Provided by: libstring-print-perl_0.94-2_all 
NAME
String::Print - printf alternative
SYNOPSIS
### Functional interface
use String::Print; # simpelest way
use String::Print qw/printi printp/, %config;
printi 'age {years}', years => 12;
# interpolation of arrays and hashes (serializers)
printi 'price-list: {prices}', prices => \@p, _join => "+";
printi 'dump: {c}', c => \%config;
# same with positional parameters
printp 'age %d", 12;
printp 'price-list: %.2f', \@prices;
printp 'dump: %s', \%settings;
# modifiers
printi 'price: {price%.2f}', price => 3.14*VAT*EURO;
# [0.91] more complex interpolation names
printi 'filename: {c.filename}', c => \%config;
printi 'username: {user.name}', user => $user_object;
printi 'price: {product.price €}', product => $db->product(3);
### Object Oriented interface
use String::Print 'oo'; # import nothing
my $f = String::Print->new(%config);
$f->printi('age {years}', years => 12);
$f->printp('age %d', 12);
### via Log::Report's __* functions (optional translation)
use Log::Report; # or Log::Report::Optional
print __x"age {years}", years => 12;
### via Log::Report::Template (Template Toolkit extension)
[% SET name = 'John Doe' %]
[% loc("Dear {name},") %] # includes translation
DESCRIPTION
This module inserts values into (format) strings. It provides "printf" and "sprintf" alternatives via
both an object oriented and a functional interface.
Read in the "DETAILS" chapter below, why this module provides a better alternative for "printf()". Also,
some extended examples can be found down there. Take a look at them first, when you start using this
module!
METHODS
The Object Oriented interface
See functions printi(), sprinti(), printp(), and sprintp(): you can also call them as method.
use String::Print 'oo';
my $f = String::Print->new(%config);
$f->printi($format, @params);
# exactly the same functionality:
use String::Print 'printi', %config;
printi $format, @params;
The Object Oriented interface wins when you need the same configuration in multiple source files, or when
you need different configurations within one program. In these cases, the hassle of explicitly using the
object has some benefits.
Constructors
String::Print->new(%options)
-Option --Default
encode_for undef
missing_key <warning>
modifiers [ qr/^%\S+/ = \&format_printf]>
serializers <useful defaults>
encode_for => HASH|'HTML'
[0.91] The format string and the inserted values will get encoded according to some syntax rules.
For instance, "encode_entities()" of HTML::Entities when you specify the predefined string "HTML".
See encodeFor().
missing_key => CODE
[0.91] During interpolation, it may be discovered that a key is missing from the parameter list.
In that case, a warning is produced and "undef" inserted. May can overrule that behavior.
modifiers => ARRAY
Add one or more modifier handlers to power of the formatter. They will get preference over the
predefined modifiers, but lower than the modifiers passed to "print[ip]" itself.
serializers => HASH|ARRAY
How to serialize data elements.
example:
my $f = String::Print->new
( modifiers => [ EUR => sub {sprintf "%5.2f e", $_[0]} ]
, serializers => [ UNDEF => sub {'-'} ]
, encode_for => 'HTML'
);
$f->printi("price: {p EUR}", p => 3.1415); # price: ␣␣3.14 e
$f->printi("count: {c}", c => undef); # count: -
Attributes
$obj->addModifiers(PAIRS)
The PAIRS are a combination of an selector and a CODE which processes the value when the modifier
matches. The selector is a string or (preferred) a regular expression. Later modifiers with the same
name overrule earlier definitions. You may also specify an ARRAY of modifiers per "print".
See section "Interpolation: Modifiers" about the details.
$obj->encodeFor(HASH|undef|($predefined, %overrule))
[0.91] Enable/define the output encoding. Read section "Output encoding" about the details.
Printing
The following are provided as method and as function. You find their explanation further down on this
page.
$obj->printi([$fh], $format, PAIRS|HASH);
$obj->printp([$fh], $format, PAIRS|HASH);
$obj->sprinti($format, PAIRS|HASH);
$obj->sprintp($format, LIST, PAIRS);
FUNCTIONS
The functional interface creates a hidden object. You may import any of these functions explicitly, or
all together by not specifying the names.
. Example
use String::Print; # all
use String::Print 'sprinti'; # only sprinti
use String::Print 'printi' # only printi
, modifiers => [ EUR => sub {sprintf "%5.2f e", $_[0]} ]
, serializers => [ UNDEF => sub {'-'} ];
printi "price: {p EUR}", p => 3.1415; # price: ␣␣3.14 e
printi "count: {c}", c => undef; # count: -
printi( [$fh], $format, PAIRS|HASH )
Calls sprinti() to fill the data in PAIRS or HASH in $format, and then sends it to the $fh (by
default the selected file)
open my $fh, '>', $file;
printi $fh, ...
printi \*STDERR, ...
printp( [$fh], $format, PAIRS|HASH )
Calls sprintp() to fill the data in PAIRS or HASH in $format, and then sends it to the $fh (by
default the selected file)
sprinti($format, PAIRS|HASH|OBJECT)
The $format refers to some string, maybe the result of a translation.
The PAIRS (which may be passed as LIST, HASH, or blessed HASH) contains a mixture of special and
normal variables to be filled in. The names of the special variables (the options) start with an
underscore ("_").
-Option --Default
_append undef
_count undef
_join ', '
_prepend undef
_append => STRING|OBJECT
Text as STRING appended after $format, without interpolation.
_count => INTEGER
Result of the translation process: when Log::Report subroutine __xn is are used for count-sensitive
translation. Those function may add more specials to the parameter list.
_join => STRING
Which STRING to use when an ARRAY is being filled-in as parameter.
_prepend => STRING|OBJECT
Text as STRING prepended before $format, without interpolation. This may also be an OBJECT which
gets stringified, but variables not filled-in.
sprintp($format, LIST, PAIRS)
Where sprinti() uses named parameters --especially useful when the strings need translation-- this
function stays close to the standard "sprintf()". All features of POSIX formats are supported. This
should say enough: you can use "%3$0#5.*d", if you like.
It may be useful to know that the positional $format is rewritten and then fed into sprinti(). Be
careful with the length of the LIST: superfluous parameter PAIRS are passed along to "sprinti()", and
should only contain "specials": parameter names which start with '_'.
example: of the rewrite
# positional parameters
my $x = sprintp "dumpfiles: %s\n", \@dumpfiles
, _join => ':';
# is rewritten into, and then processed as
my $x = sprinti "dumpfiles: {_1}\n"
, _1 => \@dumpfiles, _join => ':';
DETAILS
Why use "printi()", not "printf()"?
The "printf()" function is provided by Perl's CORE; you do not need to install any module to use it. Why
would you use consider using this module?
translating
"printf()" uses positional parameters, where printi() uses names to refer to the values to be filled-
in. Especially in a set-up with translations, where the format strings get extracted into PO-files,
it is much clearer to use names. This is also a disadvantage of printp()
pluggable serializers
"printi()" supports serialization for specific data-types: how to interpolate "undef", HASHes, etc.
pluggable modifiers
Especially useful in context of translations, the FORMAT string may contain (language specific)
helpers to insert the values correctly.
correct use of utf8
Sized string formatting in "printf()" is broken: it takes your string as bytes, not Perl strings
(which may be utf8). In unicode, one "character" may use many bytes. Also, some characters are
displayed double wide, for instance in Chinese. The printi() implementation will use
Unicode::GCString for correct behavior.
automatic output encoding (for HTML)
You can globally declare that all produced strings must be encoded in a certain format, for instance
that HTML entities should be encoded.
Four components
To fill-in a FORMAT, four clearly separated components play a role:
1. modifiers
How to change the provided values, for instance to hide locale differences.
2. serializer
How to represent (the modified) the values correctly, for instance "undef" and ARRAYs.
3. conversion
The standard UNIX format rules, like %d. One conversion rule has been added 'S', which provides
unicode correct behavior.
4. encoding
Prepare the output for a certain syntax, like HTML.
Simplified:
# sprinti() replaces "{$key$modifiers$conversion}" by
$encode->($format->($serializer->($modifiers->($args{$key}))))
# sprintp() replaces "%pos{$modifiers}$conversion" by
$encode->($format->($serializer->($modifiers->($arg[$pos]))))
Example:
#XXX Your manual-page reader may not support the unicode used
#XXX in the examples below.
printi "price: {price € %-10s}", price => $cost;
printi "price: {price € %-10s}", { price => $cost };
printp "price: %-10{€}s", $cost;
$value = $cost (in €)
$modifier = convert € to local currency £
$serializer = show float as string
$format = column width %-10s
$encode = £ into £ # when encodingFor('HTML')
Interpolation: keys
A key is a bareword (like a variable name) or a list of barewords separated by dots (no blanks!)
Please use explanatory key names, to help the translation process once you need that (in the future).
Simple keys
A simple key directly refers to a named parameter of the function or method:
printi "Username: {name}", name => 'John';
You may also pass them as HASH or CODE:
printi "Username: {name}", { name => 'John' };
printi "Username: {name}", name => sub { 'John' };
printi "Username: {name}", { name => sub { 'John' } };
printi "Username: {name}", name => sub { sub {'John'} };
The smartness of pre-processing CODE is part of serialization.
Complex keys
[0.91] In the previous section, we kept our addressing it simple: let's change that now. Two
alternatives for the same:
my $user = { name => 'John' };
printi "Username: {name}", name => $user->{name}; # simple key
printi "Username: {user.name}", user => $user; # complex key
The way these complex keys work, is close to the flexibility of template toolkit: the only thing you
cannot do, is passing parameters to called CODE.
You can pass a parameter name as HASH, which contains values. This may even be nested into multiple
levels. You may also pass objects, class (package names), and code references.
In above case of "user.name", when "user" is a HASH it will take the value which belongs to the key
"name". When "user" is a CODE, it will run code to get a value. When "user" is an object, the method
"name" is called to get a value back. When "user" is a class name, the "name" refers to an instance
method on that class.
More examples which do work:
# when name is a column in the database query result
printi "Username: {user.name}", user => $sth->fetchrow_hashref;
# call a sub which does the database query, returning a HASH
printi "Username: {user.name}", user => sub { $db->getUser('John') };
# using an instance method (object)
{ package User;
sub new { bless { myname => $_[1] }, $_[0] }
sub name { $_[0]->{myname} }
}
my $user = User->new('John');
printi "Username: {user.name}", user => $user;
# using a class method
sub User::count { 42 }
printi "Username: {user.count}", user => 'User';
# nesting, mixing
printi "Complain to {product.factory.address}", product => $p;
# mixed, here CODE, HASH, and Object
printi "Username: {document.author.name}", document => sub {
return +{ author => User->new('John') }
};
Limitation: you cannot pass arguments to CODE calls.
Interpolation: Serialization
The 'interpolation' functions have named VARIABLES to be filled-in, but also additional OPTIONS. To
distinguish between the OPTIONS and VARIABLES (both a list of key-value pairs), the keys of the OPTIONS
start with an underscore "_". As result of this, please avoid the use of keys which start with an
underscore in variable names. On the other hand, you are allowed to interpolate OPTION values in your
strings.
There is no way of checking beforehand whether you have provided all values to be interpolated in the
translated string. When you refer to value which is missing, it will be interpreted as "undef".
strings
Simple scalar values are interpolated "as is"
CODE
When a value is passed as CODE reference, that function will get called to return the value to be
filled in. For interpolating, the following rules apply:
SCALAR
Takes the value where the scalar reference points to.
ARRAY
All members will be interpolated with ",␣" between the elements. Alternatively (maybe nicer), you
can pass an interpolation parameter via the "_join" OPTION.
printi "matching files: {files}", files => \@files, _join => ', '
HASH
By default, HASHes are interpolated with sorted keys,
$key => $value, $key2 => $value2, ...
There is no quoting on the keys or values (yet). Usually, this will produce an ugly result anyway.
Objects
With the "serialization" parameter, you can overrule the interpolation of above defaults, but also
add rules for your own objects. By default, objects get stringified.
serialization => [ $myclass => \&name_in_reverse ]
sub name_in_reverse($$$)
{ my ($formatter, $object, $args) = @_;
# the $args are all parameters to be filled-in
scalar reverse $object->name;
}
Interpolation: Modifiers
Modifiers are used to change the value to be inserted, before the characters get interpolated in the
line. This is a powerful simplification. Let's discuss this with an example.
In traditional (gnu) gettext, you would write:
printf(gettext("approx pi: %.6f\n"), PI);
to get PI printed with six digits in the fragment. Locale::TextDomain has two ways to achieve that:
printf __"approx pi: %.6f\n", PI;
print __x"approx pi: {approx}\n", approx => sprintf("%.6f", PI);
The first does not respect the wish to be able to reorder the arguments during translation (although
there are ways to work around that) The second version is quite long. The string to be translated
differs between the two examples.
With "Log::Report", above syntaxes do work as well, but you can also do:
# with optional translations
print __x"approx pi: {pi%.6f}\n", pi => PI;
The base for "__x()" is the printi() provided by this module. Internally, it will call "printi" to fill-
in parameters:
printi "approx pi: {pi%.6f}\n", pi => PI;
Another example:
printi "{perms} {links%2d} {user%-8s} {size%10d} {fn}\n",
perms => '-rw-r--r--', links => 7, user => 'me',
size => 12345, fn => $filename;
An additional advantage (when you use translation) is the fact that not all languages produce comparable
length strings. Now, the translators can change the format, such that the layout of tables is optimal
for their language.
Above example in printp() syntax, shorter but less maintainable:
printp "%s %2d %-8s 10d %s\n",
'-rw-r--r--', 7, 'me', 12345, $filename;
Interpolation: default modifiers
Default modifier: POSIX format
As shown in the examples above, you can specify a format. This can, for instance, help you with rounding
or columns:
printp "π = {pi%.3f}", pi => 3.1415;
printp "weight is {kilogram%d}", kilogram => 127*OUNCE_PER_KILO;
printp "{filename%-20.20s}\n", filename => $fn;
- improvements on POSIX format
The POSIX "printf()" does not handle unicode strings. Perl does understand that the 's' modifier may
need to insert utf8 so does not count bytes but characters. "printi()" does not use characters but
"grapheme clusters" via Unicode::GCString. Now, also composed characters do work correctly.
Additionally, you can use the new 'S' conversion to count in columns. In fixed-width fonts, graphemes
can have width 0, 1 or 2. For instance, Chinese characters have width 2. When printing in fixed-width,
this 'S' is probably the better choice over 's'. When the field does not specify its width, then there
is no performance penalty for using 'S'.
# name right aligned, commas on same position, always
printp "name: {name%20S},\n", name => $some_chinese;
Default modifier: BYTES
[0.91] Too often, you have to translate a (file) size into humanly readible format. The "BYTES" modifier
simplifies this a lot:
printp "{size BYTES} {fn}\n", fn => $fn, size => -s $fn;
The output will always be 6 characters. Examples are "999 B", "1.2 kB", and " 27 MB".
Default modifiers: YEAR, DATE, TIME, DT, and DT()
[0.91] A set of modifiers help displaying dates and times. They are a little flexible in values they
accept, but do not expect miracles: when it get harder, you will need to process it yourself.
The actual treatment of a time value depends on the value: three different situations:
1. numeric
A pure numeric value is considered "seconds since epoch", unless it is smaller than 21000000, in
which case it is taken as date without separators.
2. date format without time-zone
The same formats are understood as in the next option, but without time-zone information. The date
is processed as text as if in the local time zone, and the output in the local time-zone.
3. date format with time-zone
By far not all possible date formats are supported, just a few common versions, like
2017-06-27 10:04:15 +02:00
2017-06-27 17:34:28.571491+02 # psql timestamp with zone
20170627100415+2
2017-06-27T10:04:15Z # iso 8601
20170627 # only for YEAR and DATE
2017-6-1 # only for YEAR and DATE
12:34 # only for TIME
The meaning of 05-04-2017 is unclear, so not supported. Milliseconds get ignored.
When the provided value has a timezone indication, it will get converted into the local timezone of
the observer.
The output of "YEAR" is in format 'YYYY', for "DATE" it will always be 'YYYY-MM-DD', where "TIME"
produces 'HH:mm:ss'.
The short form "DT" is an alias for "DT(FT)". The DT modifier can produce different formats:
DT(ASC) : %a %b %e %T %Y asctime output
DT(FT) : %F %T YYYY-MM-DD HH:mm:ss
DT(ISO) : %FT%T%z iso8601
DT(RFC822) : %a, %d %b %y %T %z email old
DT(RFC2822) : %a, %d %b %Y %T %z email newer
You may suggest additional formats, or add your own modifier.
Default modifiers: //word, //"string", //'string'
[0.91] By default, an undefined value is shown as text 'undef'. Empty strings are shown as nothing.
This may not be nice. You may want to be more specific when a value is missing.
"visitors: {count //0}"
"published: {date DT//'not yet'}"
"copyright: {year//2017 YEAR}
Modifiers will usually return "undef" when they are called with an undefined or empty value. By the
right order of '//', you may product different kinds of output:
"price: {price//5 EUR}"
"price: {price EUR//unknown}"
Private modifiers
You may pass your own modifiers. A modifier consists of a selector and a CODE, which is called when the
selector matches. The selector is either a string or a regular expression.
# in Object Oriented syntax:
my $f = String::Print->new
( modifiers => [ qr/[€₤]/ => \&money ]
);
# in function syntax:
use String::Print 'printi', 'sprinti'
, modifiers => [ qr/[€₤]/ => \&money ];
# the implementation:
sub money$$$$)
{ my ($formatter, $modif, $value, $args) = @_;
$modif eq '€' ? sprintf("%.2f EUR", $value+0.0001)
: $modif eq '₤' ? sprintf("%.2f GBP", $value/1.16+0.0001)
: 'ERROR';
}
Using printp() makes it a little shorter, but will become quite complex when there are more parameter in
one string.
printi "price: {p€}", p => $pi; # price: 3.14 EUR
printi "price: {p₤}", p => $pi; # price: 2.71 GBP
printp "price: %{€}s", $pi; # price: 3.14 EUR
printp "price: %{₤}s", $pi; # price: 2.71 GBP
This is very useful in the translation context, where the translator can specify abstract formatting
rules. As example, see the (GNU) gettext files, in the translation table for Dutch into English. The
translator tells us which currency to use in the display.
msgid "kostprijs: {p€}"
msgstr "price: {p₤}"
Another example. Now, we want to add timestamps. In this case, we decide for modifier names in "\w", so
we need a blank to separate the parameter from the modifer.
Modifiers: stacking
You can add more than one modifier. The modifiers detect the extend of their own information (via a
regular expression), and therefore the formatter understands where one ends and the next begins.
The modifiers are called in order:
printi "price: {p€%9s}\n", p => $p; # price: ␣␣␣123.45
printi ">{t T%10s}<", t => $now; # >␣␣12:59:17<
printp "price: %9{€}s\n", $p; # price: ␣␣␣123.45
printp ">%10{T}s<", $now; # >␣␣12:59:17<
Output encoding
[0.91] This module is also used by Log::Report::Template, which is used to insert (translated) strings
with parameters into HTML templates. You can imagine that some of the parameter may need to be encoded
to HTML in the template, and other not.
example with Log::Report::Template
In pure Template Toolkit, you would write
# in your TT-template
<div>Username: [% username | html %]</div>
# in your code
username => $user->name,
With plain String::Print with output encoding enabled, you can do:
# in your TT-template
<div>[% show_username %]</div>
# in your code with encodeFor('HTML')
show_username => printi("Username: {user}", user => $user->name),
# or
show_username => printp("Username: %s", $user->name),
That does not look very efficient, however it changes for the good when this is combined with
Log::Report::Lexicon (translations) You can either do:
# in your TT-template
<div>[% show_username %]</div>
# in your code with encodeFor('HTML')
show_username => __x("Username: {user}", user => $user->name),
Shorter:
# in your TT-template with encodeFor('HTML')
<div>[% loc("Username: {user}", user => username) %]</div>
# in your code
username => $user->name,
Even shorter:
# in your TT-template with encodeFor('HTML')
<div>[% loc("Username: {user.name}", user => userobj) %]</div>
# in your code
userobj => $user,
Shortest:
# in your TT-template with encodeFor('HTML')
<div>[% loc("Username: {user.name}") %]</div>
# in your code
user => $user,
Shorter that the original, and translations for free! More examples in Log::Report::Template.
Output encoding exclusion
In some cases, the data which is inserted is already encoded in the output syntax. For instance, you
already have HTML to be included.
The default exclusion rule for HTML output is "qr/html$/i", which means that all inserted named
parameters, where the name ends on "html" will not get html-entity encoded.
This will work by default:
# with encodeFor('HTML')
printp "Me & Co: {name}, {description_html}",
name => 'René', description_html => $descr;
This may result in:
Me & Co: René, <font color="red">new member</font>
Better not to have HTML in your program: leave it to the template. But in some cases, you have no
choice.
Compared to other modules on CPAN
There are a quite a number of modules on CPAN which extend the functionality of "printf()". To name a
few: String::Format <http://search.cpan.org/~darren/String-Format>, String::Errf
<http://http://search.cpan.org/~rjbs/String-Errf>, String::Formatter
<http://http://search.cpan.org/~rjbs/String-Formatter>, Text::Sprintf::Named
<http://search.cpan.org/~shlomif/Text-Sprintf-Named>, Acme::StringFormat
<http://search.cpan.org/~gfuji/Acme-StringFormat>, Text::sprintf <http://search.cpan.org/~sharyanto/Text-
sprintfn>, Log::Sprintf <http://search.cpan.org/~frew/Log-Sprintf>, and String::Sprintf
<http://search.cpan.org/~bartl/String-Sprintf>. They are all slightly different.
When the "String::Print" module was created, none of the modules mentioned above handled unicode
correctly. Global configuration of serializers and modifiers is also usually not possible, sometimes
provided per explicit function call. Only "String::Print" cleanly separates the roles of serializers,
modifiers, and conversions.
"String::Print" is nicely integrated with Log::Report.
SEE ALSO
This module is part of String-Print distribution version 0.94, built on March 01, 2020. Website:
http://perl.overmeer.net/CPAN/
LICENSE
Copyrights 2016-2020 by [Mark Overmeer <markov@cpan.org>]. For other contributors see ChangeLog.
This program is free software; you can redistribute it and/or modify it under the same terms as Perl
itself. See http://dev.perl.org/licenses/
perl v5.36.0 2022-10-14 String::Print(3pm)