primitive_errinfo
returns important information regarding the last error as a 5-element array:
[result, enc1, enc2, error_bytes, readagain_bytes]
result is the last result of primitive_convert.
Other elements are only meaningful when result is :invalid_byte_sequence, :incomplete_input or :undefined_conversion.
enc1 and enc2 indicate a conversion step as a pair of strings. For example, a converter from EUC-JP to ISO-8859-1 converts a string as follows: EUC-JP -> UTF-8 -> ISO-8859-1. So [enc1, enc2] is either [“EUC-JP”, “UTF-8”] or [“UTF-8”, “ISO-8859-1”].
error_bytes and readagain_bytes indicate the byte sequences which caused the error. error_bytes is discarded portion. readagain_bytes is buffered portion which is read again on next conversion.
Example:
# \xff is invalid as EUC-JP. ec = Encoding::Converter.new("EUC-JP", "Shift_JIS") ec.primitive_convert(src="\xff", dst="", nil, 10) p ec.primitive_errinfo #=> [:invalid_byte_sequence, "EUC-JP", "UTF-8", "\xFF", ""] # HIRAGANA LETTER A (\xa4\xa2 in EUC-JP) is not representable in ISO-8859-1. # Since this error is occur in UTF-8 to ISO-8859-1 conversion, # error_bytes is HIRAGANA LETTER A in UTF-8 (\xE3\x81\x82). ec = Encoding::Converter.new("EUC-JP", "ISO-8859-1") ec.primitive_convert(src="\xa4\xa2", dst="", nil, 10) p ec.primitive_errinfo #=> [:undefined_conversion, "UTF-8", "ISO-8859-1", "\xE3\x81\x82", ""] # partial character is invalid ec = Encoding::Converter.new("EUC-JP", "ISO-8859-1") ec.primitive_convert(src="\xa4", dst="", nil, 10) p ec.primitive_errinfo #=> [:incomplete_input, "EUC-JP", "UTF-8", "\xA4", ""] # Encoding::Converter::PARTIAL_INPUT prevents invalid errors by # partial characters. ec = Encoding::Converter.new("EUC-JP", "ISO-8859-1") ec.primitive_convert(src="\xa4", dst="", nil, 10, Encoding::Converter::PARTIAL_INPUT) p ec.primitive_errinfo #=> [:source_buffer_empty, nil, nil, nil, nil] # \xd8\x00\x00@ is invalid as UTF-16BE because # no low surrogate after high surrogate (\xd8\x00). # It is detected by 3rd byte (\00) which is part of next character. # So the high surrogate (\xd8\x00) is discarded and # the 3rd byte is read again later. # Since the byte is buffered in ec, it is dropped from src. ec = Encoding::Converter.new("UTF-16BE", "UTF-8") ec.primitive_convert(src="\xd8\x00\x00@", dst="", nil, 10) p ec.primitive_errinfo #=> [:invalid_byte_sequence, "UTF-16BE", "UTF-8", "\xD8\x00", "\x00"] p src #=> "@" # Similar to UTF-16BE, \x00\xd8@\x00 is invalid as UTF-16LE. # The problem is detected by 4th byte. ec = Encoding::Converter.new("UTF-16LE", "UTF-8") ec.primitive_convert(src="\x00\xd8@\x00", dst="", nil, 10) p ec.primitive_errinfo #=> [:invalid_byte_sequence, "UTF-16LE", "UTF-8", "\x00\xD8", "@\x00"] p src #=> ""
Inserts string into the encoding converter. The string will be converted to the destination encoding and output on later conversions.
If the destination encoding is stateful, string is converted according to the state and the state is updated.
This method should be used only when a conversion error occurs.
ec = Encoding::Converter.new("utf-8", "iso-8859-1") src = "HIRAGANA LETTER A is \u{3042}." dst = "" p ec.primitive_convert(src, dst) #=> :undefined_conversion puts "[#{dst.dump}, #{src.dump}]" #=> ["HIRAGANA LETTER A is ", "."] ec.insert_output("<err>") p ec.primitive_convert(src, dst) #=> :finished puts "[#{dst.dump}, #{src.dump}]" #=> ["HIRAGANA LETTER A is <err>.", ""] ec = Encoding::Converter.new("utf-8", "iso-2022-jp") src = "\u{306F 3041 3068 2661 3002}" # U+2661 is not representable in iso-2022-jp dst = "" p ec.primitive_convert(src, dst) #=> :undefined_conversion puts "[#{dst.dump}, #{src.dump}]" #=> ["\e$B$O$!$H".force_encoding("ISO-2022-JP"), "\xE3\x80\x82"] ec.insert_output "?" # state change required to output "?". p ec.primitive_convert(src, dst) #=> :finished puts "[#{dst.dump}, #{src.dump}]" #=> ["\e$B$O$!$H\e(B?\e$B!#\e(B".force_encoding("ISO-2022-JP"), ""]
Returns an exception object for the last conversion. Returns nil if the last conversion did not produce an error.
“error” means that Encoding::InvalidByteSequenceError
and Encoding::UndefinedConversionError
for Encoding::Converter#convert
and :invalid_byte_sequence, :incomplete_input and :undefined_conversion for Encoding::Converter#primitive_convert
.
ec = Encoding::Converter.new("utf-8", "iso-8859-1") p ec.primitive_convert(src="\xf1abcd", dst="") #=> :invalid_byte_sequence p ec.last_error #=> #<Encoding::InvalidByteSequenceError: "\xF1" followed by "a" on UTF-8> p ec.primitive_convert(src, dst, nil, 1) #=> :destination_buffer_full p ec.last_error #=> nil
Returns the length of the hash value of the digest.
This method should be overridden by each implementation subclass. If not, digest_obj.digest().length() is returned.
Returns the block length of the digest.
This method is overridden by each implementation subclass.
Similar to read, but raises EOFError
at end of string unless the +exception: false+ option is passed in.
Reads at most maxlen bytes in the non-blocking manner.
When no data can be read without blocking it raises OpenSSL::SSL::SSLError
extended by IO::WaitReadable
or IO::WaitWritable
.
IO::WaitReadable
means SSL
needs to read internally so read_nonblock
should be called again when the underlying IO
is readable.
IO::WaitWritable
means SSL
needs to write internally so read_nonblock
should be called again after the underlying IO
is writable.
OpenSSL::Buffering#read_nonblock
needs two rescue clause as follows:
# emulates blocking read (readpartial). begin result = ssl.read_nonblock(maxlen) rescue IO::WaitReadable IO.select([io]) retry rescue IO::WaitWritable IO.select(nil, [io]) retry end
Note that one reason that read_nonblock
writes to the underlying IO
is when the peer requests a new TLS/SSL handshake. See openssl the FAQ for more details. www.openssl.org/support/faq.html
By specifying a keyword argument exception to false
, you can indicate that read_nonblock
should not raise an IO::Wait*able exception, but return the symbol :wait_writable
or :wait_readable
instead. At EOF, it will return nil
instead of raising EOFError
.
Writes s in the non-blocking manner.
If there is buffered data, it is flushed first. This may block.
write_nonblock
returns number of bytes written to the SSL
connection.
When no data can be written without blocking it raises OpenSSL::SSL::SSLError
extended by IO::WaitReadable
or IO::WaitWritable
.
IO::WaitReadable
means SSL
needs to read internally so write_nonblock
should be called again after the underlying IO
is readable.
IO::WaitWritable
means SSL
needs to write internally so write_nonblock
should be called again after underlying IO
is writable.
So OpenSSL::Buffering#write_nonblock
needs two rescue clause as follows.
# emulates blocking write. begin result = ssl.write_nonblock(str) rescue IO::WaitReadable IO.select([io]) retry rescue IO::WaitWritable IO.select(nil, [io]) retry end
Note that one reason that write_nonblock
reads from the underlying IO
is when the peer requests a new TLS/SSL handshake. See the openssl FAQ for more details. www.openssl.org/support/faq.html
By specifying a keyword argument exception to false
, you can indicate that write_nonblock
should not raise an IO::Wait*able exception, but return the symbol :wait_writable
or :wait_readable
instead.
A wrapper class to use a StringIO
object as the body and switch to a TempFile when the passed threshold is passed. Initialize the data from the query.
Handles multipart forms (in particular, forms that involve file uploads). Reads query parameters in the @params field, and cookies into @cookies.
Generate an Image Button Input element as a string.
src
is the URL of the image to use for the button. name
is the input name. alt
is the alternative text for the image.
Alternatively, the attributes can be specified as a hash.
image_button("url") # <INPUT TYPE="image" SRC="url"> image_button("url", "name", "string") # <INPUT TYPE="image" SRC="url" NAME="name" ALT="string"> image_button("SRC" => "url", "ALT" => "string") # <INPUT TYPE="image" SRC="url" ALT="string">
Returns an array of header field strings corresponding to the case-insensitive key
. This method allows you to get duplicated header fields without any processing. See also []
.
p response.get_fields('Set-Cookie') #=> ["session=al98axx; expires=Fri, 31-Dec-1999 23:58:23", "query=rubyscript; expires=Fri, 31-Dec-1999 23:58:23"] p response['Set-Cookie'] #=> "session=al98axx; expires=Fri, 31-Dec-1999 23:58:23, query=rubyscript; expires=Fri, 31-Dec-1999 23:58:23"
Iterates through the header names and values, passing in the name and value to the code block supplied.
Returns an enumerator if no block is given.
Example:
response.header.each_header {|key,value| puts "#{key} = #{value}" }
Sets the HTTP
Range: header. Accepts either a Range
object as a single argument, or a beginning index and a length from that index. Example:
req.range = (0..1023) req.set_range 0, 1023
Returns a Range
object which represents the value of the Content-Range: header field. For a partial entity body, this indicates where this fragment fits inside the full entity body, as range of byte offsets.
The length of the range represented in Content-Range: header.
Creates an unsigned certificate for subject
and key
. The lifetime of the key is from the current time to age
which defaults to one year.
The extensions
restrict the key to the indicated uses.
Enumerates the trusted certificates via Gem::Security::TrustDir
.
Simple deprecation method that deprecates name
by wrapping it up in a dummy method. It warns on each call to the dummy method telling the user of repl
(unless repl
is :none) and the Rubygems version that it is planned to go away.
Simple deprecation method that deprecates name
by wrapping it up in a dummy method. It warns on each call to the dummy method telling the user of repl
(unless repl
is :none) and the Rubygems version that it is planned to go away.