SQLDataFrame 1.2.0
last edit: 10/7/2019
SQL database are very commonly used in the storage of very large
genomic data resources. Many useful tools, such as DBI, dbplyr
have provided convenient interfaces for R users to check and
manipulate the data. These tools represent the SQL tables in tidy
formats and support lazy and quick aggregation operations (e.g,
*_join
, union
, etc.) for tables from same resources. Cross
database aggregation is also supported when opted (using copy=TRUE
)
but become very expensive due to the internal copying process of a
whole table into the other connection. Use of advanced functions often
involves specialized SQL knowledge which brings challenges for common
R users. The interoperability of existing bioinformatics tools are
suboptimal, e.g., the SummarizedExperiment container for
representation of sequencing or genotyping experiments that many
modern bioinformatics pipelines are based.
The SQLDataFrame package was developed using familiar DataFrame-like
paradigm and lazily represents the very large dataset from different
SQL databases, such as SQLite and MySQL. The DataFrame-like interface
provides familiarity for common R users in easy data manipulations
such as square bracket subsetting, rbinding, etc. For modern R
users, it also recognizes the tidy
data analysis and dplyr
grammar by supporting %>%
, select
, filter
, mutate
, etc. More
importantly, database type-specific strategies were implemented in
SQLDataFrame to efficiently handle the cross-database operations
without incurring any internally expensive processes (especially for
database with write permission). Some previously difficult data
operations are made quick and easy in R, such as cross-database ID
matching and conversion, variant annotation extraction, etc. The
scalability and interoperability of SQLDataFrame are expected to
significantly promote the handling of very large genomic data
resources and facilitating the overall bioinformatics analysis.
Currently SQLDataFrame supports the DBI backend of SQLite, MySQL and
Google BigQuery, which are most commonly used SQL-based databases. In
the future or upon feature request, we would implement this package so
that users could choose to use different database backend for
SQLDataFrame
representation.
Here is a list of commonly used backends (bolded are already supported!):
if (!requireNamespace("BiocManager", quietly = TRUE))
install.packages("BiocManager")
BiocManager::install("SQLDataFrame")
The development version is also available to download from Github.
BiocManager::install("Liubuntu/SQLDataFrame")
library(SQLDataFrame)
library(DBI)
SQLDataFrame
classSQLDataFrame
constructorThere are two ways to construct a SQLDataFrame
object:
Provide an argument of conn
, dbtable
and dbkey
. conn
is a
valid DBIConnection from SQLite or MySQL; dbtable
specifies the
database table name that is going to be represented as SQLDataFrame
object. If only one table is available in the specified database name,
this argument could be left blank. The dbkey
argument is used to
specify the column name in the table which could uniquely identify all
the data observations (rows).
Provide dbtable
, dbkey
as specified above, and credentials to
build valid DBIConnections. for SQLite, the credential argument
includes dbname
. For MySQL, the credential arguments are host
,
user
, password
. Additional to the credentials, users must provide
the type
argument to specify the SQL database type. Supported types
are “SQLite” and “MySQL”. If not specified, “SQLite” is used by
default. Supported database tables could be on-disk or remote on the
web or cloud.
dbfile <- system.file("extdata/test.db", package = "SQLDataFrame")
conn <- DBI::dbConnect(DBI::dbDriver("SQLite"), dbname = dbfile)
obj <- SQLDataFrame(conn = conn, dbtable = "state",
dbkey = "state")
construction from database credentials:
obj1 <- SQLDataFrame(dbname = dbfile, type = "SQLite",
dbtable = "state", dbkey = "state")
all.equal(obj, obj1)
#> [1] TRUE
Note that after reading the database table into SQLDataFrame
, the
key columns will be kept as fixed columns showing on the left hand
side, with |
separating key column(s) with the other columns. The
ncol
, colnames
, and corresponding column subsetting will only
apply to the non-key-columns.
obj
#> SQLDataFrame with 50 rows and 4 columns
#> state | division region population size
#> <character> | <character> <character> <numeric> <character>
#> Alabama | East South Central South 3615 medium
#> Alaska | Pacific West 365 small
#> Arizona | Mountain West 2280 medium
#> Arkansas | West South Central South 2110 medium
#> California | Pacific West 21198 large
#> ... . ... ... ... ...
#> Virginia | South Atlantic South 4981 medium
#> Washington | Pacific West 3559 medium
#> West Virginia | South Atlantic South 1799 medium
#> Wisconsin | East North Central North Central 4589 medium
#> Wyoming | Mountain West 376 small
dim(obj)
#> [1] 50 4
colnames(obj)
#> [1] "division" "region" "population" "size"
To make the SQLDataFrame
object as light and compact as possible,
there are only 5 slots contained in the object: tblData
, dbkey
,
dbnrows
, dbconcatKey
, indexes
. Metadata information could be
returned through these 5 slots using slot accessors or other utility
functions.
slotNames(obj)
#> [1] "dbkey" "dbnrows" "tblData" "indexes" "dbconcatKey"
dbtable(obj)
#> [1] "state"
dbkey(obj)
#> [1] "state"
connSQLDataFrame(obj)
#> <SQLiteConnection>
#> Path: /tmp/Rtmp6LGdv3/Rinst7a6855b7b469/SQLDataFrame/extdata/test.db
#> Extensions: TRUE
Besides, many useful common methods are defined on SQLDataFrame
object to make it a more DataFrame-like data structure. e.g., we can
use dimnames()
to return the row/colnames of the data. It returns an
unnamed list, with the first element being rownames which is always
NULL
, and 2nd element being colnames (could also use colnames()
method). dim()
method is defined to return the dimension of the
database table, which enables the nrow()/ncol()
to extract a
specific dimension. length()
method is also defined which works same
as ncol()
.
Note that the rownames(SQLDataFrame)
would always be NULL
as
rownames are not supported in SQLDataFrame
. However, ROWNAMES(obj)
was implemented for the [
subsetting with characters.
dim(obj)
#> [1] 50 4
dimnames(obj)
#> [[1]]
#> NULL
#>
#> [[2]]
#> [1] "division" "region" "population" "size"
length(obj)
#> [1] 4
ROWNAMES(obj)
#> [1] "Alabama" "Alaska" "Arizona" "Arkansas"
#> [5] "California" "Colorado" "Connecticut" "Delaware"
#> [9] "Florida" "Georgia" "Hawaii" "Idaho"
#> [13] "Illinois" "Indiana" "Iowa" "Kansas"
#> [17] "Kentucky" "Louisiana" "Maine" "Maryland"
#> [21] "Massachusetts" "Michigan" "Minnesota" "Mississippi"
#> [25] "Missouri" "Montana" "Nebraska" "Nevada"
#> [29] "New Hampshire" "New Jersey" "New Mexico" "New York"
#> [33] "North Carolina" "North Dakota" "Ohio" "Oklahoma"
#> [37] "Oregon" "Pennsylvania" "Rhode Island" "South Carolina"
#> [41] "South Dakota" "Tennessee" "Texas" "Utah"
#> [45] "Vermont" "Virginia" "Washington" "West Virginia"
#> [49] "Wisconsin" "Wyoming"
NOTE that the dbtable()
accessor only works for a SQLDataFrame
object that the lazy tbl carried in tblData
slot corresponds to a
single database. If the SQLDataFrame
was generated from rbind
,
union
or *_join
, call saveSQLDataFrame()
to save the lazy tbl to
disk so that dbtable()
will be activated.
dbtable(obj)
#> [1] "state"
aa <- rbind(obj[1:5, ], obj[6:10, ])
aa
#> SQLDataFrame with 10 rows and 4 columns
#> state | division region population size
#> <character> | <character> <character> <numeric> <character>
#> Alabama | East South Central South 3615 medium
#> Alaska | Pacific West 365 small
#> Arizona | Mountain West 2280 medium
#> Arkansas | West South Central South 2110 medium
#> California | Pacific West 21198 large
#> Colorado | Mountain West 2541 medium
#> Connecticut | New England Northeast 3100 medium
#> Delaware | South Atlantic South 579 small
#> Florida | South Atlantic South 8277 large
#> Georgia | South Atlantic South 4931 medium
dbtable(aa) ## message
#> Warning in dbtable(aa): ## not available for SQLDataFrame with lazy queries of 'union', 'join', or 'rbind'.
#> ## call 'saveSQLDataFrame()' to save the data as database table and call 'dbtable()' again!
bb <- saveSQLDataFrame(aa, dbname = tempfile(fileext=".db"),
dbtable = "aa", overwrite = TRUE)
#> ## A new database table is saved!
#> ## Source: table<aa> [10 X 4]
#> ## Database: sqlite 3.30.1 [/tmp/RtmpsL5525/file3347d2da5e7.db]
#> ## Use the following command to reload into R:
#> ## sdf <- SQLDataFrame(
#> ## dbname = '/tmp/RtmpsL5525/file3347d2da5e7.db',
#> ## type = 'SQLite',
#> ## dbtable = 'aa',
#> ## dbkey = 'state')
connSQLDataFrame(bb)
#> <SQLiteConnection>
#> Path: /tmp/RtmpsL5525/file3347d2da5e7.db
#> Extensions: TRUE
dbtable(bb)
#> [1] "aa"
We could also construct a SQLDataFrame
object directly from a file
name. The makeSQLDataFrame
function takes input of character value
of file name for common text files (.csv, .txt, etc.), write into
database tables, and open as SQLDataFrame
object. Users could
provide values for the dbname
and dbtable
argument. If NULL,
default value for dbname
would be a temporary database file, and
dbtable
would be the basename(filename)
without extension.
NOTE that the input file must have one or multiple columns that
could uniquely identify each observation (row) to be used the
dbkey()
for SQLDataFrame
. Also the file must be rectangular, i.e.,
rownames are not accepted. But users could save rownames as a separate
column.
mtc <- tibble::rownames_to_column(mtcars)[,1:6]
filename <- file.path(tempdir(), "mtc.csv")
write.csv(mtc, file= filename, row.names = FALSE)
aa <- makeSQLDataFrame(filename, dbkey = "rowname", sep = ",",
overwrite = TRUE)
#> ## A new database table is saved!
#> ## Source: table<mtc> [32 X 5]
#> ## Database: sqlite 3.30.1 [/tmp/RtmpsL5525/file3343777e306.db]
#> ## Use the following command to reload into R:
#> ## sdf <- SQLDataFrame(
#> ## dbname = '/tmp/RtmpsL5525/file3343777e306.db',
#> ## type = 'SQLite',
#> ## dbtable = 'mtc',
#> ## dbkey = 'rowname')
#>
aa
#> SQLDataFrame with 32 rows and 5 columns
#> rowname | mpg cyl disp hp drat
#> <character> | <numeric> <integer> <numeric> <integer> <numeric>
#> "Mazda RX4" | 21.0 6 160 110 3.90
#> "Mazda RX4 Wag" | 21.0 6 160 110 3.90
#> "Datsun 710" | 22.8 4 108 93 3.85
#> "Hornet 4 Drive" | 21.4 6 258 110 3.08
#> "Hornet Sportabout" | 18.7 8 360 175 3.15
#> ... . ... ... ... ... ...
#> "Lotus Europa" | 30.4 4 95.1 113 3.77
#> "Ford Pantera L" | 15.8 8 351.0 264 4.22
#> "Ferrari Dino" | 19.7 6 145.0 175 3.62
#> "Maserati Bora" | 15.0 8 301.0 335 3.54
#> "Volvo 142E" | 21.4 4 121.0 109 4.11
connSQLDataFrame(aa)
#> <SQLiteConnection>
#> Path: /tmp/RtmpsL5525/file3343777e306.db
#> Extensions: TRUE
dbtable(aa)
#> [1] "mtc"
With all the methods ([
subsetting, rbind
, *_join
, etc.,)
provided in the next section, the SQLDataFrame
always work like a
lazy representation until users explicitly call the saveSQLDataFrame
function for realization. saveSQLDataFrame
write the lazy tbl
carried in tblData
slot into an on-disk database table, and re-open
the SQLDataFrame
object from the new path.
It’s also recommended that users call saveSQLDataFrame
frequently to
avoid too many lazy layers which slows down the data processing.
connSQLDataFrame(obj)
#> <SQLiteConnection>
#> Path: /tmp/Rtmp6LGdv3/Rinst7a6855b7b469/SQLDataFrame/extdata/test.db
#> Extensions: TRUE
dbtable(obj)
#> [1] "state"
obj1 <- saveSQLDataFrame(obj, dbname = tempfile(fileext = ".db"),
dbtable = "obj_copy")
#> ## A new database table is saved!
#> ## Source: table<obj_copy> [50 X 4]
#> ## Database: sqlite 3.30.1 [/tmp/RtmpsL5525/file334707b68ff.db]
#> ## Use the following command to reload into R:
#> ## sdf <- SQLDataFrame(
#> ## dbname = '/tmp/RtmpsL5525/file334707b68ff.db',
#> ## type = 'SQLite',
#> ## dbtable = 'obj_copy',
#> ## dbkey = 'state')
connSQLDataFrame(obj1)
#> <SQLiteConnection>
#> Path: /tmp/RtmpsL5525/file334707b68ff.db
#> Extensions: TRUE
dbtable(obj1)
#> [1] "obj_copy"
[[
subsetting[[,SQLDataFrame
Behaves similarly to [[,DataFrame
and returns a
realized vector of values from a single column. $,SQLDataFrame
is
also defined to conveniently extract column values.
head(obj[[1]])
#> [1] "East South Central" "Pacific" "Mountain"
#> [4] "West South Central" "Pacific" "Mountain"
head(obj[["region"]])
#> [1] "South" "West" "West" "South" "West" "West"
head(obj$size)
#> [1] "medium" "small" "medium" "medium" "large" "medium"
We can also get the key column values using character extraction.
head(obj[["state"]])
#> [1] "Alabama" "Alaska" "Arizona" "Arkansas" "California"
#> [6] "Colorado"
[
subsettingSQLDataFrame
instances can be subsetted in a similar way of
DataFrame
following the usual R conventions, with numeric,
character or logical vectors; logical vectors are recycled to the
appropriate length.
NOTE, use drop=FALSE
explicitly for single column subsetting if
you want to return a SQLDataFrame
object, otherwise, the default
drop=TRUE
would always return a realized value for that column.
obj[1:3, 1:2]
#> SQLDataFrame with 3 rows and 2 columns
#> state | division region
#> <character> | <character> <character>
#> Alabama | East South Central South
#> Alaska | Pacific West
#> Arizona | Mountain West
obj[c(TRUE, FALSE), c(TRUE, FALSE), drop=FALSE]
#> SQLDataFrame with 25 rows and 2 columns
#> state | division population
#> <character> | <character> <numeric>
#> Alabama | East South Central 3615
#> Arizona | Mountain 2280
#> California | Pacific 21198
#> Connecticut | New England 3100
#> Florida | South Atlantic 8277
#> ... . ... ...
#> South Dakota | West North Central 746
#> Texas | West South Central 12237
#> Vermont | New England 472
#> Washington | Pacific 3559
#> Wisconsin | East North Central 4589
obj[1:3, "population", drop=FALSE]
#> SQLDataFrame with 3 rows and 1 column
#> state | population
#> <character> | <numeric>
#> Alabama | 3615
#> Alaska | 365
#> Arizona | 2280
obj[, "population"] ## realized column value
#> [1] 3615 365 2280 2110 21198 2541 3100 579 8277 4931 868 813
#> [13] 11197 5313 2861 2280 9111 3806 1058 4122 5814 9111 3921 2341
#> [25] 4767 746 1544 590 812 7333 1799 18076 5441 637 10735 2715
#> [37] 2284 11860 931 2816 746 4173 12237 1203 472 4981 3559 1799
#> [49] 4589 376
Subsetting with character vector works for the SQLDataFrame
objects. With composite keys, users need to concatenate the key values
by :
for row subsetting (See the vignette for internal
implementation for more details).
rnms <- ROWNAMES(obj)
obj[c("Alabama", "Colorado"), ]
#> SQLDataFrame with 2 rows and 4 columns
#> state | division region population size
#> <character> | <character> <character> <numeric> <character>
#> Alabama | East South Central South 3615 medium
#> Colorado | Mountain West 2541 medium
obj1 <- SQLDataFrame(conn = conn, dbtable = "state",
dbkey = c("region", "population"))
rnms <- ROWNAMES(obj1)
obj1[c("South:3615.0", "West:365.0"), ]
#> SQLDataFrame with 2 rows and 3 columns
#> region population | division state size
#> <character> <numeric> | <character> <character> <character>
#> South 3615 | East South Central Alabama medium
#> West 365 | Pacific Alaska small
List style subsetting is also allowed to extract certain columns from
the SQLDataFrame
object which returns SQLDataFrame
by default.
obj[1]
#> SQLDataFrame with 50 rows and 1 column
#> state | division
#> <character> | <character>
#> Alabama | East South Central
#> Alaska | Pacific
#> Arizona | Mountain
#> Arkansas | West South Central
#> California | Pacific
#> ... . ...
#> Virginia | South Atlantic
#> Washington | Pacific
#> West Virginia | South Atlantic
#> Wisconsin | East North Central
#> Wyoming | Mountain
obj["region"]
#> SQLDataFrame with 50 rows and 1 column
#> state | region
#> <character> | <character>
#> Alabama | South
#> Alaska | West
#> Arizona | West
#> Arkansas | South
#> California | West
#> ... . ...
#> Virginia | South
#> Washington | West
#> West Virginia | South
#> Wisconsin | North Central
#> Wyoming | West
We have also enabled the S3 methods of filter
and mutate
from
dplyr
package, so that users could have the convenience in filtering
data observations and adding new columns.
obj1 %>% filter(division == "South Atlantic" & size == "medium")
#> SQLDataFrame with 5 rows and 3 columns
#> region population | division state size
#> <character> <numeric> | <character> <character> <character>
#> South 4931 | South Atlantic Georgia medium
#> South 4122 | South Atlantic Maryland medium
#> South 2816 | South Atlantic South Carolina medium
#> South 4981 | South Atlantic Virginia medium
#> South 1799 | South Atlantic West Virginia medium
obj1 %>% mutate(p1 = population/10, s1 = size)
#> SQLDataFrame with 50 rows and 5 columns
#> region population | division state size
#> <character> <numeric> | <character> <character> <character>
#> South 3615 | East South Central Alabama medium
#> West 365 | Pacific Alaska small
#> West 2280 | Mountain Arizona medium
#> South 2110 | West South Central Arkansas medium
#> West 21198 | Pacific California large
#> ... ... . ... ... ...
#> South 4981 | South Atlantic Virginia medium
#> West 3559 | Pacific Washington medium
#> South 1799 | South Atlantic West Virginia medium
#> North Central 4589 | East North Central Wisconsin medium
#> West 376 | Mountain Wyoming small
#> p1 s1
#> <numeric> <character>
#> 361.5 medium
#> 36.5 small
#> 228.0 medium
#> 211.0 medium
#> 2119.8 large
#> ... ...
#> 498.1 medium
#> 355.9 medium
#> 179.9 medium
#> 458.9 medium
#> 37.6 small
To be consistent with DataFrame
, union
and rbind
methods were
implemented for SQLDataFrame
, where union
returns the
SQLDataFrame
sorted by the dbkey(obj)
, and rbind
keeps the
original orders of input objects.
dbfile1 <- system.file("extdata/test.db", package = "SQLDataFrame")
con1 <- DBI::dbConnect(dbDriver("SQLite"), dbname = dbfile1)
dbfile2 <- system.file("extdata/test1.db", package = "SQLDataFrame")
con2 <- DBI::dbConnect(dbDriver("SQLite"), dbname = dbfile2)
ss1 <- SQLDataFrame(conn = con1, dbtable = "state",
dbkey = c("state"))
ss2 <- SQLDataFrame(conn = con2, dbtable = "state1",
dbkey = c("state"))
ss11 <- ss1[sample(5), ]
ss21 <- ss2[sample(10, 5), ]
obj1 <- union(ss11, ss21)
obj1 ## reordered by the "dbkey()"
obj2 <- rbind(ss11, ss21)
obj2 ## keeping the original order by updating the row index
#> SQLDataFrame with 10 rows and 4 columns
#> state | division region population size
#> <character> | <character> <character> <numeric> <character>
#> Arizona | Mountain West 2280 medium
#> Alabama | East South Central South 3615 medium
#> California | Pacific West 21198 large
#> Arkansas | West South Central South 2110 medium
#> Alaska | Pacific West 365 small
#> Delaware | South Atlantic South 579 small
#> Georgia | South Atlantic South 4931 medium
#> Arizona | Mountain West 2280 medium
#> Alabama | East South Central South 3615 medium
#> Arkansas | West South Central South 2110 medium
The *_join
family methods was implemented for SQLDataFrame
objects, including the left_join
, inner_join
, semi_join
and
anti_join
, which provides the capability of merging database files
from different sources.
ss12 <- ss1[1:10, 1:2]
ss22 <- ss2[6:15, 3:4]
left_join(ss12, ss22)
#> Joining, by = "state"
#> SQLDataFrame with 10 rows and 4 columns
#> state | division region population size
#> <character> | <character> <character> <numeric> <character>
#> Alabama | East South Central South <NA> <NA>
#> Alaska | Pacific West <NA> <NA>
#> Arizona | Mountain West <NA> <NA>
#> Arkansas | West South Central South <NA> <NA>
#> California | Pacific West <NA> <NA>
#> Colorado | Mountain West 2541 medium
#> Connecticut | New England Northeast 3100 medium
#> Delaware | South Atlantic South 579 small
#> Florida | South Atlantic South 8277 large
#> Georgia | South Atlantic South 4931 medium
inner_join(ss12, ss22)
#> Joining, by = "state"
#> SQLDataFrame with 5 rows and 4 columns
#> state | division region population size
#> <character> | <character> <character> <numeric> <character>
#> Colorado | Mountain West 2541 medium
#> Connecticut | New England Northeast 3100 medium
#> Delaware | South Atlantic South 579 small
#> Florida | South Atlantic South 8277 large
#> Georgia | South Atlantic South 4931 medium
semi_join(ss12, ss22)
#> Joining, by = "state"
#> SQLDataFrame with 5 rows and 2 columns
#> state | division region
#> <character> | <character> <character>
#> Colorado | Mountain West
#> Connecticut | New England Northeast
#> Delaware | South Atlantic South
#> Florida | South Atlantic South
#> Georgia | South Atlantic South
anti_join(ss12, ss22)
#> Joining, by = "state"
#> SQLDataFrame with 5 rows and 2 columns
#> state | division region
#> <character> | <character> <character>
#> Alabama | East South Central South
#> Alaska | Pacific West
#> Arizona | Mountain West
#> Arkansas | West South Central South
#> California | Pacific West
SQLDataFrame now supports the MySQL database tables through RMySQL,
for local MySQL servers, or remote ones on the web or cloud. The
SQLDataFrame construction, *_join
functions, union
, rbind
, and
saving are all supported. Aggregation operations are supported for
same or cross MySQL databases. Details please see the function
documentations.
Here I’ll show a simple use case for MySQL tables from ensembl.
library(RMySQL)
ensbConn <- dbConnect(dbDriver("MySQL"),
host="genome-mysql.soe.ucsc.edu",
user = "genome",
dbname = "xenTro9")
enssdf <- SQLDataFrame(conn = ensbConn,
dbtable = "xenoRefGene",
dbkey = c("name", "txStart"))
#> Warning in .local(conn, statement, ...): Unsigned INTEGER in col 0 imported as
#> numeric
#> Warning in .local(conn, statement, ...): Unsigned INTEGER in col 4 imported as
#> numeric
#> Warning in .local(conn, statement, ...): Unsigned INTEGER in col 5 imported as
#> numeric
#> Warning in .local(conn, statement, ...): Unsigned INTEGER in col 6 imported as
#> numeric
#> Warning in .local(conn, statement, ...): Unsigned INTEGER in col 7 imported as
#> numeric
#> Warning in .local(conn, statement, ...): Unsigned INTEGER in col 8 imported as
#> numeric
enssdf1 <- enssdf[1:20, 1:2]
enssdf2 <- enssdf[11:30,3:4]
res <- left_join(enssdf1, enssdf2)
#> Joining, by = c("name", "txStart")
SQLDataFrame has just added support for Google BigQuery
tables. Construction and queries using [
and filter
are supported!
“Authentication and authorization” will be needed when using bigrquery. Check here for more details.
Also note that, the support of BigQuery tables has implemented
specialized strategy for efficient data representation. The dbkey()
is assigned by default as SurrogateKey
, and dbkey
argument will be
ignored during construction.
library(bigrquery)
bigrquery::bq_auth() ## use this to authorize bigrquery in the
## browser.
bqConn <- DBI::dbConnect(dbDriver("bigquery"),
project = "bigquery-public-data",
dataset = "human_variant_annotation",
billing = "") ## if not previous provided
## authorization, must specify a
## project name that was already
## linked with Google Cloud with
## billing info.
sdf <- SQLDataFrame(conn = bqConn, dbtable = "ncbi_clinvar_hg38_20180701")
sdf[1:5, 1:5]
sdf %>% filter(GENEINFO == "PYGL:5836")
sdf %>% filter(reference_name == "21")
sessionInfo()
#> R version 4.0.0 (2020-04-24)
#> Platform: x86_64-pc-linux-gnu (64-bit)
#> Running under: Ubuntu 18.04.4 LTS
#>
#> Matrix products: default
#> BLAS: /home/biocbuild/bbs-3.11-bioc/R/lib/libRblas.so
#> LAPACK: /home/biocbuild/bbs-3.11-bioc/R/lib/libRlapack.so
#>
#> locale:
#> [1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
#> [3] LC_TIME=en_US.UTF-8 LC_COLLATE=C
#> [5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
#> [7] LC_PAPER=en_US.UTF-8 LC_NAME=C
#> [9] LC_ADDRESS=C LC_TELEPHONE=C
#> [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
#>
#> attached base packages:
#> [1] parallel stats4 stats graphics grDevices utils datasets
#> [8] methods base
#>
#> other attached packages:
#> [1] RMySQL_0.10.20 DBI_1.1.0 SQLDataFrame_1.2.0
#> [4] S4Vectors_0.26.0 BiocGenerics_0.34.0 dbplyr_1.4.3
#> [7] dplyr_0.8.5 BiocStyle_2.16.0
#>
#> loaded via a namespace (and not attached):
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#> [4] BiocManager_1.30.10 tools_4.0.0 digest_0.6.25
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