Working with large tables

2024-03-12

Most StatCan tables are small in size and can easily processed in memory. However, some tables are so large that this is not a feasible strategy. Table 43-10-0024 is one such example and comes with a CSV file that is several gigabytes in size. In cases like this it is more useful to store and access the data as an SQLite database using the get_cansim_sqlite function instead of the usual get_cansim. In these circumstances it is also useful to cache the data for longer than just the current R session, and the data_cache option allows to specify a permanent location. It defaults to getOption("cansim.cache_path"), and if this option is not set it will only cache the data for the duration of the current session.

For this vignette we use the (rather small) motor vehicle sales data as an example.

library(dplyr)
#> 
#> Attaching package: 'dplyr'
#> The following objects are masked from 'package:stats':
#> 
#>     filter, lag
#> The following objects are masked from 'package:base':
#> 
#>     intersect, setdiff, setequal, union
library(ggplot2)

library(cansim)

One main difference to the get_cansim method is that get_cansim_sqlite does not return data but only a connection to the database. This allows us to filter the data before fetching the data into memory. When this is called the first time it will fetch the data, parse it into an SQLite database, index the main columns. This can take a significant amount of time, depending on the size of the table. In any subsequent call it will simply open a database connection to the cached database.

connection <- get_cansim_sqlite("20-10-0001")
#> Accessing CANSIM NDM product 20-10-0001 from Statistics Canada
#> Parsing data
#> Indexing GEO
#> Indexing Vehicle type
#> Indexing Origin of manufacture
#> Indexing Sales
#> Indexing Seasonal adjustment
#> Indexing REF_DATE
#> Indexing DGUID
#> Indexing GeoUID

We can inspect the data by looking at the first few columns to get a general idea of what the data looks like.

head(connection)
#> # Source:   SQL [6 x 19]
#> # Database: sqlite 3.44.2 [/private/var/folders/z4/gcjq2cd93p3bs5bgp8j2vv240000gp/T/RtmpPwg2TL/cansim_20100001_eng/20100001-eng.sqlite]
#>   REF_DATE GEO    DGUID          `Vehicle type`     Origin of manufactur…¹ Sales
#>   <chr>    <chr>  <chr>          <chr>              <chr>                  <chr>
#> 1 1946-01  Canada 2016A000011124 Total, new motor … Total, country of man… Units
#> 2 1946-01  Canada 2016A000011124 Total, new motor … Total, country of man… Doll…
#> 3 1946-01  Canada 2016A000011124 Passenger cars     Total, country of man… Units
#> 4 1946-01  Canada 2016A000011124 Passenger cars     Total, country of man… Units
#> 5 1946-01  Canada 2016A000011124 Passenger cars     Total, country of man… Doll…
#> 6 1946-01  Canada 2016A000011124 Trucks             Total, country of man… Units
#> # ℹ abbreviated name: ¹​`Origin of manufacture`
#> # ℹ 13 more variables: `Seasonal adjustment` <chr>, UOM <chr>, UOM_ID <chr>,
#> #   SCALAR_FACTOR <chr>, SCALAR_ID <chr>, VECTOR <chr>, COORDINATE <chr>,
#> #   VALUE <dbl>, STATUS <chr>, SYMBOL <chr>, TERMINATED <chr>, DECIMALS <chr>,
#> #   GeoUID <chr>

To make good use of the data we will have to look at the metadata and inspect the member columns and variables available. The metadata will be available in the R session after the database connection has been opened. Trying to access the metadata before the connection has been opened will result in the package to attempt to download the data via the get_cansim call, which the get_cansim_sqlite function is trying to avoid.

get_cansim_table_overview("20-10-0001")
#> New motor vehicle sales
#> CANSIM Table 20-10-0001
#> Start Reference Period: 1946-01-01, End Reference Period: 2023-12-01, Frequency: Monthly
#> 
#> Column Geography (11)
#> Newfoundland and Labrador, Prince Edward Island, Nova Scotia, New Brunswick, Quebec, Ontario, Manitoba, Saskatchewan, Alberta, British Columbia and the Territories, ...
#> 
#> Column Vehicle type (3)
#> Passenger cars, Trucks, Total, new motor vehicles
#> 
#> Column Origin of manufacture (5)
#> North America, Total, overseas, Japan, Other countries, Total, country of manufacture
#> 
#> Column Sales (2)
#> Units, Dollars
#> 
#> Column Seasonal adjustment (2)
#> Unadjusted, Seasonally adjusted

This gives us an understanding of the available variables. For the purpose of this vignette we are interested in the breakdown of sales units by Vehicle type in Canada overall. The data is stored in its raw form in the database, the only processing done is that it is augmented by the GeoUID. In order to work with it we need to collect the data. If the only operation done is filtering, and no selection or renaming of columns was done before accessing the data, we can utilize the custom collect_and_normalize function to collect and at the same time normalize the data so it will appear the same way as if we had used the get_cansim function. This will add the category and hierarchy metadata and the normalized value column.

data <- connection %>%
  filter(GEO=="Canada",
         `Seasonal adjustment`=="Unadjusted",
         Sales=="Units",
         `Origin of manufacture`=="Total, country of manufacture",
         `Vehicle type` %in% c("Passenger cars","Trucks")) %>%
  collect_and_normalize()

data %>% head()
#> # A tibble: 6 × 30
#>   REF_DATE GEO    DGUID   UOM   UOM_ID SCALAR_FACTOR SCALAR_ID VECTOR COORDINATE
#>   <chr>    <chr>  <chr>   <chr> <chr>  <chr>         <chr>     <chr>  <chr>     
#> 1 1946-01  Canada 2016A0… Units 300    "units "      0         v4216… 1.2.1.1.1 
#> 2 1946-01  Canada 2016A0… Units 300    "units "      0         v4216… 1.3.1.1.1 
#> 3 1946-02  Canada 2016A0… Units 300    "units "      0         v4216… 1.2.1.1.1 
#> 4 1946-02  Canada 2016A0… Units 300    "units "      0         v4216… 1.3.1.1.1 
#> 5 1946-03  Canada 2016A0… Units 300    "units "      0         v4216… 1.2.1.1.1 
#> 6 1946-03  Canada 2016A0… Units 300    "units "      0         v4216… 1.3.1.1.1 
#> # ℹ 21 more variables: VALUE <dbl>, STATUS <chr>, SYMBOL <chr>,
#> #   TERMINATED <chr>, DECIMALS <chr>, GeoUID <chr>, val_norm <dbl>,
#> #   Date <date>, `Hierarchy for GEO` <chr>,
#> #   `Classification Code for Vehicle type` <chr>,
#> #   `Hierarchy for Vehicle type` <chr>,
#> #   `Classification Code for Origin of manufacture` <chr>,
#> #   `Hierarchy for Origin of manufacture` <chr>, …

Given the data we can further filter the date range and plot it.

data %>%
  filter(Date>=as.Date("1990-01-01")) %>%
  ggplot(aes(x=Date,y=val_norm,color=`Vehicle type`)) +
  geom_smooth(span=0.2,method = 'loess', formula = y ~ x) +
  theme(legend.position="bottom") +
  scale_y_continuous(labels = function(d)scales::comma(d,scale=10^-3,suffix="k")) +
  labs(title="Canada new motor vehicle sales",caption="StatCan Table 20-10-0001",
       x=NULL,y="Number of units")

When we don’t need the database connection any more we should remember to close it. This frees up resources and keeps the database handlers happy.

disconnect_cansim_sqlite(connection)

Keeping track of cached data

Since we now have the option of a more permanent cache we should take care to manage that space properly. The list_cansim_sqlite_cached_tables function gives us an overview over the cached data we have.

list_cansim_sqlite_cached_tables()
#> # A tibble: 1 × 8
#>   cansimTableNumber language timeCached          sqliteSize title          path 
#>   <chr>             <chr>    <dttm>              <chr>      <chr>          <chr>
#> 1 20-10-0001        eng      2024-03-12 12:04:27 46.4 Mb    New motor veh… cans…
#> # ℹ 2 more variables: timeReleased <dttm>, upToDate <lgl>

Cached data won’t update automatically, we will have to pass the refresh=TRUE option to refresh it manually when we want a fresh data pull from StatCan. If we want to free up disk space we can remove a cached table.

remove_cansim_sqlite_cached_table("20-10-0001")
#> Removing cached data for 20-10-0001 (eng)
#> NULL