# RUN: %fish -C "set fish %fish" %s # Set term again explicitly to ensure behavior. set -gx TERM xterm # Read with no vars is not an error read # Read with -a and anything other than exactly on var name is an error read -a #CHECKERR: read: Expected 1 args, got 0 read --array v1 v2 #CHECKERR: read: Expected 1 args, got 2 read --list v1 # Verify correct behavior of subcommands and splitting of input. begin count (echo one\ntwo) #CHECK: 2 set -l IFS \t count (echo one\ntwo) #CHECK: 2 set -l IFS count (echo one\ntwo) #CHECK: 1 echo [(echo -n one\ntwo)] #CHECK: [one #CHECK: two] count (echo one\ntwo\n) #CHECK: 1 echo [(echo -n one\ntwo\n)] #CHECK: [one #CHECK: two] count (echo one\ntwo\n\n) #CHECK: 1 echo [(echo -n one\ntwo\n\n)] #CHECK: [one #CHECK: two #CHECK: ] end function print_vars --no-scope-shadowing set -l space set -l IFS \n # ensure our command substitution works right for var in $argv echo -n $space (count $$var) \'$$var\' set space '' end echo end # Test splitting input echo 'hello there' | read -l one two print_vars one two #CHECK: 1 'hello' 1 'there' echo 'hello there' | read -l one print_vars one #CHECK: 1 'hello there' echo '' | read -l one print_vars one #CHECK: 1 '' echo '' | read -l one two print_vars one two #CHECK: 1 '' 1 '' echo 'test' | read -l one two three print_vars one two three #CHECK: 1 'test' 1 '' 1 '' echo 'foo bar baz' | read -l one two three print_vars one two three #CHECK: 1 'foo' 1 'bar' 1 ' baz' echo -n 'a' | read -l one echo "$status $one" #CHECK: 0 a # Test splitting input with IFS empty set -l IFS echo 'hello' | read -l one print_vars one #CHECK: 1 'hello' echo 'hello' | read -l one two print_vars one two #CHECK: 1 'h' 1 'ello' echo 'hello' | read -l one two three print_vars one two three #CHECK: 1 'h' 1 'e' 1 'llo' echo '' | read -l one print_vars one #CHECK: 0 echo 't' | read -l one two print_vars one two #CHECK: 1 't' 0 echo 't' | read -l one two three print_vars one two three #CHECK: 1 't' 0 0 echo ' t' | read -l one two print_vars one two #CHECK: 1 ' ' 1 't' set -le IFS echo 'hello there' | read -la ary print_vars ary #CHECK: 2 'hello' 'there' echo 'hello' | read -la ary print_vars ary #CHECK: 1 'hello' echo 'this is a bunch of words' | read -la ary print_vars ary #CHECK: 6 'this' 'is' 'a' 'bunch' 'of' 'words' echo ' one two three' | read -la ary print_vars ary #CHECK: 3 'one' 'two' 'three' echo '' | read -la ary print_vars ary #CHECK: 0 set -l IFS echo 'hello' | read -la ary print_vars ary #CHECK: 5 'h' 'e' 'l' 'l' 'o' echo 'h' | read -la ary print_vars ary #CHECK: 1 'h' echo '' | read -la ary print_vars ary #CHECK: 0 set -le IFS # read -n tests echo 'testing' | read -n 3 foo echo $foo #CHECK: tes echo 'test' | read -n 10 foo echo $foo #CHECK: test echo 'test' | read -n 0 foo echo $foo #CHECK: test echo 'testing' | begin; read -n 3 foo; read -n 3 bar; end echo $foo #CHECK: tes echo $bar #CHECK: tin echo 'test' | read -n 1 foo echo $foo #CHECK: t # read -z tests echo -n 'testing' | read -lz foo echo $foo #CHECK: testing echo -n 'test ing' | read -lz foo echo $foo #CHECK: test ing echo 'newline' | read -lz foo echo $foo #CHECK: newline #CHECK: echo -n 'test ing' | read -lz foo bar print_vars foo bar #CHECK: 1 'test' 1 'ing' echo -ne 'test\0ing' | read -lz foo bar print_vars foo bar #CHECK: 1 'test' 1 '' echo -ne 'foo\nbar' | read -lz foo bar print_vars foo bar #CHECK: 1 'foo' 1 'bar' echo -ne 'foo\nbar\0baz\nquux' | while read -lza foo print_vars foo end #CHECK: 2 'foo' 'bar' #CHECK: 2 'baz' 'quux' # Chunked read tests set -l path /tmp/fish_chunked_read_test.txt set -l longstr (seq 1024 | string join ',') echo -n $longstr > $path read -l longstr2 < $path test "$longstr" = "$longstr2" and echo "Chunked reads test pass" or echo "Chunked reads test failure: long strings don't match!" rm $path #CHECK: Chunked reads test pass # ========== # The following tests verify that `read` correctly handles the limit on the # number of bytes consumed. # set fish_read_limit 8192 set line abcdefghijklmnopqrstuvwxyz # Ensure the `read` command terminates if asked to read too much data. The var # should be empty. We throw away any data we read if it exceeds the limit on # what we consider reasonable. yes $line | dd bs=1024 count=(math "1 + $fish_read_limit / 1024") 2>/dev/null | read --null x if test $status -ne 122 echo reading too much data did not terminate with failure status end # The read var should be defined but not have any elements when the read # aborts due to too much data. set -q x or echo reading too much data did not define the var set -q x[1] and echo reading too much data resulted in a var with unexpected data # Ensure the `read` command terminates if asked to read too much data even if # given an explicit limit. The var should be empty. We throw away any data we # read if it exceeds the limit on what we consider reasonable. yes $line | read --null --nchars=(math "$fish_read_limit + 1") x if test $status -ne 122 echo reading too much data did not terminate with failure status end set -q x or echo reading too much data with --nchars did not define the var set -q x[1] and echo reading too much data with --nchars resulted in a var with unexpected data # Now do the opposite of the previous test and confirm we can read reasonable # amounts of data. echo $line | read x if test $status -ne 0 echo the read of a reasonable amount of data failed unexpectedly end set exp_length (string length $x) set act_length (string length $line) if test $exp_length -ne $act_length echo reading a reasonable amount of data failed the length test echo expected length $exp_length, actual length $act_length end # Confirm we can read exactly up to the limit. yes $line | read --null --nchars $fish_read_limit x if test $status -ne 0 echo the read of the max amount of data with --nchars failed unexpectedly end if test (string length "$x") -ne $fish_read_limit echo reading the max amount of data with --nchars failed the length test end # Same as previous test but limit the amount of data fed to `read` rather than # using the `--nchars` flag. yes $line | dd bs=1024 count=(math "$fish_read_limit / 1024") 2>/dev/null | read --null x if test $status -ne 0 echo the read of the max amount of data failed unexpectedly end if test (string length "$x") -ne $fish_read_limit echo reading the max amount of data with --nchars failed the length test: (string length "$x") end # Confirm reading non-interactively works -- \#4206 regression echo abc\ndef | $fish -i -c 'read a; read b; set --show a; set --show b' #CHECK: $a: not set in local scope #CHECK: $a: set in global scope, unexported, with 1 elements #CHECK: $a[1]: length=3 value=|abc| #CHECK: $a: not set in universal scope #CHECK: #CHECK: $b: not set in local scope #CHECK: $b: set in global scope, unexported, with 1 elements #CHECK: $b[1]: length=3 value=|def| #CHECK: $b: not set in universal scope # Test --delimiter (and $IFS, for now) echo a=b | read -l foo bar echo $foo echo $bar #CHECK: a=b # Delimiter = echo a=b | read -l -d = foo bar echo $foo #CHECK: a echo $bar #CHECK: b # Delimiter empty echo a=b | read -l -d '' foo bar baz echo $foo #CHECK: a echo $bar #CHECK: = echo $baz #CHECK: b # IFS empty string set -l IFS '' echo a=b | read -l foo bar baz echo $foo #CHECK: a echo $bar #CHECK: = echo $baz #CHECK: b # IFS unset set -e IFS echo a=b | read -l foo bar baz echo $foo #CHECK: a=b echo $bar #CHECK: echo $baz #CHECK: # Delimiter = echo a=b | read -l -d = foo bar baz echo $foo #CHECK: a echo $bar #CHECK: b echo $baz #CHECK: # Multi-char delimiters with -d echo a...b...c | read -l -d "..." a b c echo $a #CHECK: a echo $b #CHECK: b echo $c #CHECK: c # Multi-char delimiters with IFS begin set -l IFS "..." echo a...b...c | read -l a b c echo $a; echo $b; echo $c end #CHECK: a #CHECK: b #CHECK: ..c # At one point, whatever was read was printed _before_ banana echo banana (echo sausage | read) echo 'a | b' | read -lt a b c #CHECK: banana sausage echo a $a echo b $b echo c $c # CHECK: a a # CHECK: b | # CHECK: c b echo 'a"foo bar"b' | read -lt a b c echo a \'$a\' echo b $b echo c $c # CHECK: a 'afoo barb' # CHECK: b # CHECK: c