Users can pick dates as shown in the following screen shot:
Any starting month/day and ending month/day combinations are valid, such as:
- Mar 22 to Jun 22
- Dec 1 to Feb 28
The second combination is difficult (I call it the "tricky date scenario") because the year for the ending month/day should come after the year for the starting month/day. That is to say, for the year 1900 (also shown selected in the screen shot above), the full dates would be:
- Dec 22, 1900 to Feb 28, 1901
- Dec 22, 1901 to Feb 28, 1902
- Dec 22, 2007 to Feb 28, 2008
- Dec 22, 2008 to Feb 28, 2009
Writing a SQL statement that selects values from a table with dates that fall between the start month/day and end month/day, regardless of how the start and end days are selected. In other words, this is a year wrapping problem.
The query receives as parameters:
- Year1, Year2: The full range of years, independent of month/day combination.
- Month1, Day1: The starting day within the year to gather data.
- Month2, Day2: The ending day within the year (or the next year) to gather data.
Consider the following MySQL code (that worked):
end_year = start_year + greatest( -1 * sign( datediff( date( concat_ws('-', year, end_month, end_day ) ), date( concat_ws('-', year, start_month, start_day ) ) ) ), 0 )
How it works, with respect to the tricky date scenario:
- Create two dates in the current year.
- The first date is Dec 22, 1900 and the second date is Feb 28, 1900.
- Count the difference, in days, between the two dates.
- If the result is negative, it means the year for the second date must be incremented by 1. In this case:
- Add 1 to the current year.
- Create a new end date: Feb 28, 1901.
- Check to see if the date range for the data falls between the start and calculated end date.
- If the result is positive, the dates have been provided in chronological order and nothing special needs to be done.
This worked in MySQL because the difference in dates would be positive or negative.
In PostgreSQL, the equivalent functionality always returns a positive number, regardless of their relative chronological order. (My tests of subtracting dates may have been incorrect, though.)
How should the following (broken) code be rewritten for PostgreSQL to take into consideration the relative chronological order of the starting and ending month/day pairs (with respect to introducing that tricky annual temporal displacement)?
SELECT m.amount FROM measurement m WHERE (extract(MONTH FROM m.taken) >= month1 AND extract(DAY FROM m.taken) >= day1) AND (extract(MONTH FROM m.taken) <= month2 AND extract(DAY FROM m.taken) <= day2)
Any thoughts, comments, or questions?
(The dates are pre-parsed into MM/DD format in PHP. My preference is for a pure PostgreSQL solution, but I am open to suggestions on what might make the problem simpler using PHP. The SQL lives in a stored procedure that is called by JasperReports, so the only items PHP can touch are the dates passed into the reporting engine.)
The following code nearly works:
select (extract(YEAR FROM m.taken)||'-12-12')::date as start_date, ((extract(YEAR FROM m.taken)+ greatest( 0, sign( (extract(YEAR FROM m.taken)||'-12-12')::date - (extract(YEAR FROM m.taken)||'-02-01')::date) ))||'-02-01')::date as end_date, m.taken, extract(YEAR FROM m.taken) as year_taken from measurement m where m.station_id = 200 AND m.category_id = 1 AND (m.taken, m.taken) OVERLAPS ((extract(YEAR FROM m.taken)||'-12-12')::date, ((extract(YEAR FROM m.taken)+ greatest( 0, sign( (extract(YEAR FROM m.taken)||'-12-12')::date - (extract(YEAR FROM m.taken)||'-02-01')::date) ))||'-02-01')::date)
It produces the correct start and end date constraints:
start_date ;end_date ;taken ;year_taken "1969-12-12";"1970-02-01";"1969-12-12";1969 "1969-12-12";"1970-02-01";"1969-12-13";1969 ... "1969-12-12";"1970-02-01";"1969-12-31";1969 "1970-12-12";"1971-02-01";"1970-12-12";1970
However, the values between
1970-02-01 are missing, but must be included.
PostgreSQL 8.4.4 and PHP 5.2.10