The pgtypes library maps PostgreSQL database types to C equivalents that can be used in C programs. It also offers functions to do basic calculations with those types within C, i.e., without the help of the PostgreSQL server. See the following example:
EXEC SQL BEGIN DECLARE SECTION; date date1; timestamp ts1, tsout; interval iv1; char *out; EXEC SQL END DECLARE SECTION; PGTYPESdate_today(&date1); EXEC SQL SELECT started, duration INTO :ts1, :iv1 FROM datetbl WHERE d=:date1; PGTYPEStimestamp_add_interval(&ts1, &iv1, &tsout); out = PGTYPEStimestamp_to_asc(&tsout); printf("Started + duration: %s\n", out); PGTYPESchar_free(out);
Some functions such as PGTYPESnumeric_to_asc
return
a pointer to a freshly allocated character string. These results should be
freed with PGTYPESchar_free
instead of
free
. (This is important only on Windows, where
memory allocation and release sometimes need to be done by the same
library.)
The numeric type offers to do calculations with arbitrary precision. See
Section 8.1 for the equivalent type in the
PostgreSQL server. Because of the arbitrary precision this
variable needs to be able to expand and shrink dynamically. That's why you
can only create numeric variables on the heap, by means of the
PGTYPESnumeric_new
and PGTYPESnumeric_free
functions. The decimal type, which is similar but limited in precision,
can be created on the stack as well as on the heap.
The following functions can be used to work with the numeric type:
PGTYPESnumeric_new
#Request a pointer to a newly allocated numeric variable.
numeric *PGTYPESnumeric_new(void);
PGTYPESnumeric_free
#Free a numeric type, release all of its memory.
void PGTYPESnumeric_free(numeric *var);
PGTYPESnumeric_from_asc
#Parse a numeric type from its string notation.
numeric *PGTYPESnumeric_from_asc(char *str, char **endptr);
Valid formats are for example:
-2
,
.794
,
+3.44
,
592.49E07
or
-32.84e-4
.
If the value could be parsed successfully, a valid pointer is returned,
else the NULL pointer. At the moment ECPG always parses the complete
string and so it currently does not support to store the address of the
first invalid character in *endptr
. You can safely
set endptr
to NULL.
PGTYPESnumeric_to_asc
#
Returns a pointer to a string allocated by malloc
that contains the string
representation of the numeric type num
.
char *PGTYPESnumeric_to_asc(numeric *num, int dscale);
The numeric value will be printed with dscale
decimal
digits, with rounding applied if necessary.
The result must be freed with PGTYPESchar_free()
.
PGTYPESnumeric_add
#Add two numeric variables into a third one.
int PGTYPESnumeric_add(numeric *var1, numeric *var2, numeric *result);
The function adds the variables var1
and
var2
into the result variable
result
.
The function returns 0 on success and -1 in case of error.
PGTYPESnumeric_sub
#Subtract two numeric variables and return the result in a third one.
int PGTYPESnumeric_sub(numeric *var1, numeric *var2, numeric *result);
The function subtracts the variable var2
from
the variable var1
. The result of the operation is
stored in the variable result
.
The function returns 0 on success and -1 in case of error.
PGTYPESnumeric_mul
#Multiply two numeric variables and return the result in a third one.
int PGTYPESnumeric_mul(numeric *var1, numeric *var2, numeric *result);
The function multiplies the variables var1
and
var2
. The result of the operation is stored in the
variable result
.
The function returns 0 on success and -1 in case of error.
PGTYPESnumeric_div
#Divide two numeric variables and return the result in a third one.
int PGTYPESnumeric_div(numeric *var1, numeric *var2, numeric *result);
The function divides the variables var1
by
var2
. The result of the operation is stored in the
variable result
.
The function returns 0 on success and -1 in case of error.
PGTYPESnumeric_cmp
#Compare two numeric variables.
int PGTYPESnumeric_cmp(numeric *var1, numeric *var2)
This function compares two numeric variables. In case of error,
INT_MAX
is returned. On success, the function
returns one of three possible results:
1, if var1
is bigger than var2
-1, if var1
is smaller than var2
0, if var1
and var2
are equal
PGTYPESnumeric_from_int
#Convert an int variable to a numeric variable.
int PGTYPESnumeric_from_int(signed int int_val, numeric *var);
This function accepts a variable of type signed int and stores it
in the numeric variable var
. Upon success, 0 is returned and
-1 in case of a failure.
PGTYPESnumeric_from_long
#Convert a long int variable to a numeric variable.
int PGTYPESnumeric_from_long(signed long int long_val, numeric *var);
This function accepts a variable of type signed long int and stores it
in the numeric variable var
. Upon success, 0 is returned and
-1 in case of a failure.
PGTYPESnumeric_copy
#Copy over one numeric variable into another one.
int PGTYPESnumeric_copy(numeric *src, numeric *dst);
This function copies over the value of the variable that
src
points to into the variable that dst
points to. It returns 0 on success and -1 if an error occurs.
PGTYPESnumeric_from_double
#Convert a variable of type double to a numeric.
int PGTYPESnumeric_from_double(double d, numeric *dst);
This function accepts a variable of type double and stores the result
in the variable that dst
points to. It returns 0 on success
and -1 if an error occurs.
PGTYPESnumeric_to_double
#Convert a variable of type numeric to double.
int PGTYPESnumeric_to_double(numeric *nv, double *dp)
The function converts the numeric value from the variable that
nv
points to into the double variable that dp
points
to. It returns 0 on success and -1 if an error occurs, including
overflow. On overflow, the global variable errno
will be set
to PGTYPES_NUM_OVERFLOW
additionally.
PGTYPESnumeric_to_int
#Convert a variable of type numeric to int.
int PGTYPESnumeric_to_int(numeric *nv, int *ip);
The function converts the numeric value from the variable that
nv
points to into the integer variable that ip
points to. It returns 0 on success and -1 if an error occurs, including
overflow. On overflow, the global variable errno
will be set
to PGTYPES_NUM_OVERFLOW
additionally.
PGTYPESnumeric_to_long
#Convert a variable of type numeric to long.
int PGTYPESnumeric_to_long(numeric *nv, long *lp);
The function converts the numeric value from the variable that
nv
points to into the long integer variable that
lp
points to. It returns 0 on success and -1 if an error
occurs, including overflow. On overflow, the global variable
errno
will be set to PGTYPES_NUM_OVERFLOW
additionally.
PGTYPESnumeric_to_decimal
#Convert a variable of type numeric to decimal.
int PGTYPESnumeric_to_decimal(numeric *src, decimal *dst);
The function converts the numeric value from the variable that
src
points to into the decimal variable that
dst
points to. It returns 0 on success and -1 if an error
occurs, including overflow. On overflow, the global variable
errno
will be set to PGTYPES_NUM_OVERFLOW
additionally.
PGTYPESnumeric_from_decimal
#Convert a variable of type decimal to numeric.
int PGTYPESnumeric_from_decimal(decimal *src, numeric *dst);
The function converts the decimal value from the variable that
src
points to into the numeric variable that
dst
points to. It returns 0 on success and -1 if an error
occurs. Since the decimal type is implemented as a limited version of
the numeric type, overflow cannot occur with this conversion.
The date type in C enables your programs to deal with data of the SQL type date. See Section 8.5 for the equivalent type in the PostgreSQL server.
The following functions can be used to work with the date type:
PGTYPESdate_from_timestamp
#Extract the date part from a timestamp.
date PGTYPESdate_from_timestamp(timestamp dt);
The function receives a timestamp as its only argument and returns the extracted date part from this timestamp.
PGTYPESdate_from_asc
#Parse a date from its textual representation.
date PGTYPESdate_from_asc(char *str, char **endptr);
The function receives a C char* string str
and a pointer to
a C char* string endptr
. At the moment ECPG always parses
the complete string and so it currently does not support to store the
address of the first invalid character in *endptr
.
You can safely set endptr
to NULL.
Note that the function always assumes MDY-formatted dates and there is currently no variable to change that within ECPG.
Table 38.2 shows the allowed input formats.
Table 38.2. Valid Input Formats for PGTYPESdate_from_asc
Input | Result |
---|---|
January 8, 1999 | January 8, 1999 |
1999-01-08 | January 8, 1999 |
1/8/1999 | January 8, 1999 |
1/18/1999 | January 18, 1999 |
01/02/03 | February 1, 2003 |
1999-Jan-08 | January 8, 1999 |
Jan-08-1999 | January 8, 1999 |
08-Jan-1999 | January 8, 1999 |
99-Jan-08 | January 8, 1999 |
08-Jan-99 | January 8, 1999 |
08-Jan-06 | January 8, 2006 |
Jan-08-99 | January 8, 1999 |
19990108 | ISO 8601; January 8, 1999 |
990108 | ISO 8601; January 8, 1999 |
1999.008 | year and day of year |
J2451187 | Julian day |
January 8, 99 BC | year 99 before the Common Era |
PGTYPESdate_to_asc
#Return the textual representation of a date variable.
char *PGTYPESdate_to_asc(date dDate);
The function receives the date dDate
as its only parameter.
It will output the date in the form 1999-01-18
, i.e., in the
YYYY-MM-DD
format.
The result must be freed with PGTYPESchar_free()
.
PGTYPESdate_julmdy
#Extract the values for the day, the month and the year from a variable of type date.
void PGTYPESdate_julmdy(date d, int *mdy);
The function receives the date d
and a pointer to an array
of 3 integer values mdy
. The variable name indicates
the sequential order: mdy[0]
will be set to contain the
number of the month, mdy[1]
will be set to the value of the
day and mdy[2]
will contain the year.
PGTYPESdate_mdyjul
#Create a date value from an array of 3 integers that specify the day, the month and the year of the date.
void PGTYPESdate_mdyjul(int *mdy, date *jdate);
The function receives the array of the 3 integers (mdy
) as
its first argument and as its second argument a pointer to a variable
of type date that should hold the result of the operation.
PGTYPESdate_dayofweek
#Return a number representing the day of the week for a date value.
int PGTYPESdate_dayofweek(date d);
The function receives the date variable d
as its only
argument and returns an integer that indicates the day of the week for
this date.
0 - Sunday
1 - Monday
2 - Tuesday
3 - Wednesday
4 - Thursday
5 - Friday
6 - Saturday
PGTYPESdate_today
#Get the current date.
void PGTYPESdate_today(date *d);
The function receives a pointer to a date variable (d
)
that it sets to the current date.
PGTYPESdate_fmt_asc
#Convert a variable of type date to its textual representation using a format mask.
int PGTYPESdate_fmt_asc(date dDate, char *fmtstring, char *outbuf);
The function receives the date to convert (dDate
), the
format mask (fmtstring
) and the string that will hold the
textual representation of the date (outbuf
).
On success, 0 is returned and a negative value if an error occurred.
The following literals are the field specifiers you can use:
dd
- The number of the day of the month.
mm
- The number of the month of the year.
yy
- The number of the year as a two digit number.
yyyy
- The number of the year as a four digit number.
ddd
- The name of the day (abbreviated).
mmm
- The name of the month (abbreviated).
All other characters are copied 1:1 to the output string.
Table 38.3 indicates a few possible formats. This will give you an idea of how to use this function. All output lines are based on the same date: November 23, 1959.
Table 38.3. Valid Input Formats for PGTYPESdate_fmt_asc
Format | Result |
---|---|
mmddyy | 112359 |
ddmmyy | 231159 |
yymmdd | 591123 |
yy/mm/dd | 59/11/23 |
yy mm dd | 59 11 23 |
yy.mm.dd | 59.11.23 |
.mm.yyyy.dd. | .11.1959.23. |
mmm. dd, yyyy | Nov. 23, 1959 |
mmm dd yyyy | Nov 23 1959 |
yyyy dd mm | 1959 23 11 |
ddd, mmm. dd, yyyy | Mon, Nov. 23, 1959 |
(ddd) mmm. dd, yyyy | (Mon) Nov. 23, 1959 |
PGTYPESdate_defmt_asc
#
Use a format mask to convert a C char*
string to a value of type
date.
int PGTYPESdate_defmt_asc(date *d, char *fmt, char *str);
The function receives a pointer to the date value that should hold the
result of the operation (d
), the format mask to use for
parsing the date (fmt
) and the C char* string containing
the textual representation of the date (str
). The textual
representation is expected to match the format mask. However you do not
need to have a 1:1 mapping of the string to the format mask. The
function only analyzes the sequential order and looks for the literals
yy
or yyyy
that indicate the
position of the year, mm
to indicate the position of
the month and dd
to indicate the position of the
day.
Table 38.4 indicates a few possible formats. This will give you an idea of how to use this function.
Table 38.4. Valid Input Formats for rdefmtdate
Format | String | Result |
---|---|---|
ddmmyy | 21-2-54 | 1954-02-21 |
ddmmyy | 2-12-54 | 1954-12-02 |
ddmmyy | 20111954 | 1954-11-20 |
ddmmyy | 130464 | 1964-04-13 |
mmm.dd.yyyy | MAR-12-1967 | 1967-03-12 |
yy/mm/dd | 1954, February 3rd | 1954-02-03 |
mmm.dd.yyyy | 041269 | 1969-04-12 |
yy/mm/dd | In the year 2525, in the month of July, mankind will be alive on the 28th day | 2525-07-28 |
dd-mm-yy | I said on the 28th of July in the year 2525 | 2525-07-28 |
mmm.dd.yyyy | 9/14/58 | 1958-09-14 |
yy/mm/dd | 47/03/29 | 1947-03-29 |
mmm.dd.yyyy | oct 28 1975 | 1975-10-28 |
mmddyy | Nov 14th, 1985 | 1985-11-14 |
The timestamp type in C enables your programs to deal with data of the SQL type timestamp. See Section 8.5 for the equivalent type in the PostgreSQL server.
The following functions can be used to work with the timestamp type:
PGTYPEStimestamp_from_asc
#Parse a timestamp from its textual representation into a timestamp variable.
timestamp PGTYPEStimestamp_from_asc(char *str, char **endptr);
The function receives the string to parse (str
) and a
pointer to a C char* (endptr
).
At the moment ECPG always parses
the complete string and so it currently does not support to store the
address of the first invalid character in *endptr
.
You can safely set endptr
to NULL.
The function returns the parsed timestamp on success. On error,
PGTYPESInvalidTimestamp
is returned and errno
is
set to PGTYPES_TS_BAD_TIMESTAMP
. See PGTYPESInvalidTimestamp
for important notes on this value.
In general, the input string can contain any combination of an allowed date specification, a whitespace character and an allowed time specification. Note that time zones are not supported by ECPG. It can parse them but does not apply any calculation as the PostgreSQL server does for example. Timezone specifiers are silently discarded.
Table 38.5 contains a few examples for input strings.
Table 38.5. Valid Input Formats for PGTYPEStimestamp_from_asc
Input | Result |
---|---|
1999-01-08 04:05:06 | 1999-01-08 04:05:06 |
January 8 04:05:06 1999 PST | 1999-01-08 04:05:06 |
1999-Jan-08 04:05:06.789-8 | 1999-01-08 04:05:06.789 (time zone specifier ignored) |
J2451187 04:05-08:00 | 1999-01-08 04:05:00 (time zone specifier ignored) |
PGTYPEStimestamp_to_asc
#Converts a date to a C char* string.
char *PGTYPEStimestamp_to_asc(timestamp tstamp);
The function receives the timestamp tstamp
as
its only argument and returns an allocated string that contains the
textual representation of the timestamp.
The result must be freed with PGTYPESchar_free()
.
PGTYPEStimestamp_current
#Retrieve the current timestamp.
void PGTYPEStimestamp_current(timestamp *ts);
The function retrieves the current timestamp and saves it into the
timestamp variable that ts
points to.
PGTYPEStimestamp_fmt_asc
#Convert a timestamp variable to a C char* using a format mask.
int PGTYPEStimestamp_fmt_asc(timestamp *ts, char *output, int str_len, char *fmtstr);
The function receives a pointer to the timestamp to convert as its
first argument (ts
), a pointer to the output buffer
(output
), the maximal length that has been allocated for
the output buffer (str_len
) and the format mask to
use for the conversion (fmtstr
).
Upon success, the function returns 0 and a negative value if an error occurred.
You can use the following format specifiers for the format mask. The
format specifiers are the same ones that are used in the
strftime
function in libc. Any
non-format specifier will be copied into the output buffer.
%A
- is replaced by national representation of
the full weekday name.
%a
- is replaced by national representation of
the abbreviated weekday name.
%B
- is replaced by national representation of
the full month name.
%b
- is replaced by national representation of
the abbreviated month name.
%C
- is replaced by (year / 100) as decimal
number; single digits are preceded by a zero.
%c
- is replaced by national representation of
time and date.
%D
- is equivalent to
%m/%d/%y
.
%d
- is replaced by the day of the month as a
decimal number (01–31).
%E*
%O*
- POSIX locale
extensions. The sequences
%Ec
%EC
%Ex
%EX
%Ey
%EY
%Od
%Oe
%OH
%OI
%Om
%OM
%OS
%Ou
%OU
%OV
%Ow
%OW
%Oy
are supposed to provide alternative representations.
Additionally %OB
implemented to represent
alternative months names (used standalone, without day mentioned).
%e
- is replaced by the day of month as a decimal
number (1–31); single digits are preceded by a blank.
%F
- is equivalent to %Y-%m-%d
.
%G
- is replaced by a year as a decimal number
with century. This year is the one that contains the greater part of
the week (Monday as the first day of the week).
%g
- is replaced by the same year as in
%G
, but as a decimal number without century
(00–99).
%H
- is replaced by the hour (24-hour clock) as a
decimal number (00–23).
%h
- the same as %b
.
%I
- is replaced by the hour (12-hour clock) as a
decimal number (01–12).
%j
- is replaced by the day of the year as a
decimal number (001–366).
%k
- is replaced by the hour (24-hour clock) as a
decimal number (0–23); single digits are preceded by a blank.
%l
- is replaced by the hour (12-hour clock) as a
decimal number (1–12); single digits are preceded by a blank.
%M
- is replaced by the minute as a decimal
number (00–59).
%m
- is replaced by the month as a decimal number
(01–12).
%n
- is replaced by a newline.
%O*
- the same as %E*
.
%p
- is replaced by national representation of
either “ante meridiem” or “post meridiem” as appropriate.
%R
- is equivalent to %H:%M
.
%r
- is equivalent to %I:%M:%S
%p
.
%S
- is replaced by the second as a decimal
number (00–60).
%s
- is replaced by the number of seconds since
the Epoch, UTC.
%T
- is equivalent to %H:%M:%S
%t
- is replaced by a tab.
%U
- is replaced by the week number of the year
(Sunday as the first day of the week) as a decimal number (00–53).
%u
- is replaced by the weekday (Monday as the
first day of the week) as a decimal number (1–7).
%V
- is replaced by the week number of the year
(Monday as the first day of the week) as a decimal number (01–53).
If the week containing January 1 has four or more days in the new
year, then it is week 1; otherwise it is the last week of the
previous year, and the next week is week 1.
%v
- is equivalent to
%e-%b-%Y
.
%W
- is replaced by the week number of the year
(Monday as the first day of the week) as a decimal number (00–53).
%w
- is replaced by the weekday (Sunday as the
first day of the week) as a decimal number (0–6).
%X
- is replaced by national representation of
the time.
%x
- is replaced by national representation of
the date.
%Y
- is replaced by the year with century as a
decimal number.
%y
- is replaced by the year without century as a
decimal number (00–99).
%Z
- is replaced by the time zone name.
%z
- is replaced by the time zone offset from
UTC; a leading plus sign stands for east of UTC, a minus sign for
west of UTC, hours and minutes follow with two digits each and no
delimiter between them (common form for RFC 822 date headers).
%+
- is replaced by national representation of
the date and time.
%-*
- GNU libc extension. Do not do any padding
when performing numerical outputs.
$_* - GNU libc extension. Explicitly specify space for padding.
%0*
- GNU libc extension. Explicitly specify zero
for padding.
%%
- is replaced by %
.
PGTYPEStimestamp_sub
#Subtract one timestamp from another one and save the result in a variable of type interval.
int PGTYPEStimestamp_sub(timestamp *ts1, timestamp *ts2, interval *iv);
The function will subtract the timestamp variable that ts2
points to from the timestamp variable that ts1
points to
and will store the result in the interval variable that iv
points to.
Upon success, the function returns 0 and a negative value if an error occurred.
PGTYPEStimestamp_defmt_asc
#Parse a timestamp value from its textual representation using a formatting mask.
int PGTYPEStimestamp_defmt_asc(char *str, char *fmt, timestamp *d);
The function receives the textual representation of a timestamp in the
variable str
as well as the formatting mask to use in the
variable fmt
. The result will be stored in the variable
that d
points to.
If the formatting mask fmt
is NULL, the function will fall
back to the default formatting mask which is %Y-%m-%d
%H:%M:%S
.
This is the reverse function to PGTYPEStimestamp_fmt_asc
. See the documentation there in
order to find out about the possible formatting mask entries.
PGTYPEStimestamp_add_interval
#Add an interval variable to a timestamp variable.
int PGTYPEStimestamp_add_interval(timestamp *tin, interval *span, timestamp *tout);
The function receives a pointer to a timestamp variable tin
and a pointer to an interval variable span
. It adds the
interval to the timestamp and saves the resulting timestamp in the
variable that tout
points to.
Upon success, the function returns 0 and a negative value if an error occurred.
PGTYPEStimestamp_sub_interval
#Subtract an interval variable from a timestamp variable.
int PGTYPEStimestamp_sub_interval(timestamp *tin, interval *span, timestamp *tout);
The function subtracts the interval variable that span
points to from the timestamp variable that tin
points to
and saves the result into the variable that tout
points
to.
Upon success, the function returns 0 and a negative value if an error occurred.
The interval type in C enables your programs to deal with data of the SQL type interval. See Section 8.5 for the equivalent type in the PostgreSQL server.
The following functions can be used to work with the interval type:
PGTYPESinterval_new
#Return a pointer to a newly allocated interval variable.
interval *PGTYPESinterval_new(void);
PGTYPESinterval_free
#Release the memory of a previously allocated interval variable.
void PGTYPESinterval_free(interval *intvl);
PGTYPESinterval_from_asc
#Parse an interval from its textual representation.
interval *PGTYPESinterval_from_asc(char *str, char **endptr);
The function parses the input string str
and returns a
pointer to an allocated interval variable.
At the moment ECPG always parses
the complete string and so it currently does not support to store the
address of the first invalid character in *endptr
.
You can safely set endptr
to NULL.
PGTYPESinterval_to_asc
#Convert a variable of type interval to its textual representation.
char *PGTYPESinterval_to_asc(interval *span);
The function converts the interval variable that span
points to into a C char*. The output looks like this example:
@ 1 day 12 hours 59 mins 10 secs
.
The result must be freed with PGTYPESchar_free()
.
PGTYPESinterval_copy
#Copy a variable of type interval.
int PGTYPESinterval_copy(interval *intvlsrc, interval *intvldest);
The function copies the interval variable that intvlsrc
points to into the variable that intvldest
points to. Note
that you need to allocate the memory for the destination variable
before.
The decimal type is similar to the numeric type. However it is limited to
a maximum precision of 30 significant digits. In contrast to the numeric
type which can be created on the heap only, the decimal type can be
created either on the stack or on the heap (by means of the functions
PGTYPESdecimal_new
and
PGTYPESdecimal_free
).
There are a lot of other functions that deal with the decimal type in the
Informix compatibility mode described in Section 38.15.
The following functions can be used to work with the decimal type and are
not only contained in the libcompat
library.
PGTYPES_NUM_BAD_NUMERIC
#An argument should contain a numeric variable (or point to a numeric variable) but in fact its in-memory representation was invalid.
PGTYPES_NUM_OVERFLOW
#An overflow occurred. Since the numeric type can deal with almost arbitrary precision, converting a numeric variable into other types might cause overflow.
PGTYPES_NUM_UNDERFLOW
#An underflow occurred. Since the numeric type can deal with almost arbitrary precision, converting a numeric variable into other types might cause underflow.
PGTYPES_NUM_DIVIDE_ZERO
#A division by zero has been attempted.
PGTYPES_DATE_BAD_DATE
#
An invalid date string was passed to
the PGTYPESdate_from_asc
function.
PGTYPES_DATE_ERR_EARGS
#
Invalid arguments were passed to the
PGTYPESdate_defmt_asc
function.
PGTYPES_DATE_ERR_ENOSHORTDATE
#
An invalid token in the input string was found by the
PGTYPESdate_defmt_asc
function.
PGTYPES_INTVL_BAD_INTERVAL
#
An invalid interval string was passed to the
PGTYPESinterval_from_asc
function, or an
invalid interval value was passed to the
PGTYPESinterval_to_asc
function.
PGTYPES_DATE_ERR_ENOTDMY
#
There was a mismatch in the day/month/year assignment in the
PGTYPESdate_defmt_asc
function.
PGTYPES_DATE_BAD_DAY
#
An invalid day of the month value was found by
the PGTYPESdate_defmt_asc
function.
PGTYPES_DATE_BAD_MONTH
#
An invalid month value was found by
the PGTYPESdate_defmt_asc
function.
PGTYPES_TS_BAD_TIMESTAMP
#
An invalid timestamp string pass passed to
the PGTYPEStimestamp_from_asc
function,
or an invalid timestamp value was passed to
the PGTYPEStimestamp_to_asc
function.
PGTYPES_TS_ERR_EINFTIME
#An infinite timestamp value was encountered in a context that cannot handle it.
PGTYPESInvalidTimestamp
#
A value of type timestamp representing an invalid time stamp. This is
returned by the function PGTYPEStimestamp_from_asc
on
parse error.
Note that due to the internal representation of the timestamp
data type,
PGTYPESInvalidTimestamp
is also a valid timestamp at
the same time. It is set to 1899-12-31 23:59:59
. In order
to detect errors, make sure that your application does not only test
for PGTYPESInvalidTimestamp
but also for
errno != 0
after each call to
PGTYPEStimestamp_from_asc
.