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datastream validation

pull/406/head
qadan 11 years ago
parent
commit
6de9280b5d
  1. 472
      tests/datastream_validators.inc
  2. 130
      tests/islandora_web_test_case.inc

472
tests/datastream_validators.inc

@ -0,0 +1,472 @@
<?php
/**
* @file
* Assertions for various datastream types.
*
* For a datastream validator to work correctly with IslandoraWebTestCase::
* validateDatastreams(), it needs to return an array of results, each entry of
* which contains two values: first, TRUE or FALSE, depending on whether or not
* that particular result passed or failed, and second, a string containing a
* message to accompany the result.
*
* It also should contain three parameters, all of which may use any label, but
* must be organized in the following order:
* $object - an object that the datastream can be loaded from.
* $datastream - a DSID to pull from $object.
* $optional_params - a parameter for any data the function requires.
*
* When IslandoraWebTestCase::validateDatastreams() is called, it is passed an
* array of datastreams, each of which is itself an array containing the DSID of
* the datastream, the middle of the function name (image, pdf, tiff, etc.), and
* (optional) data to be passed to that third parameter.
*/
/**
* A function to pass assertions to and receive results from.
*
* @param bool $assertion
* The if/then statement to validate against.
* @param array $results
* An array of results to append the generated result to.
* @param string $pass
* A message to return if the assertion turns up true.
* @param string $fail
* An optional message to return if the assertion turns up false.
* If left empty, the $pass message will be returned.
*
* @return array
* A result that can be made useful in the validation functions below.
*/
function assert_valid($assertion, $results, $pass, $fail = '') {
if ($assertion) {
$result = array(TRUE, $pass);
}
else {
if (isset($fail)) {
$result = array(FALSE, $fail);
}
else {
$result = array(FALSE, $pass);
}
}
array_push($results, $result);
return $results;
}
/**
* Converts a hexidecimal string to an integer.
*
* This is useful for running checks on values that appear in the binary
* of a datastream. Returns FALSE if the hex value contains non-hex characters
* or if the string would not return a 16- or 32-bit formatted big-endian
* signed integer.
*
* @param string $hex
* The hexidecimal string.
*
* @return bool|int
* FALSE on failure, or the integer on success.
*/
function hex2int($hex) {
// A couple of quick string checks.
if (!ctype_xdigit($hex)) {
drupal_set_message(t('String passed to hex2int() contains non-hexidecimal characters.'), 'error');
return FALSE;
}
if (!strlen($hex) === 4 || !strlen($hex) === 8) {
drupal_set_message(t('String passed to hex2int() cannot create a 16- or 32-bit little-endian signed integer'), 'error');
return FALSE;
}
// The actual conversion.
try {
$reverse_hex = implode('', array_reverse(str_split($hex, 2)));
$int = hexdec($reverse_hex);
return $int;
}
catch (Exception $e) {
throw new Exception('An error occurred during the conversion of hexidecimal to integer.', 0, $e);
}
}
/**
* Asserts that an object's given datastreams are common-type image files.
*
* Uses PHPGD to run the assertion check. This means that only certain kinds
* of image files can be checked. Please check the documentation for the PHPGD
* imagecreatefromstring() function to determine what filetypes are valid.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID to check that corresponds to a PHPGD-valid image datastream.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_image_datastream($object, $datastream) {
$datastream_string = $object[$datastream]->content;
$results = array();
$pass = "Image datastream {$datastream} is valid.";
$fail = "Image datastream {$datastream} is either invalid or corrupt.";
$results = assert_valid(imagecreatefromstring($datastream_string), $results, $pass, $fail);
return $results;
}
/**
* Asserts the validity of any .tif/.tiff datastream.
*
* Does not use the assert_valid() function, as this is not a simple true/false.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID to check that corresponds to a .tif/.tiff datastream.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_tiff_datastream($object, $datastream) {
$datastream_string = $object[$datastream]->content;
$datastream_header_hex = substr(bin2hex($datastream_string), 0, 8);
$results = array();
if ($datastream_header_hex == "49492a00") {
// In this case, the ingested TIFF is designated as using the "Intel
// byte-order" (e.g. little-endian) by starting with the characters "II"
// (repeated so that byte order does not yet need to be significant).
// The number that follows is '42' in little-endian hex, a number of
// 'deep philosophical significance' to the TIFF format creators.
array_push($results, array(TRUE, "{$datastream} datastream asserts that it is a valid Intel-byte-orderded TIF/TIFF file."));
}
elseif ($datastream_header_hex == "4d4d002a") {
// In this case, the ingested TIFF is designated as using the "Motorola
// byte-order" (e.g. big-endian) by starting with the characters "MM"
// instead. 42 follows once again, this time in big-endian hex.
array_push($results, array(TRUE, "{$datastream} datastream asserts that it is a valid Motorola-byte-ordered TIF/TIFF file."));
}
else {
array_push($results, array(FALSE, "{$datastream} datastream does not assert that it is a valid TIF/TIFF file."));
}
return $results;
}
/**
* Asserts the validity of any .jp2 datastream.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID to check that corresponds to a .jp2 datastream.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_jp2_datastream($object, $datastream) {
$datastream_hex = bin2hex($object[$datastream]->content);
$results = array();
// JP2 files begin with an offset header at the second 32-bit integer,
// 0x6A502020. This header is in all .jp2s, and we check for it here.
$pass = "{$datastream} datastream begins correctly with the appropriate .jp2 header.";
$fail = "{$datastream} datastream does not begin with the appropriate .jp2 header.";
$results = assert_valid(substr($datastream_hex, 8, 8) == '6a502020', $results, $pass, $fail);
// JP2 files have their codestream capped with a marker, 0xFFD9. We're
// just checking for it here to see if the .jp2 encoder finished okay.
$pass = "{$datastream} datastream ends correctly with the appropriate .jp2 marker.";
$fail = "{$datastream} datastream does not end with a .jp2 marker; derivative generation was likely interrupted.";
$results = assert_valid(substr($datastream_hex, strlen($datastream_hex) - 4, 4) == 'ffd9', $results, $pass, $fail);
return $results;
}
/**
* Asserts the validity of any .pdf datastream.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID to check that corresponds to a .pdf datastream.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_pdf_datastream($object, $datastream) {
$pdf = $object[$datastream]->content;
$pdf_version = substr($pdf, 5, 3);
$results = array();
$pass = "{$datastream} datastream asserts that it is a valid PDF file using PDF version {$pdf_version}";
$fail = "{$datastream} datastream binary header appears to be corrupt and missing a valid PDF signature.";
$results = assert_valid(substr($pdf, 0, 5) == '%PDF-', $results, $pass, $fail);
$pdf_streams = substr_count(bin2hex($pdf), '0a73747265616d0a');
$pass = "{$datastream} datastream reports the existence of {$pdf_streams} PDF streams. Note that an extremely low number could still indicate corruption.";
$fail = "{$datastream} datastream contains zero PDF streams, and is likely not a PDF file.";
$results = assert_valid($pdf_streams, $results, $pass, $fail);
$pass = "{$datastream} datastream reports the existence of the closing 'EOF' tag required at the end of PDFs";
$fail = "{$datastream} datastream does not contain the closing 'EOF' tag. If this is the only PDF validation that failed, it is likely that derivative generation was interrupted.";
$results = assert_valid(strpos(bin2hex($pdf), '0a2525454f460a'), $results, $pass, $fail);
return $results;
}
/**
* Asserts that a string of text shows up inside a datastream.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID to check that corresponds to a datastream containing text.
* @param array $text
* An array of strings/the number of times it should appear in the datastream.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_text_datastream($object, $datastream, array $text) {
$results = array();
$content = $object[$datastream]->content;
$string_count = substr_count($content, $text[0]);
$pass = "{$datastream} datastream contains the word(s) '{$text[0]}' repeated {$string_count} time(s) (expected: {$text[1]}).";
$fail = "{$datastream} datastream contains the word(s) '{$text[0]}' repeated {$string_count} time(s) (expected: {$text[1]}).";
$results = assert_valid($string_count == $text[1], $results, $pass, $fail);
return $results;
}
/**
* Asserts the validity of any .wav datastraeam.
*
* WAV files contain a rigidly detailed header that contains all sorts of fun
* information we can use to validate things against other things. So, we check
* rigorously that the header contains properly constructed data by looking to
* see if certain values are at their expected byte offset. We also compare
* declared chunk sizes against actual sizes. If any of these are off, WAV
* players will fail to function.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID to check that corresponds to a datastream generated via OCR or HOCR.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_wav_datastream($object, $datastream) {
$results = array();
$wav = bin2hex($object['OBJ']->content);
$wav_subchunk2size = hex2int(substr($wav, 80, 8));
$wav_samplerate = hex2int(substr($wav, 48, 8));
$wav_numchannels = hex2int(substr($wav, 44, 4));
$wav_bytespersample = hex2int(substr($wav, 68, 4)) / 8;
$wav_numsamples = strlen(substr($wav, 88)) / $wav_numchannels / $wav_bytespersample / 2;
$magic_number = str_split(substr($wav, 0, 24), 8);
$pass = "Header of the {$datastream} datastream contains correct file signature";
$fail = "Header of the {$datastream} datastream contains corrupt file signature";
$results = assert_valid($magic_number[0] = '52494646' && $magic_number[2] = '57415645', $results, $pass, $fail);
$pass = "{$datastream} datastream chunksize in WAV header is correct";
$fail = "{$datastream} datastream chunksize in WAV header does not match actual chunksize.";
$results = assert_valid(hex2int(substr($wav, 8, 8)) === 36 + $wav_subchunk2size, $results, $pass, $fail);
$pass = "{$datastream} datastream contains a 'fmt' subchunk.";
$fail = "{$datastream} datastream is missing the required 'fmt' subchunk.";
$results = assert_valid(substr($wav, 24, 8) === '666d7420', $results, $pass, $fail);
$pass = "{$datastream} datastream byterate in the WAV header is correct.";
$fail = "{$datastream} datastream byterate in the WAV header does not match actual calculated byterate.";
$results = assert_valid(hex2int(substr($wav, 56, 8)) === $wav_samplerate * $wav_numchannels * $wav_bytespersample, $results, $pass, $fail);
$pass = "{$datastream} datastream block alignment is set correctly.";
$fail = "{$datastream} datastream block alignment is off.";
$results = assert_valid(hex2int(substr($wav, 64, 4)) === $wav_numchannels * $wav_bytespersample, $results, $pass, $fail);
$pass = "{$datastream} datastream contains 'data' subchunk.";
$fail = "{$datastream} datastream is missing the 'data' subchunk.";
$results = assert_valid(substr($wav, 72, 8) === '64617461', $results, $pass, $fail);
$pass = "{$datastream} datastream 'data' chunk is the correct size.";
$fail = "{$datastream} datastream 'data' chunk is sized incorrectly.";
$results = assert_valid($wav_subchunk2size === $wav_numsamples * $wav_numchannels * $wav_bytespersample, $results, $pass, $fail);
return $results;
}
/**
* Asserts the validity of any .mp3 datastream.
*
* Our default setup tries to create an MP3 using VBR, but we do some extra
* checks in case someone turns that off. If the header contains the characters
* 'Xing', it is flagged as VBR, and we can do an in-depth check on each of the
* VBR settings. Otherwise, we look for the basic MP3 signature 'fffa' or 'fffb'
* at the start of the binary.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID of a datastream corresponding to an mp3 file.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_mp3_datastream($object, $datastream) {
$results = array();
$mp3 = bin2hex($object[$datastream]->content);
$mp3_size = strlen($mp3) / 2;
// Looks to see if VBR was set properly by LAME. If so, MATH TIME!
if (strpos($mp3, '58696e67')) {
$mp3_vbrheader = substr($mp3, strpos($mp3, '58696e67'), 240);
// Check the field flags. VBR-formatted MP3 files contain a 32-bit
// integer (stored as $mp3_flag_value) that is a combination of four
// bits, each one indicating the on-off status of a VBR setting, via
// logical OR. Rather than disassembling this value into individual
// bits, we use the algorithm "if (binary_total+bit_value*2)/bit_value*2
// is greater than or equal to bit_value, that bit is turned on" to find
// the status of each bit, so we know whether to offset the rest.
$mp3_field_offset = array(0, 0, 0);
$mp3_flag_value = hexdec(substr($mp3_vbrheader, 8, 8));
// We can't use the first flag, but we still need to offset the rest.
if (($mp3_flag_value + 1) % 2 == 0) {
$mp3_field_offset[0] += 8;
$mp3_field_offset[1] += 8;
$mp3_field_offset[2] += 8;
}
// The second flag leads us to filesize data, which we can verify.
if (($mp3_flag_value + 4) % 4 > 1) {
$mp3_field_bytes = hexdec(substr($mp3_vbrheader, $mp3_field_offset[0] + 16, 8));
$pass = "{$datastream} datastream reported filesize of {$mp3_size} bytes matches size field value of {$mp3_field_bytes}";
$fail = "{$datastream} datastream reported filesize of {$mp3_size} bytes does not match size field value of {$mp3_field_bytes}";
$results = assert_valid($mp3_size == $mp3_field_bytes, $results, $pass, $fail);
$mp3_field_offset[1] += 8;
$mp3_field_offset[2] += 8;
}
// We can't use the third flag for anything either.
if (($mp3_flag_value + 8) % 8 > 3) {
$mp3_field_offset[2] += 200;
}
// The fourth flag leads us to VBR quality data, which we can validate.
if ($mp3_flag_value > 7) {
$mp3_field_quality = hexdec(substr($mp3_vbrheader, $mp3_field_offset[2] + 16, 8));
$pass = "{$datastream} datastream reports valid VBR quality of {$mp3_field_quality} (expected: between 0-100)";
$fail = "{$datastream} datastream reports invalid VBR quality of {$mp3_field_quality} (expected: between 0-100)";
$results = assert_valid($mp3_field_quality <= 100 && $mp3_field_quality >= 0, $results, $pass, $fail);
}
}
// Otherwise, just forget everything and check the file signature.
elseif (strpos($mp3, '58696e67') == FALSE && substr($mp3, 0, 4) == 'fffa') {
$results = array(array(TRUE, "{$datastream} datastream is encoded as a valid MPEG-1 Layer 3 file with CRC protection"));
}
elseif (strpos($mp3, '58696e67') == FALSE && substr($mp3, 0, 4) == 'fffb') {
$results = array(array(TRUE, "{$datastream} datastream is encoded as a valid unprotected MPEG-1 Layer 3 file"));
}
else {
$results = array(array(FALSE, "{$datastream} datastream is corrupt and does not identify as a valid MP3."));
}
return $results;
}
/**
* Attempts to validate an .mp4 datastream.
*
* MP4 files are a subset of the ISO file format specification, and as such need
* to contain a 64-bit declaration of type within the first eight eight bytes of
* the file. This declaration is comprised of the characters 'ftyp', followed by
* a four-character filetype code. Below, we look for 'ftyp', and then pass the
* filetype code to the test message.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID of a datastream corresponding to an mp4 file.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_mp4_datastream($object, $datastream) {
$results = array();
$mp4 = $object[$datastream]->content;
if (strpos($mp4, 'ftyp')) {
$mp4_ftyp = substr(strpos($mp4, 'ftyp'), 4, 4);
}
$pass = "{$datastream} datastream asserts that it is a valid ISO-formatted video file using ftyp {$mp4_ftyp}";
$fail = "{$datastream} datastream is not a valid ISO-formatted video";
$results = assert_valid(strpos($mp4, 'ftyp'), $results, $pass, $fail);
return $results;
}
/**
* Attempts to validate an .ogg/ogv datastream using Vorbis and Theora encoding.
*
* OGG files are made up of several 'pages' of OGG data, each prefaced with an
* OGG marker - the letters 'OggS'. The file header also contains information on
* what encoders were used to create the file. Here, we're looking for at least
* one OGG page, and confirming that the file asserts the Theora and Vorbis
* codecs were used to create the file.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID of a datastream corresponding to an ogg file.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_ogg_datastream($object, $datastream) {
$results = array();
$ogg = $object[$datastream]->content;
$ogg_pages = substr_count($ogg, 'OggS');
$pass = "{$datastream} datastream asserts that it contains {$ogg_pages} Ogg pages (even a very small file should contain several).";
$fail = "{$datastream} datastream contains no Ogg pages.";
$results = assert_valid(substr_count($ogg, 'OggS'), $results, $pass, $fail);
$pass = "{$datastream} datastream asserts that it contains Theora-encoded video data.";
$fail = "{$datastream} datastream contains no marker indicating the presence of Theora-encoded video data.";
$results = assert_valid(substr_count($ogg, 'theora'), $results, $pass, $fail);
$pass = "{$datastream} datastream asserts that it contains Vorbis-encoded audio data";
$fail = "{$datastream} datastream contains no marker indicating the presence of Vorbis-encoded audio data.";
$results = assert_valid(substr_count($ogg, 'vorbis'), $results, $pass, $fail);
return $results;
}
/**
* Attempts to validate an .mkv datastream.
*
* There's not much we can do to check an MKV file, since the format is really,
* really loose. We do know a couple of things though - first, since MKV is an
* EBML format, the first four characters will always be the same. Since they're
* non-standard characters, we're looking at their hex values instead. And
* second, we know that the file will contain the declaration 'matroska' soon
* after. We could look for this in the binary, but we already have the hex-
* translated version, so we just look for 'matroska' in hex.
*
* @param AbstractObject $object
* The PID of the object.
* @param string $datastream
* A DSID of a datastream corresponding to an MKV file.
*
* @return array
* A series of TRUE(pass)/FALSE(fail) results paired with result messages.
*/
function validate_mkv_datastream($object, $datastream) {
$results = array();
$mkv = bin2hex($object[$datastream]->content);
$pass = "{$datastream} datastream asserts that it is an EBML-formatted file";
$fail = "{$datastream} datastream is not an EBML-formatted file.";
$results = assert_valid(substr($mkv, 0, 8) == '1a45dfa3', $results, $pass, $fail);
$pass = "{$datastream} datastream asserts that its EBML DocType is Matroska";
$fail = "{$datastream} datastream does not contain a Matroska EBML DocType marker.";
$results = assert_valid(substr_count($mkv, '6d6174726f736b61') == 1, $results, $pass, $fail);
return $results;
}

130
tests/islandora_web_test_case.inc

@ -181,94 +181,42 @@ class IslandoraWebTestCase extends DrupalWebTestCase {
} }
/** /**
* Asserts that an object's given datastreams are common-type image files. * Attempts to validate an array of datastreams, generally via binary checks.
* *
* Uses PHPGD to run the assertion check. This means that only certain kinds * These functions exist in, and can be added to, datastream_validators.inc,
* of image files can be checked. Please check the documentation for the PHPGD * which is found in this folder.
* imagecreatefromstring() function to determine what filetypes are valid.
* *
* @param AbstractObject $object * $param AbstractObject $object
* The PID of the object. * The object to load datastreams from.
* @param array $datastreams * $param array $datastreams
* An array of datastreams to check. * An array of paired DSIDs, validate function names, and optional params.
*/ */
public function assertImageDatastreams($object, array $datastreams) { public function validateDatastreams($object, array $datastreams) {
if (!is_object($object)) { if (!is_object($object)) {
$this->fail("Failed. Object passed in is invalid.", 'Islandora'); $this->fail("Failed. Object passed in is invalid.", 'Islandora');
} }
else { module_load_include('inc', 'islandora', 'tests/datastream_validators');
foreach ($datastreams as $datastream) { foreach ($datastreams as $datastream) {
$datastream_string = $object[$datastream]->content; if (isset($object[$datastream[0]])) {
if (!imagecreatefromstring($datastream_string)) { $function = 'validate_' . $datastream[1] . '_datastream';
$this->fail("Image datastream {$datastream} is either invalid or corrupt.", 'Islandora'); if (function_exists($function)) {
if (isset($datastream[2])) {
$results = $function($object, $datastream[0], $datastream[2]);
}
else {
$results = $function($object, $datastream[0]);
}
foreach ($results as $result) {
$this->assertTrue($result[0], $result[1], 'Islandora');
}
} }
else { else {
$this->pass("Image datastream {$datastream} is valid.", 'Islandora'); $this->fail("No {$datastream[0]} validation function exists for the {$datastream[1]} datastream.", 'Islandora');
} }
} }
} }
} }
/**
* Asserts the validity of any .tif/.tiff datastream, which we have a lot of.
*
* @param AbstractObject $object
* The PID of the object.
* @param array $datastreams
* An array of .tif or .tiff datastreams to check.
*/
public function assertTiffDatastreams($object, array $datastreams) {
if (!is_object($object)) {
$this->fail("Failed. Object passed in is invalid.", 'Islandora');
return FALSE;
}
foreach ($datastreams as $datastream) {
$datastream_string = $object[$datastream]->content;
$datastream_header_hex = substr(bin2hex($datastream_string), 0, 8);
if ($datastream_header_hex == "49492a00") {
// In this case, the ingested TIFF is designated as using the "Intel
// byte-order" (e.g. little-endian) by starting with the characters "II"
// (repeated so that byte order does not yet need to be significant).
// The number that follows is '42' in little-endian hex, a number of
// 'deep philosophical significance' to the TIFF format creators.
$this->pass(t("{$datastream} datastream asserts that it is a valid Intel-byte-orderded TIF/TIFF file."), 'Islandora');
}
else if ($datastream_header_hex == "4d4d002a") {
// In this case, the ingested TIFF is designated as using the "Motorola
// byte-order" (e.g. big-endian) by starting with the characters "MM"
// instead. 42 follows once again, this time in big-endian hex.
$this->pass(t("{$datastream} datastream asserts that it is a valid Motorola-byte-ordered TIF/TIFF file."), 'Islandora');
}
else {
$this->fail(t("{$datastream} datastream does not assert that it is a valid TIF/TIFF file."), 'Islandora');
}
}
}
/**
* Asserts the validity of any .jp2 datastreams, which we also have a lot of.
*
* @param AbstractObject $object
* The PID of the object.
* @param array $datastreams
* An array of .jp2 datastreams to check.
*/
public function assertJp2Datastreams($object, array $datastreams) {
if (!is_object($object)) {
$this->fail("Failed. Object passed in is invalid.", 'Islandora');
return FALSE;
}
foreach ($datastreams as $datastream) {
$datastream_hex = bin2hex($object[$datastream]->content);
// .jp2 files begin with an offset header at the second 32-bit integer,
// 0x6A502020. This header is in all .jp2s, and we check for it here.
$this->assertTrue(substr($datastream_hex, 8, 8) == '6a502020', t("{$datastream} datastream begins correctly with the appropriate .jp2 header."), 'Islandora');
// .jp2 files have their codestream capped with a marker, 0xFFD9. We're
// just checking for it here to see if the .jp2 encoder finished okay.
$this->assertTrue(substr($datastream_hex, strlen($datastream_hex) - 4, 4) == 'ffd9', t("{$datastream} datastream ends correctly with the appropriate .jp2 marker."), 'Islandora');
}
}
/** /**
* Gets a tuque object from a path. * Gets a tuque object from a path.
* *
@ -311,38 +259,6 @@ class IslandoraWebTestCase extends DrupalWebTestCase {
$this->assertResponse(404, "Object $pid successfully deleted."); $this->assertResponse(404, "Object $pid successfully deleted.");
} }
/**
* Reverses a hex string and converts it to a little-endian-formatted integer.
*
* This is useful for running checks on values that appear in the binary
* of a datastream. Returns FALSE if the hex value contains non-hex characters
* or if the string would not return a 16- or 32-bit formatted big-endian
* signed integer.
*
* @param string $hex
* The hex value being converted.
*
* @return bool|int
* FALSE or the integer value that is converted.
*/
public function convertHexToInt($hex) {
// A couple of quick string checks.
if (!ctype_xdigit($hex)) {
$this->fail('String passed to convertHexToInt() contains non-hexidecimal characters.', 'PHP');
return FALSE;
}
if (!strlen($hex) === 4 || !strlen($hex) === 8) {
$this->fail('String passed to convertHexToInt() cannot create a 16- or 32-bit little-endian signed integer', 'PHP');
return FALSE;
}
// The actual conversion.
$reverse_hex = implode('', array_reverse(str_split($hex, 2)));
$int = hexdec($reverse_hex);
return $int;
}
/** /**
* Constructs and ingests a Fedora object and datastream(s) via tuque. * Constructs and ingests a Fedora object and datastream(s) via tuque.
* *

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