description = [[ Spiders a site's images looking for interesting exif data embedded in .jpg files. Displays the make and model of the camera, the date the photo was taken, and the embedded geotag information. ]] --- -- @usage -- nmap --script http-exif-spider -p80,443 -- -- @output -- PORT STATE SERVICE REASON -- 80/tcp open http syn-ack -- | http-exif-spider: -- | http://www.javaop.com/Nationalmuseum.jpg -- | Make: Canon -- | Model: Canon PowerShot S100\xB4 -- | Date: 2003:03:29 13:35:40 -- | http://www.javaop.com/topleft.jpg -- |_ GPS: 49.941250,-97.206189 - https://maps.google.com/maps?q=49.94125,-97.20618863493 -- -- @args http-exif-spider.url the url to start spidering. This is a URL -- relative to the scanned host eg. /default.html (default: /) author = "Ron Bowes" license = "Same as Nmap--See http://nmap.org/book/man-legal.html" categories = {"intrusive"} local shortport = require 'shortport' local stdnse = require 'stdnse' local httpspider = require 'httpspider' local string = require 'string' local bin = require 'bin' local bit = require 'bit' local table = require 'table' -- These definitions are copied/pasted/reformatted from the jhead-2.96 sourcecode -- (the code is effectively public domain, but credit where credit's due!) TAG_INTEROP_INDEX = 0x0001 TAG_INTEROP_VERSION = 0x0002 TAG_IMAGE_WIDTH = 0x0100 TAG_IMAGE_LENGTH = 0x0101 TAG_BITS_PER_SAMPLE = 0x0102 TAG_COMPRESSION = 0x0103 TAG_PHOTOMETRIC_INTERP = 0x0106 TAG_FILL_ORDER = 0x010A TAG_DOCUMENT_NAME = 0x010D TAG_IMAGE_DESCRIPTION = 0x010E TAG_MAKE = 0x010F TAG_MODEL = 0x0110 TAG_SRIP_OFFSET = 0x0111 TAG_ORIENTATION = 0x0112 TAG_SAMPLES_PER_PIXEL = 0x0115 TAG_ROWS_PER_STRIP = 0x0116 TAG_STRIP_BYTE_COUNTS = 0x0117 TAG_X_RESOLUTION = 0x011A TAG_Y_RESOLUTION = 0x011B TAG_PLANAR_CONFIGURATION = 0x011C TAG_RESOLUTION_UNIT = 0x0128 TAG_TRANSFER_FUNCTION = 0x012D TAG_SOFTWARE = 0x0131 TAG_DATETIME = 0x0132 TAG_ARTIST = 0x013B TAG_WHITE_POINT = 0x013E TAG_PRIMARY_CHROMATICITIES = 0x013F TAG_TRANSFER_RANGE = 0x0156 TAG_JPEG_PROC = 0x0200 TAG_THUMBNAIL_OFFSET = 0x0201 TAG_THUMBNAIL_LENGTH = 0x0202 TAG_Y_CB_CR_COEFFICIENTS = 0x0211 TAG_Y_CB_CR_SUB_SAMPLING = 0x0212 TAG_Y_CB_CR_POSITIONING = 0x0213 TAG_REFERENCE_BLACK_WHITE = 0x0214 TAG_RELATED_IMAGE_WIDTH = 0x1001 TAG_RELATED_IMAGE_LENGTH = 0x1002 TAG_CFA_REPEAT_PATTERN_DIM = 0x828D TAG_CFA_PATTERN1 = 0x828E TAG_BATTERY_LEVEL = 0x828F TAG_COPYRIGHT = 0x8298 TAG_EXPOSURETIME = 0x829A TAG_FNUMBER = 0x829D TAG_IPTC_NAA = 0x83BB TAG_EXIF_OFFSET = 0x8769 TAG_INTER_COLOR_PROFILE = 0x8773 TAG_EXPOSURE_PROGRAM = 0x8822 TAG_SPECTRAL_SENSITIVITY = 0x8824 TAG_GPSINFO = 0x8825 TAG_ISO_EQUIVALENT = 0x8827 TAG_OECF = 0x8828 TAG_EXIF_VERSION = 0x9000 TAG_DATETIME_ORIGINAL = 0x9003 TAG_DATETIME_DIGITIZED = 0x9004 TAG_COMPONENTS_CONFIG = 0x9101 TAG_CPRS_BITS_PER_PIXEL = 0x9102 TAG_SHUTTERSPEED = 0x9201 TAG_APERTURE = 0x9202 TAG_BRIGHTNESS_VALUE = 0x9203 TAG_EXPOSURE_BIAS = 0x9204 TAG_MAXAPERTURE = 0x9205 TAG_SUBJECT_DISTANCE = 0x9206 TAG_METERING_MODE = 0x9207 TAG_LIGHT_SOURCE = 0x9208 TAG_FLASH = 0x9209 TAG_FOCALLENGTH = 0x920A TAG_SUBJECTAREA = 0x9214 TAG_MAKER_NOTE = 0x927C TAG_USERCOMMENT = 0x9286 TAG_SUBSEC_TIME = 0x9290 TAG_SUBSEC_TIME_ORIG = 0x9291 TAG_SUBSEC_TIME_DIG = 0x9292 TAG_WINXP_TITLE = 0x9c9b TAG_WINXP_COMMENT = 0x9c9c TAG_WINXP_AUTHOR = 0x9c9d TAG_WINXP_KEYWORDS = 0x9c9e TAG_WINXP_SUBJECT = 0x9c9f TAG_FLASH_PIX_VERSION = 0xA000 TAG_COLOR_SPACE = 0xA001 TAG_PIXEL_X_DIMENSION = 0xA002 TAG_PIXEL_Y_DIMENSION = 0xA003 TAG_RELATED_AUDIO_FILE = 0xA004 TAG_INTEROP_OFFSET = 0xA005 TAG_FLASH_ENERGY = 0xA20B TAG_SPATIAL_FREQ_RESP = 0xA20C TAG_FOCAL_PLANE_XRES = 0xA20E TAG_FOCAL_PLANE_YRES = 0xA20F TAG_FOCAL_PLANE_UNITS = 0xA210 TAG_SUBJECT_LOCATION = 0xA214 TAG_EXPOSURE_INDEX = 0xA215 TAG_SENSING_METHOD = 0xA217 TAG_FILE_SOURCE = 0xA300 TAG_SCENE_TYPE = 0xA301 TAG_CFA_PATTERN = 0xA302 TAG_CUSTOM_RENDERED = 0xA401 TAG_EXPOSURE_MODE = 0xA402 TAG_WHITEBALANCE = 0xA403 TAG_DIGITALZOOMRATIO = 0xA404 TAG_FOCALLENGTH_35MM = 0xA405 TAG_SCENE_CAPTURE_TYPE = 0xA406 TAG_GAIN_CONTROL = 0xA407 TAG_CONTRAST = 0xA408 TAG_SATURATION = 0xA409 TAG_SHARPNESS = 0xA40A TAG_DISTANCE_RANGE = 0xA40C TAG_IMAGE_UNIQUE_ID = 0xA420 TagTable = {} TagTable[TAG_INTEROP_INDEX] = "InteropIndex" TagTable[TAG_INTEROP_VERSION] = "InteropVersion" TagTable[TAG_IMAGE_WIDTH] = "ImageWidth" TagTable[TAG_IMAGE_LENGTH] = "ImageLength" TagTable[TAG_BITS_PER_SAMPLE] = "BitsPerSample" TagTable[TAG_COMPRESSION] = "Compression" TagTable[TAG_PHOTOMETRIC_INTERP] = "PhotometricInterpretation" TagTable[TAG_FILL_ORDER] = "FillOrder" TagTable[TAG_DOCUMENT_NAME] = "DocumentName" TagTable[TAG_IMAGE_DESCRIPTION] = "ImageDescription" TagTable[TAG_MAKE] = "Make" TagTable[TAG_MODEL] = "Model" TagTable[TAG_SRIP_OFFSET] = "StripOffsets" TagTable[TAG_ORIENTATION] = "Orientation" TagTable[TAG_SAMPLES_PER_PIXEL] = "SamplesPerPixel" TagTable[TAG_ROWS_PER_STRIP] = "RowsPerStrip" TagTable[TAG_STRIP_BYTE_COUNTS] = "StripByteCounts" TagTable[TAG_X_RESOLUTION] = "XResolution" TagTable[TAG_Y_RESOLUTION] = "YResolution" TagTable[TAG_PLANAR_CONFIGURATION] = "PlanarConfiguration" TagTable[TAG_RESOLUTION_UNIT] = "ResolutionUnit" TagTable[TAG_TRANSFER_FUNCTION] = "TransferFunction" TagTable[TAG_SOFTWARE] = "Software" TagTable[TAG_DATETIME] = "DateTime" TagTable[TAG_ARTIST] = "Artist" TagTable[TAG_WHITE_POINT] = "WhitePoint" TagTable[TAG_PRIMARY_CHROMATICITIES]= "PrimaryChromaticities" TagTable[TAG_TRANSFER_RANGE] = "TransferRange" TagTable[TAG_JPEG_PROC] = "JPEGProc" TagTable[TAG_THUMBNAIL_OFFSET] = "ThumbnailOffset" TagTable[TAG_THUMBNAIL_LENGTH] = "ThumbnailLength" TagTable[TAG_Y_CB_CR_COEFFICIENTS] = "YCbCrCoefficients" TagTable[TAG_Y_CB_CR_SUB_SAMPLING] = "YCbCrSubSampling" TagTable[TAG_Y_CB_CR_POSITIONING] = "YCbCrPositioning" TagTable[TAG_REFERENCE_BLACK_WHITE] = "ReferenceBlackWhite" TagTable[TAG_RELATED_IMAGE_WIDTH] = "RelatedImageWidth" TagTable[TAG_RELATED_IMAGE_LENGTH] = "RelatedImageLength" TagTable[TAG_CFA_REPEAT_PATTERN_DIM]= "CFARepeatPatternDim" TagTable[TAG_CFA_PATTERN1] = "CFAPattern" TagTable[TAG_BATTERY_LEVEL] = "BatteryLevel" TagTable[TAG_COPYRIGHT] = "Copyright" TagTable[TAG_EXPOSURETIME] = "ExposureTime" TagTable[TAG_FNUMBER] = "FNumber" TagTable[TAG_IPTC_NAA] = "IPTC/NAA" TagTable[TAG_EXIF_OFFSET] = "ExifOffset" TagTable[TAG_INTER_COLOR_PROFILE] = "InterColorProfile" TagTable[TAG_EXPOSURE_PROGRAM] = "ExposureProgram" TagTable[TAG_SPECTRAL_SENSITIVITY] = "SpectralSensitivity" TagTable[TAG_GPSINFO] = "GPS Dir offset" TagTable[TAG_ISO_EQUIVALENT] = "ISOSpeedRatings" TagTable[TAG_OECF] = "OECF" TagTable[TAG_EXIF_VERSION] = "ExifVersion" TagTable[TAG_DATETIME_ORIGINAL] = "DateTimeOriginal" TagTable[TAG_DATETIME_DIGITIZED] = "DateTimeDigitized" TagTable[TAG_COMPONENTS_CONFIG] = "ComponentsConfiguration" TagTable[TAG_CPRS_BITS_PER_PIXEL] = "CompressedBitsPerPixel" TagTable[TAG_SHUTTERSPEED] = "ShutterSpeedValue" TagTable[TAG_APERTURE] = "ApertureValue" TagTable[TAG_BRIGHTNESS_VALUE] = "BrightnessValue" TagTable[TAG_EXPOSURE_BIAS] = "ExposureBiasValue" TagTable[TAG_MAXAPERTURE] = "MaxApertureValue" TagTable[TAG_SUBJECT_DISTANCE] = "SubjectDistance" TagTable[TAG_METERING_MODE] = "MeteringMode" TagTable[TAG_LIGHT_SOURCE] = "LightSource" TagTable[TAG_FLASH] = "Flash" TagTable[TAG_FOCALLENGTH] = "FocalLength" TagTable[TAG_MAKER_NOTE] = "MakerNote" TagTable[TAG_USERCOMMENT] = "UserComment" TagTable[TAG_SUBSEC_TIME] = "SubSecTime" TagTable[TAG_SUBSEC_TIME_ORIG] = "SubSecTimeOriginal" TagTable[TAG_SUBSEC_TIME_DIG] = "SubSecTimeDigitized" TagTable[TAG_WINXP_TITLE] = "Windows-XP Title" TagTable[TAG_WINXP_COMMENT] = "Windows-XP comment" TagTable[TAG_WINXP_AUTHOR] = "Windows-XP author" TagTable[TAG_WINXP_KEYWORDS] = "Windows-XP keywords" TagTable[TAG_WINXP_SUBJECT] = "Windows-XP subject" TagTable[TAG_FLASH_PIX_VERSION] = "FlashPixVersion" TagTable[TAG_COLOR_SPACE] = "ColorSpace" TagTable[TAG_PIXEL_X_DIMENSION] = "ExifImageWidth" TagTable[TAG_PIXEL_Y_DIMENSION] = "ExifImageLength" TagTable[TAG_RELATED_AUDIO_FILE] = "RelatedAudioFile" TagTable[TAG_INTEROP_OFFSET] = "InteroperabilityOffset" TagTable[TAG_FLASH_ENERGY] = "FlashEnergy" TagTable[TAG_SPATIAL_FREQ_RESP] = "SpatialFrequencyResponse" TagTable[TAG_FOCAL_PLANE_XRES] = "FocalPlaneXResolution" TagTable[TAG_FOCAL_PLANE_YRES] = "FocalPlaneYResolution" TagTable[TAG_FOCAL_PLANE_UNITS] = "FocalPlaneResolutionUnit" TagTable[TAG_SUBJECT_LOCATION] = "SubjectLocation" TagTable[TAG_EXPOSURE_INDEX] = "ExposureIndex" TagTable[TAG_SENSING_METHOD] = "SensingMethod" TagTable[TAG_FILE_SOURCE] = "FileSource" TagTable[TAG_SCENE_TYPE] = "SceneType" TagTable[TAG_CFA_PATTERN] = "CFA Pattern" TagTable[TAG_CUSTOM_RENDERED] = "CustomRendered" TagTable[TAG_EXPOSURE_MODE] = "ExposureMode" TagTable[TAG_WHITEBALANCE] = "WhiteBalance" TagTable[TAG_DIGITALZOOMRATIO] = "DigitalZoomRatio" TagTable[TAG_FOCALLENGTH_35MM] = "FocalLengthIn35mmFilm" TagTable[TAG_SUBJECTAREA] = "SubjectArea" TagTable[TAG_SCENE_CAPTURE_TYPE] = "SceneCaptureType" TagTable[TAG_GAIN_CONTROL] = "GainControl" TagTable[TAG_CONTRAST] = "Contrast" TagTable[TAG_SATURATION] = "Saturation" TagTable[TAG_SHARPNESS] = "Sharpness" TagTable[TAG_DISTANCE_RANGE] = "SubjectDistanceRange" TagTable[TAG_IMAGE_UNIQUE_ID] = "ImageUniqueId" GPS_TAG_VERSIONID = 0X00 GPS_TAG_LATITUDEREF = 0X01 GPS_TAG_LATITUDE = 0X02 GPS_TAG_LONGITUDEREF = 0X03 GPS_TAG_LONGITUDE = 0X04 GPS_TAG_ALTITUDEREF = 0X05 GPS_TAG_ALTITUDE = 0X06 GPS_TAG_TIMESTAMP = 0X07 GPS_TAG_SATELLITES = 0X08 GPS_TAG_STATUS = 0X09 GPS_TAG_MEASUREMODE = 0X0A GPS_TAG_DOP = 0X0B GPS_TAG_SPEEDREF = 0X0C GPS_TAG_SPEED = 0X0D GPS_TAG_TRACKREF = 0X0E GPS_TAG_TRACK = 0X0F GPS_TAG_IMGDIRECTIONREF = 0X10 GPS_TAG_IMGDIRECTION = 0X11 GPS_TAG_MAPDATUM = 0X12 GPS_TAG_DESTLATITUDEREF = 0X13 GPS_TAG_DESTLATITUDE = 0X14 GPS_TAG_DESTLONGITUDEREF = 0X15 GPS_TAG_DESTLONGITUDE = 0X16 GPS_TAG_DESTBEARINGREF = 0X17 GPS_TAG_DESTBEARING = 0X18 GPS_TAG_DESTDISTANCEREF = 0X19 GPS_TAG_DESTDISTANCE = 0X1A GPS_TAG_PROCESSINGMETHOD = 0X1B GPS_TAG_AREAINFORMATION = 0X1C GPS_TAG_DATESTAMP = 0X1D GPS_TAG_DIFFERENTIAL = 0X1E GpsTagTable = {} GpsTagTable[GPS_TAG_VERSIONID] = "VersionID" GpsTagTable[GPS_TAG_LATITUDEREF] = "LatitudeRef" GpsTagTable[GPS_TAG_LATITUDE] = "Latitude" GpsTagTable[GPS_TAG_LONGITUDEREF] = "LongitudeRef" GpsTagTable[GPS_TAG_LONGITUDE] = "Longitude" GpsTagTable[GPS_TAG_ALTITUDEREF] = "AltitudeRef" GpsTagTable[GPS_TAG_ALTITUDE] = "Altitude" GpsTagTable[GPS_TAG_TIMESTAMP] = "Timestamp" GpsTagTable[GPS_TAG_SATELLITES] = "Satellites" GpsTagTable[GPS_TAG_STATUS] = "Status" GpsTagTable[GPS_TAG_MEASUREMODE] = "MeasureMode" GpsTagTable[GPS_TAG_DOP] = "Dop" GpsTagTable[GPS_TAG_SPEEDREF] = "SpeedRef" GpsTagTable[GPS_TAG_SPEED] = "Speed" GpsTagTable[GPS_TAG_TRACKREF] = "TrafRef" GpsTagTable[GPS_TAG_TRACK] = "Track" GpsTagTable[GPS_TAG_IMGDIRECTIONREF] = "ImgDirectionRef" GpsTagTable[GPS_TAG_IMGDIRECTION] = "ImgDirection" GpsTagTable[GPS_TAG_MAPDATUM] = "MapDatum" GpsTagTable[GPS_TAG_DESTLATITUDEREF] = "DestLatitudeRef" GpsTagTable[GPS_TAG_DESTLATITUDE] = "DestLatitude" GpsTagTable[GPS_TAG_DESTLONGITUDEREF]= "DestLongitudeRef" GpsTagTable[GPS_TAG_DESTLONGITUDE] = "DestLongitude" GpsTagTable[GPS_TAG_DESTBEARINGREF] = "DestBearingref" GpsTagTable[GPS_TAG_DESTBEARING] = "DestBearing" GpsTagTable[GPS_TAG_DESTDISTANCEREF] = "DestDistanceRef" GpsTagTable[GPS_TAG_DESTDISTANCE] = "DestDistance" GpsTagTable[GPS_TAG_PROCESSINGMETHOD]= "ProcessingMethod" GpsTagTable[GPS_TAG_AREAINFORMATION] = "AreaInformation" GpsTagTable[GPS_TAG_DATESTAMP] = "Datestamp" GpsTagTable[GPS_TAG_DIFFERENTIAL] = "Differential" FMT_BYTE = 1 FMT_STRING = 2 FMT_USHORT = 3 FMT_ULONG = 4 FMT_URATIONAL = 5 FMT_SBYTE = 6 FMT_UNDEFINED = 7 FMT_SSHORT = 8 FMT_SLONG = 9 FMT_SRATIONAL = 10 FMT_SINGLE = 11 FMT_DOUBLE = 12 bytes_per_format = {0,1,1,2,4,8,1,1,2,4,8,4,8} portrule = shortport.http ---Unpack a rational number from exif. In exif, a rational number is stored --as a pair of integers - the numerator and the denominator. -- --@return the new position, and the value. local function unpack_rational(endian, data, pos) local v1, v2 pos, v1, v2 = bin.unpack(endian .. "II", data, pos) return pos, v1 / v2 end local function process_gps(data, pos, endian, result) local value, num_entries local latitude, latitude_ref, longitude, longitude_ref -- The first entry in the gps section is a 16-bit size pos, num_entries = bin.unpack(endian .. "S", data, pos) -- Loop through the entries to find the fun stuff for i=1, num_entries do local pos, tag, format, components, value = bin.unpack(endian .. "SSII", data, pos) if(tag == GPS_TAG_LATITUDE or tag == GPS_TAG_LONGITUDE) then local dummy, gps, h, m, s dummy, h = unpack_rational(endian, data, value + 8) dummy, m = unpack_rational(endian, data, dummy) dummy, s = unpack_rational(endian, data, dummy) gps = h + (m / 60) + (s / 60 / 60) if(tag == GPS_TAG_LATITUDE) then latitude = gps else longitude = gps end elseif(tag == GPS_TAG_LATITUDEREF) then -- Get the first byte in the latitude reference as a character latitude_ref = string.char(bit.rshift(value, 24)) elseif(tag == GPS_TAG_LONGITUDEREF) then -- Get the first byte in the longitude reference as a character longitude_ref = string.char(bit.rshift(value, 24)) end end if(latitude and longitude) then -- Normalize the N/S/E/W to positive and negative if(latitude_ref == 'S') then latitude = -latitude end if(longitude_ref == 'W') then longitude = -longitude end table.insert(result, string.format("GPS: %f,%f - https://maps.google.com/maps?q=%s,%s", latitude, longitude, latitude, longitude)) end return true, result end ---Parse the exif data section and return a table. This has only been tested --in a .jpeg file, but should work for .tiff as well. local function parse_exif(exif_data) local sig, marker, size local tag, format, components, byte_count, value, offset, dummy, data local status, result local tiff_header_1, first_offset -- Initialize the result table result = {} -- Read the verify the EXIF header local pos, header1, header2, endian = bin.unpack(">ISS", exif_data, 1) if(header1 ~= 0x45786966 or header2 ~= 0x0000) then return false, "Invalid EXIF header" end -- Check the endianness - it should only ever be big endian, but it doesn't -- hurt to check if(endian == 0x4d4d) then endian = ">" elseif(endian == 0x4949) then endian = "<" else return false, "Unrecognized endianness entry" end -- Read the first tiff header and the offset to the first data entry (should be 8) pos, tiff_header_1, first_offset = bin.unpack(endian .. "SI", exif_data, pos) if(tiff_header_1 ~= 0x002A or first_offset ~= 0x00000008) then return false, "Invalid tiff header" end -- Skip over the header, and go to the first offset (subtracting 1 because lua) pos = first_offset + 8 - 1 -- The first 16-bit value is the number of entries local pos, num_entries = bin.unpack(endian .. "S", exif_data, pos) -- Loop through the entries for i=1,num_entries do -- Read the entry's header pos, tag, format, components, value = bin.unpack(endian .. "SSII", exif_data, pos) -- Look at the tags we care about if(tag == TAG_GPSINFO) then -- If it's a GPSINFO tag, we need to parse the GPS structure status, result = process_gps(exif_data, value + 8 - 1, endian, result) if(not(status)) then return false, result end elseif(tag == TAG_MAKE) then dummy, value = bin.unpack("z", exif_data, value + 8 - 1) table.insert(result, string.format("Make: %s", value)) elseif(tag == TAG_MODEL) then dummy, value = bin.unpack("z", exif_data, value + 8 - 1) table.insert(result, string.format("Model: %s", value)) elseif(tag == TAG_DATETIME) then dummy, value = bin.unpack("z", exif_data, value + 8 - 1) table.insert(result, string.format("Date: %s", value)) end end return true, result end ---Parse a jpeg and find the EXIF data section local function parse_jpeg(s) local pos, sig, marker, size, exif_data -- Parse the jpeg header, make sure it's valid (we expect 0xFFD8) pos, sig = bin.unpack(">S", s, pos) if(sig ~= 0xFFD8) then return false, "Unexpected signature" end -- Parse the sections to find the exif marker (0xffe1) while(true) do pos, marker, size = bin.unpack(">SS", s, pos) -- Check if we found the exif metadata section, break if we did if(marker == 0xffe1) then break -- If the marker is nil, we're off the end of the image (and therefore, it wasn't found) elseif(not(marker)) then return false, "Could not found EXIF marker" end -- Go to the next section (we subtract 2 because of the 2-byte marker we read) pos = pos + size - 2 end pos, exif_data = bin.unpack(string.format(">A%d", size), s, pos) return parse_exif(exif_data) end function action(host, port) local pattern = "%.jpg" local images = {} local results = {} -- once we know the pattern we'll be searching for, we can set up the function local whitelist = function(url) return string.match(url.file, "%.jpg") or string.match(url.file, "%.jpeg") end local crawler = httpspider.Crawler:new( host, port, nil, { scriptname = SCRIPT_NAME, whitelist = { whitelist }} ) if ( not(crawler) ) then return end while(true) do -- Begin the crawler local status, r = crawler:crawl() -- Make sure there's no error if ( not(status) ) then if ( r.err ) then return stdnse.format_output(false, r.reason) else break end end -- Check if we got a response, and the response is a .jpg file if r.response and r.response.body and r.response.status==200 and (string.match(r.url.path, ".jpg") or string.match(r.url.path, ".jpeg")) then local status, result stdnse.debug1("Attempting to read exif data from %s", r.url.raw) status, result = parse_jpeg(r.response.body) if(not(status)) then stdnse.debug1("Couldn't read exif from %s: %s", r.url.raw, result) else -- If there are any exif results, add them to the result if(result and #result > 0) then result['name'] = r.url.raw table.insert(results, result) end end end end return stdnse.format_output(true, results) end