 ...
# ..$ Upper middle income:Classes 'data.table' and 'data.frame': 1220 obs. of 4 variables:
# .. ..$ country: chr [1:1220] "Argentina" "Argentina" "Argentina" "Argentina" ...
# .. ..$ year : int [1:1220] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:1220] 5643 5853 5711 5323 5773 ...
# .. ..$ LIFEEX : num [1:1220] 65.1 65.2 65.3 65.3 65.4 ...
# $ Middle East & North Africa:List of 4
# ..$ High income :Classes 'data.table' and 'data.frame': 488 obs. of 4 variables:
# .. ..$ country: chr [1:488] "Bahrain" "Bahrain" "Bahrain" "Bahrain" ...
# .. ..$ year : int [1:488] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:488] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:488] 51.9 53.2 54.6 55.9 57.2 ...
# ..$ Low income :Classes 'data.table' and 'data.frame': 122 obs. of 4 variables:
# .. ..$ country: chr [1:122] "Syrian Arab Republic" "Syrian Arab Republic" "Syrian Arab Republic" "Syrian Arab Republic" ...
# .. ..$ year : int [1:122] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:122] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:122] 52 52.6 53.2 53.8 54.4 ...
# ..$ Lower middle income:Classes 'data.table' and 'data.frame': 305 obs. of 4 variables:
# .. ..$ country: chr [1:305] "Djibouti" "Djibouti" "Djibouti" "Djibouti" ...
# .. ..$ year : int [1:305] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:305] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:305] 44 44.5 44.9 45.3 45.7 ...
# ..$ Upper middle income:Classes 'data.table' and 'data.frame': 366 obs. of 4 variables:
# .. ..$ country: chr [1:366] "Algeria" "Algeria" "Algeria" "Algeria" ...
# .. ..$ year : int [1:366] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:366] 2481 2091 1638 2146 2214 ...
# .. ..$ LIFEEX : num [1:366] 46.1 46.6 47.1 47.5 48 ...
# $ North America :List of 1
# ..$ High income:Classes 'data.table' and 'data.frame': 183 obs. of 4 variables:
# .. ..$ country: chr [1:183] "Bermuda" "Bermuda" "Bermuda" "Bermuda" ...
# .. ..$ year : int [1:183] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:183] 33363 34080 34763 34324 37202 ...
# .. ..$ LIFEEX : num [1:183] NA NA NA NA NA ...
# $ South Asia :List of 3
# ..$ Low income :Classes 'data.table' and 'data.frame': 122 obs. of 4 variables:
# .. ..$ country: chr [1:122] "Afghanistan" "Afghanistan" "Afghanistan" "Afghanistan" ...
# .. ..$ year : int [1:122] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:122] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:122] 32.4 33 33.5 34 34.5 ...
# ..$ Lower middle income:Classes 'data.table' and 'data.frame': 244 obs. of 4 variables:
# .. ..$ country: chr [1:244] "Bangladesh" "Bangladesh" "Bangladesh" "Bangladesh" ...
# .. ..$ year : int [1:244] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:244] 372 384 394 381 411 ...
# .. ..$ LIFEEX : num [1:244] 45.4 46 46.6 47.1 47.6 ...
# ..$ Upper middle income:Classes 'data.table' and 'data.frame': 122 obs. of 4 variables:
# .. ..$ country: chr [1:122] "Maldives" "Maldives" "Maldives" "Maldives" ...
# .. ..$ year : int [1:122] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:122] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:122] 37.3 37.9 38.6 39.2 39.9 ...
# $ Sub-Saharan Africa :List of 4
# ..$ High income :Classes 'data.table' and 'data.frame': 61 obs. of 4 variables:
# .. ..$ country: chr [1:61] "Seychelles" "Seychelles" "Seychelles" "Seychelles" ...
# .. ..$ year : int [1:61] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:61] 2830 2617 2763 2966 3064 ...
# .. ..$ LIFEEX : num [1:61] NA NA NA NA NA NA NA NA NA NA ...
# ..$ Low income :Classes 'data.table' and 'data.frame': 1464 obs. of 4 variables:
# .. ..$ country: chr [1:1464] "Benin" "Benin" "Benin" "Benin" ...
# .. ..$ year : int [1:1464] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:1464] 712 724 689 710 745 ...
# .. ..$ LIFEEX : num [1:1464] 37.3 37.7 38.2 38.7 39.1 ...
# ..$ Lower middle income:Classes 'data.table' and 'data.frame': 1037 obs. of 4 variables:
# .. ..$ country: chr [1:1037] "Angola" "Angola" "Angola" "Angola" ...
# .. ..$ year : int [1:1037] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:1037] NA NA NA NA NA NA NA NA NA NA ...
# .. ..$ LIFEEX : num [1:1037] 37.5 37.8 38.1 38.4 38.8 ...
# ..$ Upper middle income:Classes 'data.table' and 'data.frame': 366 obs. of 4 variables:
# .. ..$ country: chr [1:366] "Botswana" "Botswana" "Botswana" "Botswana" ...
# .. ..$ year : int [1:366] 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 ...
# .. ..$ PCGDP : num [1:366] 408 425 444 460 480 ...
# .. ..$ LIFEEX : num [1:366] 49.2 49.7 50.2 50.6 51.1 ...
```
We can use `rapply2d` to apply a function to each data frame / data.table in an arbitrary nested structure:
```r
# This runs region-income level regressions, with country fixed effects
# following Mundlak (1978)
lm_summary_list <- DT_list %>%
rapply2d(lm, formula = G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)) %>%
# Summarizing the results
rapply2d(summary, classes = "lm")
# This is a nested list of linear model summaries
str(lm_summary_list, give.attr = FALSE)
# List of 7
# $ East Asia & Pacific :List of 3
# ..$ High income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:441] -1.64 -2.59 2.75 3.45 2.48 ...
# .. ..$ coefficients : num [1:3, 1:4] 0.531 2.494 3.83 0.706 0.759 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 4.59
# .. ..$ df : int [1:3] 3 438 3
# .. ..$ r.squared : num 0.0525
# .. ..$ adj.r.squared: num 0.0481
# .. ..$ fstatistic : Named num [1:3] 12.1 2 438
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.02361 -0.00158 -0.04895 -0.00158 0.02728 ...
# .. ..$ na.action : 'omit' Named int [1:352] 1 61 62 63 64 65 66 67 68 69 ...
# ..$ Lower middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:549] -39.6968 3.6618 -0.0944 -1.8261 -1.0491 ...
# .. ..$ coefficients : num [1:3, 1:4] 1.348 0.524 0.949 0.701 0.757 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 5.4
# .. ..$ df : int [1:3] 3 546 3
# .. ..$ r.squared : num 0.00471
# .. ..$ adj.r.squared: num 0.00106
# .. ..$ fstatistic : Named num [1:3] 1.29 2 546
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.016821 0.000511 -0.022767 0.000511 0.01965 ...
# .. ..$ na.action : 'omit' Named int [1:244] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Upper middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:312] -32.29 -11.61 2.91 11.23 10.28 ...
# .. ..$ coefficients : num [1:3, 1:4] 1.507 -0.547 4.816 0.428 0.478 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 4.39
# .. ..$ df : int [1:3] 3 309 3
# .. ..$ r.squared : num 0.103
# .. ..$ adj.r.squared: num 0.0976
# .. ..$ fstatistic : Named num [1:3] 17.8 2 309
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.009471 0.000492 -0.013551 0.000492 0.011842 ...
# .. ..$ na.action : 'omit' Named int [1:298] 1 2 3 4 5 6 7 8 9 10 ...
# $ Europe & Central Asia :List of 4
# ..$ High income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:1355] 2.706 -0.548 1.001 3.034 0.257 ...
# .. ..$ coefficients : num [1:3, 1:4] 3.254 -0.172 -2.506 0.407 0.227 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 3.3
# .. ..$ df : int [1:3] 3 1352 3
# .. ..$ r.squared : num 0.00257
# .. ..$ adj.r.squared: num 0.00109
# .. ..$ fstatistic : Named num [1:3] 1.74 2 1352
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.015254 -0.000863 -0.05461 -0.000863 0.004722 ...
# .. ..$ na.action : 'omit' Named int [1:902] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Low income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:34] 0.166 -1.804 15.949 -0.778 7.165 ...
# .. ..$ coefficients : num [1:2, 1:4] -5.31 9.36 2.03 2.56 -2.61 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE TRUE
# .. ..$ sigma : num 8.43
# .. ..$ df : int [1:3] 2 32 3
# .. ..$ r.squared : num 0.295
# .. ..$ adj.r.squared: num 0.273
# .. ..$ fstatistic : Named num [1:3] 13.4 1 32
# .. ..$ cov.unscaled : num [1:2, 1:2] 0.0582 -0.0514 -0.0514 0.092
# .. ..$ na.action : 'omit' Named int [1:27] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Lower middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:121] -1.626 8.745 -14.47 0.298 -11.886 ...
# .. ..$ coefficients : num [1:3, 1:4] 0.106 4.631 1.499 1.315 0.938 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 6.02
# .. ..$ df : int [1:3] 3 118 3
# .. ..$ r.squared : num 0.178
# .. ..$ adj.r.squared: num 0.164
# .. ..$ fstatistic : Named num [1:3] 12.7 2 118
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.047775 -0.000927 -0.142782 -0.000927 0.024298 ...
# .. ..$ na.action : 'omit' Named int [1:123] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Upper middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:511] 0.761 -2.153 -4.091 -6.476 -3.43 ...
# .. ..$ coefficients : num [1:3, 1:4] 2.983 4.147 -3.351 0.698 0.779 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 8.28
# .. ..$ df : int [1:3] 3 508 3
# .. ..$ r.squared : num 0.0531
# .. ..$ adj.r.squared: num 0.0493
# .. ..$ fstatistic : Named num [1:3] 14.2 2 508
# .. ..$ cov.unscaled : num [1:3, 1:3] 7.11e-03 4.52e-05 -1.45e-02 4.52e-05 8.85e-03 ...
# .. ..$ na.action : 'omit' Named int [1:465] 1 2 3 4 5 6 7 8 9 10 ...
# $ Latin America & Caribbean :List of 4
# ..$ High income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:487] 2.39 6.02 6.1 1.71 -2.27 ...
# .. ..$ coefficients : num [1:3, 1:4] 1.015 0.483 2.613 0.677 0.952 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 4.71
# .. ..$ df : int [1:3] 3 484 3
# .. ..$ r.squared : num 0.00592
# .. ..$ adj.r.squared: num 0.00181
# .. ..$ fstatistic : Named num [1:3] 1.44 2 484
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.02062 0.00155 -0.05714 0.00155 0.04082 ...
# .. ..$ na.action : 'omit' Named int [1:550] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Low income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:59] -5.667 5.091 -4.46 -4.224 -0.526 ...
# .. ..$ coefficients : num [1:2, 1:4] -3.18 4.02 1.73 2.28 -1.83 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE TRUE
# .. ..$ sigma : num 3.79
# .. ..$ df : int [1:3] 2 57 3
# .. ..$ r.squared : num 0.0516
# .. ..$ adj.r.squared: num 0.0349
# .. ..$ fstatistic : Named num [1:3] 3.1 1 57
# .. ..$ cov.unscaled : num [1:2, 1:2] 0.209 -0.265 -0.265 0.364
# .. ..$ na.action : 'omit' Named int [1:2] 1 61
# ..$ Lower middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:231] -1.386 2.029 3.213 0.413 1.334 ...
# .. ..$ coefficients : num [1:3, 1:4] -1.678 -0.479 3.896 2.26 0.709 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 3.96
# .. ..$ df : int [1:3] 3 228 3
# .. ..$ r.squared : num 0.0081
# .. ..$ adj.r.squared: num -0.000602
# .. ..$ fstatistic : Named num [1:3] 0.931 2 228
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.3264 0.005 -0.4084 0.005 0.0321 ...
# .. ..$ na.action : 'omit' Named int [1:13] 1 61 62 63 64 65 66 67 122 123 ...
# ..$ Upper middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:1065] 1.97 -4.16 -8.5 6.72 7.17 ...
# .. ..$ coefficients : num [1:3, 1:4] 1.681 0.583 -0.124 0.353 0.512 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 4.22
# .. ..$ df : int [1:3] 3 1062 3
# .. ..$ r.squared : num 0.0016
# .. ..$ adj.r.squared: num -0.000283
# .. ..$ fstatistic : Named num [1:3] 0.85 2 1062
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.006982 0.000348 -0.013936 0.000348 0.014734 ...
# .. ..$ na.action : 'omit' Named int [1:155] 1 61 62 122 123 183 184 244 245 305 ...
# $ Middle East & North Africa:List of 4
# ..$ High income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:334] -10.728 -11.988 2.151 0.985 -8.618 ...
# .. ..$ coefficients : num [1:3, 1:4] 1.929 3.963 -3.533 1.102 0.996 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 8.36
# .. ..$ df : int [1:3] 3 331 3
# .. ..$ r.squared : num 0.0456
# .. ..$ adj.r.squared: num 0.0399
# .. ..$ fstatistic : Named num [1:3] 7.91 2 331
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.01738 0.00101 -0.02441 0.00101 0.01419 ...
# .. ..$ na.action : 'omit' Named int [1:154] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Low income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:29] 0.468 3.424 0.415 3.842 3.342 ...
# .. ..$ coefficients : num [1:2, 1:4] -6.91 11.38 2.11 3.64 -3.27 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE TRUE
# .. ..$ sigma : num 6.05
# .. ..$ df : int [1:3] 2 27 3
# .. ..$ r.squared : num 0.266
# .. ..$ adj.r.squared: num 0.239
# .. ..$ fstatistic : Named num [1:3] 9.81 1 27
# .. ..$ cov.unscaled : num [1:2, 1:2] 0.122 -0.178 -0.178 0.361
# .. ..$ na.action : 'omit' Named int [1:93] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Lower middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:191] -0.95 -2.047 4.541 5.594 -0.723 ...
# .. ..$ coefficients : num [1:3, 1:4] 2.238 1.271 -0.647 1.002 0.599 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 3.94
# .. ..$ df : int [1:3] 3 188 3
# .. ..$ r.squared : num 0.0244
# .. ..$ adj.r.squared: num 0.014
# .. ..$ fstatistic : Named num [1:3] 2.35 2 188
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.06471 -0.00043 -0.07801 -0.00043 0.02309 ...
# .. ..$ na.action : 'omit' Named int [1:114] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Upper middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:263] -18.068 -23.976 28.692 0.858 1.141 ...
# .. ..$ coefficients : num [1:3, 1:4] 2.663 0.718 -1.19 3.538 1.318 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 13.8
# .. ..$ df : int [1:3] 3 260 3
# .. ..$ r.squared : num 0.00119
# .. ..$ adj.r.squared: num -0.00649
# .. ..$ fstatistic : Named num [1:3] 0.155 2 260
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.065741 0.000795 -0.084456 0.000795 0.009122 ...
# .. ..$ na.action : 'omit' Named int [1:103] 1 61 62 122 123 124 125 126 127 128 ...
# $ North America :List of 1
# ..$ High income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:137] 4.6986 -3.1098 1.8243 0.5643 0.0176 ...
# .. ..$ coefficients : num [1:3, 1:4] 6.542 -1.461 -19.53 2.272 0.662 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 2.49
# .. ..$ df : int [1:3] 3 134 3
# .. ..$ r.squared : num 0.0657
# .. ..$ adj.r.squared: num 0.0518
# .. ..$ fstatistic : Named num [1:3] 4.71 2 134
# .. ..$ cov.unscaled : num [1:3, 1:3] 8.36e-01 1.59e-17 -3.60 1.59e-17 7.10e-02 ...
# .. ..$ na.action : 'omit' Named int [1:46] 1 2 3 4 5 6 7 8 9 10 ...
# $ South Asia :List of 3
# ..$ Low income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:76] 0.544 -6.17 3.951 -0.964 7.829 ...
# .. ..$ coefficients : num [1:3, 1:4] -108.62 -1.72 96.06 174.19 1.25 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 3.7
# .. ..$ df : int [1:3] 3 73 3
# .. ..$ r.squared : num 0.0494
# .. ..$ adj.r.squared: num 0.0233
# .. ..$ fstatistic : Named num [1:3] 1.9 2 73
# .. ..$ cov.unscaled : num [1:3, 1:3] 2210.639 -6.979 -1875.261 -6.979 0.114 ...
# .. ..$ na.action : 'omit' Named int [1:46] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Lower middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:216] 0.294 -0.293 -6.067 4.954 -4.164 ...
# .. ..$ coefficients : num [1:3, 1:4] -2.232 0.238 5.972 1.074 0.493 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 3.44
# .. ..$ df : int [1:3] 3 213 3
# .. ..$ r.squared : num 0.111
# .. ..$ adj.r.squared: num 0.103
# .. ..$ fstatistic : Named num [1:3] 13.3 2 213
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.09757 -0.00201 -0.10483 -0.00201 0.02054 ...
# .. ..$ na.action : 'omit' Named int [1:28] 1 61 62 63 64 65 66 67 68 69 ...
# ..$ Upper middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:82] 3.262 3.976 3.128 1.67 -0.901 ...
# .. ..$ coefficients : num [1:3, 1:4] 3.859 -0.577 -0.476 1.036 1.365 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 4.25
# .. ..$ df : int [1:3] 3 79 3
# .. ..$ r.squared : num 0.00622
# .. ..$ adj.r.squared: num -0.0189
# .. ..$ fstatistic : Named num [1:3] 0.247 2 79
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.0595 -0.028 -0.0473 -0.028 0.1034 ...
# .. ..$ na.action : 'omit' Named int [1:40] 1 2 3 4 5 6 7 8 9 10 ...
# $ Sub-Saharan Africa :List of 4
# ..$ High income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:39] -11.33 -5.041 -3.158 0.585 7.81 ...
# .. ..$ coefficients : num [1:2, 1:4] 2.551 -0.644 0.775 0.55 3.293 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE TRUE
# .. ..$ sigma : num 4.8
# .. ..$ df : int [1:3] 2 37 3
# .. ..$ r.squared : num 0.0357
# .. ..$ adj.r.squared: num 0.00959
# .. ..$ fstatistic : Named num [1:3] 1.37 1 37
# .. ..$ cov.unscaled : num [1:2, 1:2] 0.026 -0.00217 -0.00217 0.01312
# .. ..$ na.action : 'omit' Named int [1:22] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Low income :List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:1085] 0.694 -5.869 2.069 3.855 2.415 ...
# .. ..$ coefficients : num [1:3, 1:4] -0.0756 0.5308 0.5124 0.8887 0.137 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 5.88
# .. ..$ df : int [1:3] 3 1082 3
# .. ..$ r.squared : num 0.0146
# .. ..$ adj.r.squared: num 0.0128
# .. ..$ fstatistic : Named num [1:3] 8.01 2 1082
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.022858 -0.000025 -0.025534 -0.000025 0.000543 ...
# .. ..$ na.action : 'omit' Named int [1:379] 1 61 62 122 123 183 184 244 245 305 ...
# ..$ Lower middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:891] -8.2839 -4.0289 0.0449 1.8231 -0.5267 ...
# .. ..$ coefficients : num [1:3, 1:4] 2.352 0.782 -2.616 0.608 0.169 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 5.27
# .. ..$ df : int [1:3] 3 888 3
# .. ..$ r.squared : num 0.0277
# .. ..$ adj.r.squared: num 0.0255
# .. ..$ fstatistic : Named num [1:3] 12.7 2 888
# .. ..$ cov.unscaled : num [1:3, 1:3] 1.33e-02 -1.13e-05 -2.00e-02 -1.13e-05 1.02e-03 ...
# .. ..$ na.action : 'omit' Named int [1:146] 1 2 3 4 5 6 7 8 9 10 ...
# ..$ Upper middle income:List of 12
# .. ..$ call : language FUN(formula = ..1, data = y)
# .. ..$ terms :Classes 'terms', 'formula' language G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country)
# .. ..$ residuals : Named num [1:298] 0.7659 0.9133 0.0921 0.996 0.0765 ...
# .. ..$ coefficients : num [1:3, 1:4] 0.584 0.456 4.112 2.472 0.652 ...
# .. ..$ aliased : Named logi [1:3] FALSE FALSE FALSE
# .. ..$ sigma : num 11.4
# .. ..$ df : int [1:3] 3 295 3
# .. ..$ r.squared : num 0.00658
# .. ..$ adj.r.squared: num -0.000152
# .. ..$ fstatistic : Named num [1:3] 0.977 2 295
# .. ..$ cov.unscaled : num [1:3, 1:3] 0.047213 0.000438 -0.070778 0.000438 0.003285 ...
# .. ..$ na.action : 'omit' Named int [1:68] 1 61 62 63 64 65 66 67 68 69 ...
```
We can turn this list into a *data.table* again by calling first `get_elem` to recursively extract the coefficient matrices and then `unlist2d` to recursively bind them to a new *data.table*:
```r
lm_summary_list %>%
get_elem("coefficients") %>%
unlist2d(idcols = .c(Region, Income),
row.names = "Coef",
DT = TRUE) %>% head
# Region Income Coef Estimate Std. Error t value
#
# 1: East Asia & Pacific High income (Intercept) 0.5313479 0.7058550 0.7527720
# 2: East Asia & Pacific High income G(LIFEEX) 2.4935584 0.7586943 3.2866443
# 3: East Asia & Pacific High income B(G(LIFEEX), country) 3.8297123 1.6916770 2.2638554
# 4: East Asia & Pacific Lower middle income (Intercept) 1.3476602 0.7008556 1.9228785
# 5: East Asia & Pacific Lower middle income G(LIFEEX) 0.5238856 0.7574904 0.6916069
# 6: East Asia & Pacific Lower middle income B(G(LIFEEX), country) 0.9494439 1.2031228 0.7891496
# Pr(>|t|)
#
# 1: 0.451991327
# 2: 0.001095466
# 3: 0.024071386
# 4: 0.055015131
# 5: 0.489478164
# 6: 0.430367103
```
The fact that this is a nested list of matrices, and that we can save both the names of the lists at each level of nesting and the row- and column- names of the matrices make `unlist2d` a significant generalization of `rbindlist`^[`unlist2d` can similarly bind nested lists of arrays, data frames or *data.table*'s].
But why do all this fuzz if we could have simply done:?
```r
DT[, qDT(coeftest(lm(G(PCGDP) ~ G(LIFEEX) + B(G(LIFEEX), country))), "Coef"),
keyby = .(region, income)] %>% head
# Key:
# region income Coef Estimate Std. Error t value
#
# 1: East Asia & Pacific High income (Intercept) 0.5313479 0.7058550 0.7527720
# 2: East Asia & Pacific High income G(LIFEEX) 2.4935584 0.7586943 3.2866443
# 3: East Asia & Pacific High income B(G(LIFEEX), country) 3.8297123 1.6916770 2.2638554
# 4: East Asia & Pacific Lower middle income (Intercept) 1.3476602 0.7008556 1.9228785
# 5: East Asia & Pacific Lower middle income G(LIFEEX) 0.5238856 0.7574904 0.6916069
# 6: East Asia & Pacific Lower middle income B(G(LIFEEX), country) 0.9494439 1.2031228 0.7891496
# Pr(>|t|)
#
# 1: 0.451991327
# 2: 0.001095466
# 3: 0.024071386
# 4: 0.055015131
# 5: 0.489478164
# 6: 0.430367103
```
Well we might want to do more things with that list of linear models first before tidying it, so this is a more general workflow. We might also be interested in additional statistics like the R-squared or the F-statistic:
```r
DT_sum <- lm_summary_list %>%
get_elem("coef|r.sq|fstat", regex = TRUE) %>%
unlist2d(idcols = .c(Region, Income, Statistic),
row.names = "Coef",
DT = TRUE)
head(DT_sum)
# Region Income Statistic Coef Estimate Std. Error
#
# 1: East Asia & Pacific High income coefficients (Intercept) 0.5313479 0.7058550
# 2: East Asia & Pacific High income coefficients G(LIFEEX) 2.4935584 0.7586943
# 3: East Asia & Pacific High income coefficients B(G(LIFEEX), country) 3.8297123 1.6916770
# 4: East Asia & Pacific High income r.squared NA NA
# 5: East Asia & Pacific High income adj.r.squared NA NA
# 6: East Asia & Pacific High income fstatistic NA NA
# t value Pr(>|t|) V1 value numdf dendf
#
# 1: 0.752772 0.451991327 NA NA NA NA
# 2: 3.286644 0.001095466 NA NA NA NA
# 3: 2.263855 0.024071386 NA NA NA NA
# 4: NA NA 0.05245359 NA NA NA
# 5: NA NA 0.04812690 NA NA NA
# 6: NA NA NA 12.12325 2 438
# Reshaping to long form:
DT_sum %>%
melt(1:4, na.rm = TRUE) %>%
roworderv(1:2) %>% head(20)
# Region Income Statistic Coef variable
#
# 1: East Asia & Pacific High income coefficients (Intercept) Estimate
# 2: East Asia & Pacific High income coefficients G(LIFEEX) Estimate
# 3: East Asia & Pacific High income coefficients B(G(LIFEEX), country) Estimate
# 4: East Asia & Pacific High income coefficients (Intercept) Std. Error
# 5: East Asia & Pacific High income coefficients G(LIFEEX) Std. Error
# 6: East Asia & Pacific High income coefficients B(G(LIFEEX), country) Std. Error
# 7: East Asia & Pacific High income coefficients (Intercept) t value
# 8: East Asia & Pacific High income coefficients G(LIFEEX) t value
# 9: East Asia & Pacific High income coefficients B(G(LIFEEX), country) t value
# 10: East Asia & Pacific High income coefficients (Intercept) Pr(>|t|)
# 11: East Asia & Pacific High income coefficients G(LIFEEX) Pr(>|t|)
# 12: East Asia & Pacific High income coefficients B(G(LIFEEX), country) Pr(>|t|)
# 13: East Asia & Pacific High income r.squared V1
# 14: East Asia & Pacific High income adj.r.squared V1
# 15: East Asia & Pacific High income fstatistic value
# 16: East Asia & Pacific High income fstatistic numdf
# 17: East Asia & Pacific High income fstatistic dendf
# 18: East Asia & Pacific Lower middle income coefficients (Intercept) Estimate
# 19: East Asia & Pacific Lower middle income coefficients G(LIFEEX) Estimate
# 20: East Asia & Pacific Lower middle income coefficients B(G(LIFEEX), country) Estimate
# Region Income Statistic Coef variable
# value
#
# 1: 5.313479e-01
# 2: 2.493558e+00
# 3: 3.829712e+00
# 4: 7.058550e-01
# 5: 7.586943e-01
# 6: 1.691677e+00
# 7: 7.527720e-01
# 8: 3.286644e+00
# 9: 2.263855e+00
# 10: 4.519913e-01
# 11: 1.095466e-03
# 12: 2.407139e-02
# 13: 5.245359e-02
# 14: 4.812690e-02
# 15: 1.212325e+01
# 16: 2.000000e+00
# 17: 4.380000e+02
# 18: 1.347660e+00
# 19: 5.238856e-01
# 20: 9.494439e-01
# value
```
As a final example of this kind, lets suppose we are interested in the within-country correlations of all these variables by region and income group:
```r
DT[, qDT(pwcor(W(.SD, country)), "Variable"),
keyby = .(region, income), .SDcols = PCGDP:ODA] %>% head
# Key:
# region income Variable W.PCGDP W.LIFEEX W.GINI W.ODA
#
# 1: East Asia & Pacific High income W.PCGDP 1.0000000 0.7562668 0.6253844 -0.25258496
# 2: East Asia & Pacific High income W.LIFEEX 0.7562668 1.0000000 0.3191255 -0.33611662
# 3: East Asia & Pacific High income W.GINI 0.6253844 0.3191255 1.0000000 NA
# 4: East Asia & Pacific High income W.ODA -0.2525850 -0.3361166 NA 1.00000000
# 5: East Asia & Pacific Lower middle income W.PCGDP 1.0000000 0.4685618 0.4428879 -0.02508852
# 6: East Asia & Pacific Lower middle income W.LIFEEX 0.4685618 1.0000000 0.3231520 0.09356733
```
In summary: The list processing features, statistical capabilities and efficient converters of *collapse* and the flexibility of *data.table* work well together, facilitating more complex workflows.
## Additional Benchmarks
See [here]() or [here]().
These are all run on a 2 core laptop, so I honestly don't know how *collapse* scales on powerful multi-core machines. My own limited computational resources are part of the reason I did not opt for a thread-parallel package from the start. But a multi-core version of *collapse* will eventually be released, maybe by end of 2021.
## References
Mundlak, Yair. 1978. βOn the Pooling of Time Series and Cross Section Data.β *Econometrica* 46 (1): 69β85.