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rquery
rquery
is a piped query generator based on Codd’s
relational algebra (updated to reflect lessons learned from working
with R
, SQL
, and dplyr
at big data scale in production).
rquery
is a data wrangling system designed to express complex data manipulation
as a series of simple data transforms. This is in the spirit of
R
’s base::transform()
, or dplyr
’s
dplyr::mutate()
and uses a pipe in the style popularized in
R
with magrittr
. The operators themselves
follow the selections in Codd’s relational algebra, with the addition of
the traditional SQL
“window functions.” More on the
background and context of rquery
can be found here.
The R
/rquery
version of this introduction
is here,
and the Python
/data_algebra
version of this
introduction is here.
In transform formulations data manipulation is written as
transformations that produce new data.frame
s, instead of as
alterations of a primary data structure (as is the case with
data.table
). Transform system can use more space
and time than in-place methods. However, in our opinion, transform
systems have a number of pedagogical advantages.
In rquery
’s case the primary set of data operators is as
follows:
drop_columns
select_columns
rename_columns
select_rows
order_rows
extend
project
natural_join
convert_records
(supplied by the cdata
package).These operations break into a small number of themes:
data.frame
s.cdata
package).The point is: Codd worked out that a great number of data
transformations can be decomposed into a small number of the above
steps. rquery
supplies a high performance implementation of
these methods that scales from in-memory scale up through big data scale
(to just about anything that supplies a sufficiently powerful
SQL
interface, such as PostgreSQL, Apache Spark, or Google
BigQuery).
We will work through simple examples/demonstrations of the
rquery
data manipulation operators.
rquery
operatorsThe simple column operations are as follows.
drop_columns
select_columns
rename_columns
These operations are easy to demonstrate.
We set up some simple data.
<- data.frame(
d x = c(1, 1, 2),
y = c(5, 4, 3),
z = c(6, 7, 8)
)
::kable(d) knitr
x | y | z |
---|---|---|
1 | 5 | 6 |
1 | 4 | 7 |
2 | 3 | 8 |
For example: drop_columns
works as follows.
drop_columns
creates a new data.frame
without
certain columns.
library(rquery)
## Loading required package: wrapr
library(rqdatatable)
drop_columns(d, c('y', 'z'))
## x
## 1 1
## 2 1
## 3 2
In all cases the first argument of a rquery
operator is
either the data to be processed, or an earlier rquery
pipeline to be extended. We will take about composing
rquery
operations after we work through examples of all of
the basic operations.
We can write the above in piped notation (using the wrapr
pipe in this case):
%.>%
d drop_columns(., c('y', 'z')) %.>%
::kable(.) knitr
x |
---|
1 |
1 |
2 |
Notice the first argument is an explicit “dot” in wrapr
pipe notation.
select_columns
’s action is also obvious from
example.
%.>%
d select_columns(., c('x', 'y')) %.>%
::kable(.) knitr
x | y |
---|---|
1 | 5 |
1 | 4 |
2 | 3 |
rename_columns
is given as name-assignments of the form
'new_name' = 'old_name'
:
%.>%
d rename_columns(.,
c('x_new_name' = 'x',
'y_new_name' = 'y')
%.>%
) ::kable(.) knitr
x_new_name | y_new_name | z |
---|---|---|
1 | 5 | 6 |
1 | 4 | 7 |
2 | 3 | 8 |
The simple row operations are:
select_rows
order_rows
select_rows
keeps the set of rows that meet a given
predicate expression.
%.>%
d select_rows(., x == 1) %.>%
::kable(.) knitr
x | y | z |
---|---|---|
1 | 5 | 6 |
1 | 4 | 7 |
Notes on how to use a variable to specify column names in
select_rows
can be found here.
order_rows
re-orders rows by a selection of column names
(and allows reverse ordering by naming which columns to reverse in the
optional reverse
argument). Multiple columns can be
selected in the order, each column breaking ties in the earlier
comparisons.
%.>%
d order_rows(.,
c('x', 'y'),
reverse = 'x') %.>%
::kable(.) knitr
x | y | z |
---|---|---|
2 | 3 | 8 |
1 | 4 | 7 |
1 | 5 | 6 |
General rquery
operations do not depend on row-order and
are not guaranteed to preserve row-order, so if you do want to order
rows you should make it the last step of your pipeline.
The important create or replace column operation is:
extend
extend
accepts arbitrary expressions to create new
columns (or replace existing ones). For example:
%.>%
d extend(., zzz := y / x) %.>%
::kable(.) knitr
x | y | z | zzz |
---|---|---|---|
1 | 5 | 6 | 5.0 |
1 | 4 | 7 | 4.0 |
2 | 3 | 8 | 1.5 |
We can use =
or :=
for column assignment.
In these examples we will use :=
to keep column assignment
clearly distinguishable from argument binding.
extend
allows for very powerful per-group operations
akin to what SQL
calls “window
functions”. When the optional partitionby
argument is
set to a vector of column names then aggregate calculations can be
performed per-group. For example.
<- data.table::shift
shift
%.>%
d extend(.,
max_y := max(y),
shift_z := shift(z),
row_number := row_number(),
cumsum_z := cumsum(z),
partitionby = 'x',
orderby = c('y', 'z')) %.>%
::kable(.) knitr
x | y | z | max_y | shift_z | row_number | cumsum_z |
---|---|---|---|---|---|---|
1 | 4 | 7 | 5 | NA | 1 | 7 |
1 | 5 | 6 | 5 | 7 | 2 | 13 |
2 | 3 | 8 | 3 | NA | 1 | 8 |
Notice the aggregates were performed per-partition (a set of rows
with matching partition key values, specified by
partitionby
) and in the order determined by the
orderby
argument (without the orderby
argument
order is not guaranteed, so always set orderby
for windowed
operations that depend on row order!).
More on the window functions can be found here.
Notes on how to use a variable to specify column names in
extend
can be found here.
The main aggregation method for rquery
is:
project
project
performs per-group calculations, and returns
only the grouping columns (specified by groupby
) and
derived aggregates. For example:
%.>%
d project(.,
max_y := max(y),
count := n(),
groupby = 'x') %.>%
::kable(.) knitr
x | max_y | count |
---|---|---|
1 | 5 | 2 |
2 | 3 | 1 |
Notice we only get one row for each unique combination of the
grouping variables. We can also aggregate into a single row by not
specifying any groupby
columns.
%.>%
d project(.,
max_y := max(y),
count := n()) %.>%
::kable(.) knitr
max_y | count |
---|---|
5 | 3 |
Notes on how to use a variable to specify column names in
project
can be found here.
data.frame
sTo combine multiple tables in rquery
one uses what we
call the natural_join
operator. In the rquery
natural_join
, rows are matched by column keys and any two
columns with the same name are coalesced (meaning the first
table with a non-missing values supplies the answer). This is easiest to
demonstrate with an example.
Let’s set up new example tables.
<- data.frame(
d_left k = c('a', 'a', 'b'),
x = c(1, NA, 3),
y = c(1, NA, NA),
stringsAsFactors = FALSE
)
::kable(d_left) knitr
k | x | y |
---|---|---|
a | 1 | 1 |
a | NA | NA |
b | 3 | NA |
<- data.frame(
d_right k = c('a', 'b', 'q'),
y = c(10, 20, 30),
stringsAsFactors = FALSE
)
::kable(d_right) knitr
k | y |
---|---|
a | 10 |
b | 20 |
q | 30 |
To perform a join we specify which set of columns our our
row-matching conditions (using the by
argument) and what
type of join we want (using the jointype
argument). For
example we can use jointype = 'LEFT'
to augment our
d_left
table with additional values from
d_right
.
natural_join(d_left, d_right,
by = 'k',
jointype = 'LEFT') %.>%
::kable(.) knitr
k | x | y |
---|---|---|
a | 1 | 1 |
a | NA | 10 |
b | 3 | 20 |
In a left-join (as above) if the right-table has unique keys then we get a table with the same structure as the left-table- but with more information per row. This is a very useful type of join in data science projects. Notice columns with matching names are coalesced into each other, which we interpret as “take the value from the left table, unless it is missing.”
Record transformation is “simple once you get it”. However, we suggest reading up on that as a separate topic here.
We could, of course, perform complicated data manipulation by
sequencing rquery
operations. For example to select one row
with minimal y
per-x
group we could work in
steps as follows.
<- d
. <- extend(.,
. row_number := row_number(),
partitionby = 'x',
orderby = c('y', 'z'))
<- select_rows(.,
. == 1)
row_number <- drop_columns(.,
. "row_number")
::kable(.) knitr
x | y | z |
---|---|---|
1 | 4 | 7 |
2 | 3 | 8 |
The above discipline has the advantage that it is easy to debug, as we can run line by line and inspect intermediate values. We can even use the Bizarro pipe to make this look like a pipeline of operations.
->.;
d extend(.,
row_number := row_number(),
partitionby = 'x',
orderby = c('y', 'z')) ->.;
select_rows(.,
== 1) ->.;
row_number drop_columns(.,
"row_number") ->.;
::kable(.) knitr
x | y | z |
---|---|---|
1 | 4 | 7 |
2 | 3 | 8 |
Or we can use the wrapr
pipe on the data, which we call “immediate mode” (for more on modes
please see here).
%.>%
d extend(.,
row_number := row_number(),
partitionby = 'x',
orderby = c('y', 'z')) %.>%
select_rows(.,
== 1) %.>%
row_number drop_columns(.,
"row_number") %.>%
::kable(.) knitr
x | y | z |
---|---|---|
1 | 4 | 7 |
2 | 3 | 8 |
rquery
operators can also act on rquery
pipelines instead of acting on data. We can write our operations as
follows:
<- local_td(d) %.>%
ops extend(.,
row_number := row_number(),
partitionby = 'x',
orderby = c('y', 'z')) %.>%
select_rows(.,
== 1) %.>%
row_number drop_columns(.,
"row_number")
cat(format(ops))
## mk_td("d", c(
## "x",
## "y",
## "z")) %.>%
## extend(.,
## row_number := row_number(),
## partitionby = c('x'),
## orderby = c('y', 'z'),
## reverse = c()) %.>%
## select_rows(.,
## row_number == 1) %.>%
## drop_columns(.,
## c('row_number'))
And we can re-use this pipeline, both on local data and to generate
SQL
to be run in remote databases. Applying this operator
pipeline to our data.frame
d
is performed as
follows.
%.>%
d %.>%
ops ::kable(.) knitr
x | y | z |
---|---|---|
1 | 4 | 7 |
2 | 3 | 8 |
And for SQL
we have the following.
<- DBI::dbConnect(RSQLite::SQLite(), ":memory:")
raw_connection ::initExtension(raw_connection)
RSQLite<- rquery_db_info(
db connection = raw_connection,
is_dbi = TRUE,
connection_options = rq_connection_tests(raw_connection))
cat(to_sql(ops, db))
## SELECT
## `x`,
## `y`,
## `z`
## FROM (
## SELECT * FROM (
## SELECT
## `x`,
## `y`,
## `z`,
## row_number ( ) OVER ( PARTITION BY `x` ORDER BY `y`, `z` ) AS `row_number`
## FROM (
## SELECT
## `x`,
## `y`,
## `z`
## FROM
## `d`
## ) tsql_87263209472242564970_0000000000
## ) tsql_87263209472242564970_0000000001
## WHERE `row_number` = 1
## ) tsql_87263209472242564970_0000000002
# clean up
::dbDisconnect(raw_connection) DBI
For more SQL
examples, please see here.
What we are trying to illustrate above: there is a continuum of notations possible between:
Being able to see these as all related gives some flexibility in decomposing problems into solutions. We have some more advanced notes on the differences in working modalities here and here.
rquery
supplies a very teachable grammar of data
manipulation based on Codd’s relational algebra and experience with
pipelined data transforms (such as base::transform()
,
dplyr
, and data.table
).
For in-memory situations rquery
uses
data.table
as the implementation provider (through the
small adapter package rqdatatable
) and is routinely faster
than any other R
data manipulation system except
data.table
itself.
For bigger than memory situations rquery
can translate
to any sufficiently powerful SQL
dialect, allowing
rquery
pipelines to be executed on PostgreSQL, Apache
Spark, or Google BigQuery.
In addition the data_algebra
Python package supplies a nearly identical system for working with data
in Python. # Background
There are many prior relational algebra inspired specialized query languages. Just a few include:
Alpha
~1971.ISBL
/ Information system based language ~1973QUEL
~1974.IBM System R
~1974.SQL
~1974.Tutorial D
~1994.data.table
~2006.LINQ
~2007.pandas
~2008.dplyr
~2014.Apache Calcite
~2014.rquery
is realized as a thin translation to an
underlying SQL
provider. We are trying to put the Codd
relational operators front and center (using the original naming, and
back-porting SQL
progress such as window functions to the
appropriate relational operator).
Some related work includes:
data.table
disk.frame
dbplyr
dplyr
dtplyr
maditr
nc
poorman
rqdatatable
SparkR
sparklyr
sqldf
table.express
tidyfast
tidyfst
tidyquery
tidyr
tidytable
(formerly gdt
/tidydt
)data_algebra
To install rquery
please try
install.packages("rquery")
.
rquery
is intended to work with “tame column names”,
that is column names that are legitimate symbols in R
and
SQL
.
The previous rquery
introduction is available here.
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.