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It might seem intuitive that since you can do:
That you should also be able to do:
add_days(x, 1)
#> Error in `add_days()`:
#> ! Can't perform this operation on a <clock_year_month_day>.
#> ℹ Do you need to convert to a time point first?
#> ℹ Use `as_naive_time()` or `as_sys_time()` to convert to a time point.
Generally, calendars don’t support day based arithmetic, nor do they support arithmetic at more precise precisions than day. Instead, you have to convert to a time point, do the arithmetic there, and then convert back (if you still need a year-month-day after that).
x %>%
as_naive_time() %>%
add_days(1) %>%
as_year_month_day()
#> <year_month_day<day>[1]>
#> [1] "2019-01-06"
The first reason for this is performance. A year-month-day is a field type, implemented as multiple parallel vectors holding the year, month, day, and all other components separately. There are two ways that day based arithmetic could be implemented for this:
Increment the day field, then check the year and month field to see if they need to be incremented, accounting for months having a differing number of days, and leap years.
Convert to naive-time, add days, convert back.
Both approaches are relatively expensive. One of the goals of the low-level API of clock is to make these expensive operations explicit. This helps make it apparent that when you need to chain together multiple operations, you should try and do all of your calendrical arithmetic steps first, then convert to a time point (i.e. the second bullet point from above) to do all of your chronological arithmetic.
The second reason for this has to do with invalid dates, such as the three in this vector:
odd_dates <- year_month_day(2019, 2, 28:31)
odd_dates
#> <year_month_day<day>[4]>
#> [1] "2019-02-28" "2019-02-29" "2019-02-30" "2019-02-31"
What does it mean to “add 1 day” to these? There is no obvious answer
to this question. Since clock requires that you first convert to a time
point to do day based arithmetic, you’ll be forced to call
invalid_resolve()
to handle these invalid dates first.
After resolving them manually, then day based arithmetic again makes
sense.
odd_dates %>%
invalid_resolve(invalid = "next")
#> <year_month_day<day>[4]>
#> [1] "2019-02-28" "2019-03-01" "2019-03-01" "2019-03-01"
odd_dates %>%
invalid_resolve(invalid = "next") %>%
as_naive_time() %>%
add_days(2)
#> <naive_time<day>[4]>
#> [1] "2019-03-02" "2019-03-03" "2019-03-03" "2019-03-03"
odd_dates %>%
invalid_resolve(invalid = "overflow")
#> <year_month_day<day>[4]>
#> [1] "2019-02-28" "2019-03-01" "2019-03-02" "2019-03-03"
odd_dates %>%
invalid_resolve(invalid = "overflow") %>%
as_naive_time() %>%
add_days(2)
#> <naive_time<day>[4]>
#> [1] "2019-03-02" "2019-03-03" "2019-03-04" "2019-03-05"
If you have a zoned-time, such as:
x <- zoned_time_parse_complete("1970-04-26T01:30:00-05:00[America/New_York]")
x
#> <zoned_time<second><America/New_York>[1]>
#> [1] "1970-04-26T01:30:00-05:00"
You might wonder why you can’t add any units of time to it:
add_days(x, 1)
#> Error in `add_days()`:
#> ! Can't perform this operation on a <clock_zoned_time>.
#> ℹ Do you need to convert to a time point first?
#> ℹ Use `as_naive_time()` or `as_sys_time()` to convert to a time point.
add_seconds(x, 1)
#> Error in `add_seconds()`:
#> ! Can't perform this operation on a <clock_zoned_time>.
#> ℹ Do you need to convert to a time point first?
#> ℹ Use `as_naive_time()` or `as_sys_time()` to convert to a time point.
In clock, you can’t do much with zoned-times directly. The best way to understand this is to think of a zoned-time as containing 3 things: a sys-time, a naive-time, and a time zone name. You can access those things with:
x
#> <zoned_time<second><America/New_York>[1]>
#> [1] "1970-04-26T01:30:00-05:00"
# The printed time with no time zone info
as_naive_time(x)
#> <naive_time<second>[1]>
#> [1] "1970-04-26T01:30:00"
# The equivalent time in UTC
as_sys_time(x)
#> <sys_time<second>[1]>
#> [1] "1970-04-26T06:30:00"
zoned_time_zone(x)
#> [1] "America/New_York"
Calling add_days()
on a zoned-time is then an ambiguous
operation. Should we add to the sys-time or the naive-time that is
contained in the zoned-time? The answer changes depending on the
scenario.
Because of this, you have to extract out the relevant time point that you care about, operate on that, and then convert back to zoned-time. This often produces the same result:
x %>%
as_naive_time() %>%
add_seconds(1) %>%
as_zoned_time(zoned_time_zone(x))
#> <zoned_time<second><America/New_York>[1]>
#> [1] "1970-04-26T01:30:01-05:00"
x %>%
as_sys_time() %>%
add_seconds(1) %>%
as_zoned_time(zoned_time_zone(x))
#> <zoned_time<second><America/New_York>[1]>
#> [1] "1970-04-26T01:30:01-05:00"
But not always! When daylight saving time is involved, the choice of sys-time or naive-time matters. Let’s try adding 30 minutes:
# There is a DST gap 1 second after 01:59:59,
# which jumps us straight to 03:00:00,
# skipping the 2 o'clock hour entirely
x %>%
as_naive_time() %>%
add_minutes(30) %>%
as_zoned_time(zoned_time_zone(x))
#> Error in `as_zoned_time()`:
#> ! Nonexistent time due to daylight saving time at location 1.
#> ℹ Resolve nonexistent time issues by specifying the `nonexistent` argument.
x %>%
as_sys_time() %>%
add_minutes(30) %>%
as_zoned_time(zoned_time_zone(x))
#> <zoned_time<second><America/New_York>[1]>
#> [1] "1970-04-26T03:00:00-04:00"
When adding to the naive-time, we got an error. With the sys-time, everything seems okay. What happened?
The sys-time scenario is easy to explain. Technically this converts to UTC, adds the time there, then converts back to your time zone. An easier way to think about this is that you sat in front of your computer for exactly 30 minutes (1800 seconds), then looked at the clock. Assuming that that clock automatically changes itself correctly for daylight saving time, it should read 3 o’clock.
The naive-time scenario makes more sense if you break down the steps. First, we convert to naive-time, dropping all time zone information but keeping the printed time:
x
#> <zoned_time<second><America/New_York>[1]>
#> [1] "1970-04-26T01:30:00-05:00"
x %>%
as_naive_time()
#> <naive_time<second>[1]>
#> [1] "1970-04-26T01:30:00"
We add 30 minutes to this. Because we don’t have any time zone information, this lands us at 2 o’clock, which isn’t an issue when working with naive-time:
Finally, we convert back to zoned-time. If possible, this tries to
keep the printed time, and just attaches the relevant time zone onto it.
However, in this case that isn’t possible, since 2 o’clock didn’t exist
in this time zone! This nonexistent time must be handled
explicitly by setting the nonexistent
argument of
as_zoned_time()
. We can choose from a variety of strategies
to handle nonexistent times, but here we just roll forward to the next
valid moment in time.
x %>%
as_naive_time() %>%
add_minutes(30) %>%
as_zoned_time(zoned_time_zone(x), nonexistent = "roll-forward")
#> <zoned_time<second><America/New_York>[1]>
#> [1] "1970-04-26T03:00:00-04:00"
As a general rule, it often makes the most sense to add:
Years, quarters, and months to a calendar.
Weeks and days to a naive time.
Hours, minutes, seconds, and subseconds to a sys time.
This is what the high-level API for POSIXct does. However, this isn’t always what you want, so the low-level API requires you to be more explicit.
Consider the following POSIXct:
It looks like there is some fractional second information here, but converting it to naive-time drops it:
This is purposeful. clock treats POSIXct as a second precision data type. The reason for this has to do with the fact that POSIXct is implemented as a vector of doubles, which have a limit to how precisely they can store information. For example, try parsing a slightly smaller or larger fractional second:
y <- as.POSIXct(
c("2019-01-01 01:00:00.1", "2019-01-01 01:00:00.3"),
"America/New_York"
)
# Oh dear!
y
#> [1] "2019-01-01 01:00:00.0 EST" "2019-01-01 01:00:00.2 EST"
It isn’t printing correctly, at the very least. Let’s look under the hood:
unclass(y)
#> [1] 1546322400.099999904633 1546322400.299999952316
#> attr(,"tzone")
#> [1] "America/New_York"
Double vectors have a limit to how much precision they can represent,
and this is bumping up against that limit. So our .1
seconds is instead represented as .099999etc
.
This precision loss gets worse the farther we get from the epoch,
1970-01-01, represented as 0
under the hood. For example,
here we’ll use a number of seconds that represents the year 2050, and
add 5 microseconds to it:
new_utc <- function(x) {
class(x) <- c("POSIXct", "POSIXt")
attr(x, "tzone") <- "UTC"
x
}
year_2050 <- 2524608000
five_microseconds <- 0.000005
new_utc(year_2050)
#> [1] "2050-01-01 UTC"
# Oh no!
new_utc(year_2050 + five_microseconds)
#> [1] "2050-01-01 00:00:00.000004 UTC"
# Represented internally as:
year_2050 + five_microseconds
#> [1] 2524608000.000004768372
Because of these issues, clock treats POSIXct as a second precision data type, dropping all other information. Instead, you should parse directly into a subsecond clock type:
In clock, R’s native Date type is actually assumed to be naive, i.e. clock assumes that there is a yet-to-be-specified time zone, like with a naive-time. The other possibility is to assume that Date is UTC (like sys-time), but it is often more intuitive for Dates to be naive when manipulating them and converting them to zoned-time or POSIXct.
R does not consistently treat Dates as naive or UTC. Instead it switches between them, depending on the function.
For example, the Date method of as.POSIXct()
does not
expose a tz
argument. Instead, it assumes that Date is UTC,
and that the result should be shown in local time (as defined by
Sys.timezone()
). This often results in confusing behavior,
such as:
x <- as.Date("2019-01-01")
x
#> [1] "2019-01-01"
withr::with_timezone("America/New_York", {
print(as.POSIXct(x))
})
#> [1] "2019-01-01 UTC"
With clock, converting to zoned-time from Date will always assume
that Date is naive, which will keep the printed date (if possible) and
show it in the zone
you specified.
as_zoned_time(x, "UTC")
#> <zoned_time<second><UTC>[1]>
#> [1] "2019-01-01T00:00:00+00:00"
as_zoned_time(x, "America/New_York")
#> <zoned_time<second><America/New_York>[1]>
#> [1] "2019-01-01T00:00:00-05:00"
as_zoned_time(x, "Europe/London")
#> <zoned_time<second><Europe/London>[1]>
#> [1] "2019-01-01T00:00:00+00:00"
On the other hand, the POSIXct method for as.Date()
treats Date as a naive type. This is probably what you want, and this
example just shows the inconsistency. It is a bit hard to see this,
because the tz
argument of the method defaults to
"UTC"
, but if you set the tz
argument to the
zone of your input, it becomes clear:
x <- as.POSIXct("2019-01-01 23:00:00", "America/New_York")
as.Date(x, tz = date_time_zone(x))
#> [1] "2019-01-01"
If this assumed that Date was UTC, then it would have resulted in something like:
clock currently handles leap seconds in the same way that base R’s
date-time (POSIXct) class does - it ignores them entirely. While
strptime()
has some very simple capabilities for parsing
leap seconds, clock doesn’t allow them at all:
raw <- c(
"2015-12-31T23:59:59",
"2015-12-31T23:59:60", # A real leap second!
"2016-01-01T00:00:00"
)
x <- sys_time_parse(raw)
#> Warning: Failed to parse 1 string at location 2. Returning `NA` at that
#> location.
x
#> <sys_time<second>[3]>
#> [1] "2015-12-31T23:59:59" NA "2016-01-01T00:00:00"
# Reported as exactly 1 second apart.
# In real life these are 2 seconds apart because of the leap second.
x[[3]] - x[[1]]
#> <duration<second>[1]>
#> [1] 1
Because none of the clock types handle leap seconds, clock currently
doesn’t offer a way to parse them. Your current best option if you
really need to parse leap seconds is to use
strptime()
:
# This returns a POSIXlt, which can handle the special 60s field
x <- strptime(raw, format = "%Y-%m-%dT%H:%M:%S", tz = "UTC")
x
#> [1] "2015-12-31 23:59:59 UTC" "2015-12-31 23:59:60 UTC"
#> [3] "2016-01-01 00:00:00 UTC"
# On conversion to POSIXct, it "rolls" forward
as.POSIXct(x)
#> [1] "2015-12-31 23:59:59 UTC" "2016-01-01 00:00:00 UTC"
#> [3] "2016-01-01 00:00:00 UTC"
strptime()
isn’t a great solution though, because the
parsing is fairly simple. If you try to use a “fake” leap second, it
will still accept it, even though it isn’t a real time:
# 2016-12-31 wasn't a leap second date, but it still tries to parse this fake time
strptime("2016-12-31T23:59:60", format = "%Y-%m-%dT%H:%M:%S", tz = "UTC")
#> [1] "2016-12-31 23:59:60 UTC"
A true solution would check this against a database of actual leap
seconds, and would only successfully parse it if it matched a real leap
second. The C++ library that powers clock does have this capability,
through a utc_clock
class, and we may expose this in a
limited form in the future, with conversion to and from sys-time and
naive-time.
While the entire high-level API for R’s native date (Date) and date-time (POSIXct) types will work fine with data.table, if you try to put any of the major clock types into a data.table, you will probably see this error message:
library(data.table)
data.table(x = year_month_day(2019, 1, 1))
#> Error in dimnames(x) <- dn :
#> length of 'dimnames' [1] not equal to array extent
You won’t see this issue when working with data.frames or tibbles.
As of now, data.table doesn’t support the concept of record
types. These are implemented as a list of vectors of equal length,
that together represent a single idea. The length()
of
these types should be taken from the length of the vectors, not the
length of the list. If you unclass any of the clock types, you’ll see
that they are implemented in this way:
ymdh <- year_month_day(2019, 1, 1:2, 1)
unclass(ymdh)
#> $year
#> [1] 2019 2019
#>
#> $month
#> [1] 1 1
#>
#> $day
#> [1] 1 2
#>
#> $hour
#> [1] 1 1
#>
#> attr(,"precision")
#> [1] 5
unclass(as_naive_time(ymdh))
#> $lower
#> [1] 2147483648 2147483648
#>
#> $upper
#> [1] 429529 429553
#>
#> attr(,"precision")
#> [1] 5
#> attr(,"clock")
#> [1] 1
I find that record types are extremely useful data structures for
building upon R’s basic atomic types in ways that otherwise couldn’t be
done. They allow calendar types to hold information about each
component, enabling instant access for retrieval, modification, and
grouping. They also allow calendars to represent invalid dates, such as
2019-02-31
, without any issues. Time points use them to
store up to nanosecond precision date-times, which are really C++
int64_t
types that don’t nicely fit into any R atomic type
(I am aware of the bit64 package, and made a conscious decision to
implement as a record type instead. This partly had to do with how
missing values are handled, and how that integrates with vctrs).
The idea of a record type actually isn’t new. R’s own POSIXlt type is a record type:
x <- as.POSIXct("2019-01-01", "America/New_York")
# POSIXct is implemented as a double
unclass(x)
#> [1] 1546318800
#> attr(,"tzone")
#> [1] "America/New_York"
# POSIXlt is a record type
unclass(as.POSIXlt(x))
#> $sec
#> [1] 0
#>
#> $min
#> [1] 0
#>
#> $hour
#> [1] 0
#>
#> $mday
#> [1] 1
#>
#> $mon
#> [1] 0
#>
#> $year
#> [1] 119
#>
#> $wday
#> [1] 2
#>
#> $yday
#> [1] 0
#>
#> $isdst
#> [1] 0
#>
#> $zone
#> [1] "EST"
#>
#> $gmtoff
#> [1] -18000
#>
#> attr(,"tzone")
#> [1] "America/New_York" "EST" "EDT"
#> attr(,"balanced")
#> [1] TRUE
data.table doesn’t truly support POSIXlt either. Instead, you get a warning about them converting it to a POSIXct. This is pretty reasonable considering their focus on performance.
data.table(x = as.POSIXlt("2019-01-01", "America/New_York"))
#> x
#> 1: 2019-01-01
#> Warning message:
#> In as.data.table.list(x, keep.rownames = keep.rownames, check.names = check.names, :
#> POSIXlt column type detected and converted to POSIXct. We do not recommend use of POSIXlt at all because it uses 40 bytes to store one date.
It was previously a bit difficult to create record types in R because
there were few examples and no resources to build on. In vctrs, we’ve
added a vctrs_rcrd
type that serves as a base to build new
record types on. Many S3 methods have been written for
vctrs_rcrd
s in a way that should work for any type that
builds on top of it, giving you a lot of scaffolding for free.
I am hopeful that as more record types make their way into the R ecosystem built on this common foundation, it might be possible for data.table to enable this as an approved type in their package.
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They may not be fully stable and should be used with caution. We make no claims about them.