require 'net/http' require 'uri' module Irc # miscellaneous useful functions module Utils # read a time in string format, turn it into "seconds from now". # example formats handled are "5 minutes", "2 days", "five hours", # "11:30", "15:45:11", "one day", etc. # # Throws:: RunTimeError "invalid time string" on parse failure def Utils.timestr_offset(timestr) case timestr when (/^(\S+)\s+(\S+)$/) mult = $1 unit = $2 if(mult =~ /^([\d.]+)$/) num = $1.to_f raise "invalid time string" unless num else case mult when(/^(one|an|a)$/) num = 1 when(/^two$/) num = 2 when(/^three$/) num = 3 when(/^four$/) num = 4 when(/^five$/) num = 5 when(/^six$/) num = 6 when(/^seven$/) num = 7 when(/^eight$/) num = 8 when(/^nine$/) num = 9 when(/^ten$/) num = 10 when(/^fifteen$/) num = 15 when(/^twenty$/) num = 20 when(/^thirty$/) num = 30 when(/^sixty$/) num = 60 else raise "invalid time string" end end case unit when (/^(s|sec(ond)?s?)$/) return num when (/^(m|min(ute)?s?)$/) return num * 60 when (/^(h|h(ou)?rs?)$/) return num * 60 * 60 when (/^(d|days?)$/) return num * 60 * 60 * 24 else raise "invalid time string" end when (/^(\d+):(\d+):(\d+)$/) hour = $1.to_i min = $2.to_i sec = $3.to_i now = Time.now later = Time.mktime(now.year, now.month, now.day, hour, min, sec) return later - now when (/^(\d+):(\d+)$/) hour = $1.to_i min = $2.to_i now = Time.now later = Time.mktime(now.year, now.month, now.day, hour, min, now.sec) return later - now when (/^(\d+):(\d+)(am|pm)$/) hour = $1.to_i min = $2.to_i ampm = $3 if ampm == "pm" hour += 12 end now = Time.now later = Time.mktime(now.year, now.month, now.day, hour, min, now.sec) return later - now when (/^(\S+)$/) num = 1 unit = $1 case unit when (/^(s|sec(ond)?s?)$/) return num when (/^(m|min(ute)?s?)$/) return num * 60 when (/^(h|h(ou)?rs?)$/) return num * 60 * 60 when (/^(d|days?)$/) return num * 60 * 60 * 24 else raise "invalid time string" end else raise "invalid time string" end end # turn a number of seconds into a human readable string, e.g # 2 days, 3 hours, 18 minutes, 10 seconds def Utils.secs_to_string(secs) ret = "" days = (secs / (60 * 60 * 24)).to_i secs = secs % (60 * 60 * 24) hours = (secs / (60 * 60)).to_i secs = (secs % (60 * 60)) mins = (secs / 60).to_i secs = (secs % 60).to_i ret += "#{days} days, " if days > 0 ret += "#{hours} hours, " if hours > 0 || days > 0 ret += "#{mins} minutes and " if mins > 0 || hours > 0 || days > 0 ret += "#{secs} seconds" return ret end def Utils.safe_exec(command, *args) IO.popen("-") {|p| if(p) return p.readlines.join("\n") else begin $stderr = $stdout exec(command, *args) rescue Exception => e puts "exec of #{command} led to exception: #{e}" Kernel::exit! 0 end puts "exec of #{command} failed" Kernel::exit! 0 end } end # returns a string containing the result of an HTTP GET on the uri def Utils.http_get(uristr, readtimeout=8, opentimeout=4) # ruby 1.7 or better needed for this (or 1.6 and debian unstable) Net::HTTP.version_1_2 # (so we support the 1_1 api anyway, avoids problems) uri = URI.parse uristr query = uri.path if uri.query query += "?#{uri.query}" end proxy_host = nil proxy_port = nil if(ENV['http_proxy'] && proxy_uri = URI.parse(ENV['http_proxy'])) proxy_host = proxy_uri.host proxy_port = proxy_uri.port end http = Net::HTTP.new(uri.host, uri.port, proxy_host, proxy_port) http.open_timeout = opentimeout http.read_timeout = readtimeout begin http.start {|http| resp = http.get(query) if resp.code == "200" return resp.body end } rescue => e # cheesy for now $stderr.puts "Utils.http_get exception: #{e}, while trying to get #{uristr}" return nil end end # This is nasty-ass. I hate writing parsers. class Metar attr_reader :decoded attr_reader :input attr_reader :date attr_reader :nodata def initialize(string) str = nil @nodata = false string.each_line {|l| if str == nil # grab first line (date) @date = l.chomp.strip str = "" else if(str == "") str = l.chomp.strip else str += " " + l.chomp.strip end end } if @date && @date =~ /^(\d+)\/(\d+)\/(\d+) (\d+):(\d+)$/ # 2002/02/26 05:00 @date = Time.gm($1, $2, $3, $4, $5, 0) else @date = Time.now end @input = str.chomp @cloud_layers = 0 @cloud_coverage = { 'SKC' => '0', 'CLR' => '0', 'VV' => '8/8', 'FEW' => '1/8 - 2/8', 'SCT' => '3/8 - 4/8', 'BKN' => '5/8 - 7/8', 'OVC' => '8/8' } @wind_dir_texts = [ 'North', 'North/Northeast', 'Northeast', 'East/Northeast', 'East', 'East/Southeast', 'Southeast', 'South/Southeast', 'South', 'South/Southwest', 'Southwest', 'West/Southwest', 'West', 'West/Northwest', 'Northwest', 'North/Northwest', 'North' ] @wind_dir_texts_short = [ 'N', 'N/NE', 'NE', 'E/NE', 'E', 'E/SE', 'SE', 'S/SE', 'S', 'S/SW', 'SW', 'W/SW', 'W', 'W/NW', 'NW', 'N/NW', 'N' ] @weather_array = { 'MI' => 'Mild ', 'PR' => 'Partial ', 'BC' => 'Patches ', 'DR' => 'Low Drifting ', 'BL' => 'Blowing ', 'SH' => 'Shower(s) ', 'TS' => 'Thunderstorm ', 'FZ' => 'Freezing', 'DZ' => 'Drizzle ', 'RA' => 'Rain ', 'SN' => 'Snow ', 'SG' => 'Snow Grains ', 'IC' => 'Ice Crystals ', 'PE' => 'Ice Pellets ', 'GR' => 'Hail ', 'GS' => 'Small Hail and/or Snow Pellets ', 'UP' => 'Unknown ', 'BR' => 'Mist ', 'FG' => 'Fog ', 'FU' => 'Smoke ', 'VA' => 'Volcanic Ash ', 'DU' => 'Widespread Dust ', 'SA' => 'Sand ', 'HZ' => 'Haze ', 'PY' => 'Spray', 'PO' => 'Well-Developed Dust/Sand Whirls ', 'SQ' => 'Squalls ', 'FC' => 'Funnel Cloud Tornado Waterspout ', 'SS' => 'Sandstorm/Duststorm ' } @cloud_condition_array = { 'SKC' => 'clear', 'CLR' => 'clear', 'VV' => 'vertical visibility', 'FEW' => 'a few', 'SCT' => 'scattered', 'BKN' => 'broken', 'OVC' => 'overcast' } @strings = { 'mm_inches' => '%s mm (%s inches)', 'precip_a_trace' => 'a trace', 'precip_there_was' => 'There was %s of precipitation ', 'sky_str_format1' => 'There were %s at a height of %s meters (%s feet)', 'sky_str_clear' => 'The sky was clear', 'sky_str_format2' => ', %s at a height of %s meter (%s feet) and %s at a height of %s meters (%s feet)', 'sky_str_format3' => ' and %s at a height of %s meters (%s feet)', 'clouds' => ' clouds', 'clouds_cb' => ' cumulonimbus clouds', 'clouds_tcu' => ' towering cumulus clouds', 'visibility_format' => 'The visibility was %s kilometers (%s miles).', 'wind_str_format1' => 'blowing at a speed of %s meters per second (%s miles per hour)', 'wind_str_format2' => ', with gusts to %s meters per second (%s miles per hour),', 'wind_str_format3' => ' from the %s', 'wind_str_calm' => 'calm', 'precip_last_hour' => 'in the last hour. ', 'precip_last_6_hours' => 'in the last 3 to 6 hours. ', 'precip_last_24_hours' => 'in the last 24 hours. ', 'precip_snow' => 'There is %s mm (%s inches) of snow on the ground. ', 'temp_min_max_6_hours' => 'The maximum and minimum temperatures over the last 6 hours were %s and %s degrees Celsius (%s and %s degrees Fahrenheit).', 'temp_max_6_hours' => 'The maximum temperature over the last 6 hours was %s degrees Celsius (%s degrees Fahrenheit). ', 'temp_min_6_hours' => 'The minimum temperature over the last 6 hours was %s degrees Celsius (%s degrees Fahrenheit). ', 'temp_min_max_24_hours' => 'The maximum and minimum temperatures over the last 24 hours were %s and %s degrees Celsius (%s and %s degrees Fahrenheit). ', 'light' => 'Light ', 'moderate' => 'Moderate ', 'heavy' => 'Heavy ', 'mild' => 'Mild ', 'nearby' => 'Nearby ', 'current_weather' => 'Current weather is %s. ', 'pretty_print_metar' => '%s on %s, the wind was %s at %s. The temperature was %s degrees Celsius (%s degrees Fahrenheit), and the pressure was %s hPa (%s inHg). The relative humidity was %s%%. %s %s %s %s %s' } parse end def store_speed(value, windunit, meterspersec, knots, milesperhour) # Helper function to convert and store speed based on unit. # &$meterspersec, &$knots and &$milesperhour are passed on # reference if (windunit == 'KT') # The windspeed measured in knots: @decoded[knots] = sprintf("%.2f", value) # The windspeed measured in meters per second, rounded to one decimal place: @decoded[meterspersec] = sprintf("%.2f", value.to_f * 0.51444) # The windspeed measured in miles per hour, rounded to one decimal place: */ @decoded[milesperhour] = sprintf("%.2f", value.to_f * 1.1507695060844667) elsif (windunit == 'MPS') # The windspeed measured in meters per second: @decoded[meterspersec] = sprintf("%.2f", value) # The windspeed measured in knots, rounded to one decimal place: @decoded[knots] = sprintf("%.2f", value.to_f / 0.51444) #The windspeed measured in miles per hour, rounded to one decimal place: @decoded[milesperhour] = sprintf("%.1f", value.to_f / 0.51444 * 1.1507695060844667) elsif (windunit == 'KMH') # The windspeed measured in kilometers per hour: @decoded[meterspersec] = sprintf("%.1f", value.to_f * 1000 / 3600) @decoded[knots] = sprintf("%.1f", value.to_f * 1000 / 3600 / 0.51444) # The windspeed measured in miles per hour, rounded to one decimal place: @decoded[milesperhour] = sprintf("%.1f", knots.to_f * 1.1507695060844667) end end def parse @decoded = Hash.new puts @input @input.split(" ").each {|part| if (part == 'METAR') # Type of Report: METAR @decoded['type'] = 'METAR' elsif (part == 'SPECI') # Type of Report: SPECI @decoded['type'] = 'SPECI' elsif (part == 'AUTO') # Report Modifier: AUTO @decoded['report_mod'] = 'AUTO' elsif (part == 'NIL') @nodata = true elsif (part =~ /^\S{4}$/ && ! (@decoded.has_key?('station'))) # Station Identifier @decoded['station'] = part elsif (part =~ /([0-9]{2})([0-9]{2})([0-9]{2})Z/) # ignore this bit, it's useless without month/year. some of these # things are hideously out of date. # now = Time.new # time = Time.gm(now.year, now.month, $1, $2, $3, 0) # Date and Time of Report # @decoded['time'] = time elsif (part == 'COR') # Report Modifier: COR @decoded['report_mod'] = 'COR' elsif (part =~ /([0-9]{3}|VRB)([0-9]{2,3}).*(KT|MPS|KMH)/) # Wind Group windunit = $3 # now do ereg to get the actual values part =~ /([0-9]{3}|VRB)([0-9]{2,3})((G[0-9]{2,3})?#{windunit})/ if ($1 == 'VRB') @decoded['wind_deg'] = 'variable directions' @decoded['wind_dir_text'] = 'variable directions' @decoded['wind_dir_text_short'] = 'VAR' else @decoded['wind_deg'] = $1 @decoded['wind_dir_text'] = @wind_dir_texts[($1.to_i/22.5).round] @decoded['wind_dir_text_short'] = @wind_dir_texts_short[($1.to_i/22.5).round] end store_speed($2, windunit, 'wind_meters_per_second', 'wind_knots', 'wind_miles_per_hour') if ($4 != nil) # We have a report with information about the gust. # First we have the gust measured in knots if ($4 =~ /G([0-9]{2,3})/) store_speed($1,windunit, 'wind_gust_meters_per_second', 'wind_gust_knots', 'wind_gust_miles_per_hour') end end elsif (part =~ /([0-9]{3})V([0-9]{3})/) # Variable wind-direction @decoded['wind_var_beg'] = $1 @decoded['wind_var_end'] = $2 elsif (part == "9999") # A strange value. When you look at other pages you see it # interpreted like this (where I use > to signify 'Greater # than'): @decoded['visibility_miles'] = '>7'; @decoded['visibility_km'] = '>11.3'; elsif (part =~ /^([0-9]{4})$/) # Visibility in meters (4 digits only) # The visibility measured in kilometers, rounded to one decimal place. @decoded['visibility_km'] = sprintf("%.1f", $1.to_i / 1000) # The visibility measured in miles, rounded to one decimal place. @decoded['visibility_miles'] = sprintf("%.1f", $1.to_i / 1000 / 1.609344) elsif (part =~ /^[0-9]$/) # Temp Visibility Group, single digit followed by space @decoded['temp_visibility_miles'] = part elsif (@decoded['temp_visibility_miles'] && (@decoded['temp_visibility_miles']+' '+part) =~ /^M?(([0-9]?)[ ]?([0-9])(\/?)([0-9]*))SM$/) # Visibility Group if ($4 == '/') vis_miles = $2.to_i + $3.to_i/$5.to_i else vis_miles = $1.to_i; end if (@decoded['temp_visibility_miles'][0] == 'M') # The visibility measured in miles, prefixed with < to indicate 'Less than' @decoded['visibility_miles'] = '<' + sprintf("%.1f", vis_miles) # The visibility measured in kilometers. The value is rounded # to one decimal place, prefixed with < to indicate 'Less than' */ @decoded['visibility_km'] = '<' . sprintf("%.1f", vis_miles * 1.609344) else # The visibility measured in mile.s */ @decoded['visibility_miles'] = sprintf("%.1f", vis_miles) # The visibility measured in kilometers, rounded to one decimal place. @decoded['visibility_km'] = sprintf("%.1f", vis_miles * 1.609344) end elsif (part =~ /^(-|\+|VC|MI)?(TS|SH|FZ|BL|DR|BC|PR|RA|DZ|SN|SG|GR|GS|PE|IC|UP|BR|FG|FU|VA|DU|SA|HZ|PY|PO|SQ|FC|SS|DS)+$/) # Current weather-group @decoded['weather'] = '' unless @decoded.has_key?('weather') if (part[0].chr == '-') # A light phenomenon @decoded['weather'] += @strings['light'] part = part[1,part.length] elsif (part[0].chr == '+') # A heavy phenomenon @decoded['weather'] += @strings['heavy'] part = part[1,part.length] elsif (part[0,2] == 'VC') # Proximity Qualifier @decoded['weather'] += @strings['nearby'] part = part[2,part.length] elsif (part[0,2] == 'MI') @decoded['weather'] += @strings['mild'] part = part[2,part.length] else # no intensity code => moderate phenomenon @decoded['weather'] += @strings['moderate'] end while (part && bite = part[0,2]) do # Now we take the first two letters and determine what they # mean. We append this to the variable so that we gradually # build up a phrase. @decoded['weather'] += @weather_array[bite] # Here we chop off the two first letters, so that we can take # a new bite at top of the while-loop. part = part[2,-1] end elsif (part =~ /(SKC|CLR)/) # Cloud-layer-group. # There can be up to three of these groups, so we store them as # cloud_layer1, cloud_layer2 and cloud_layer3. @cloud_layers += 1; # Again we have to translate the code-characters to a # meaningful string. @decoded['cloud_layer'+ (@cloud_layers.to_s) +'_condition'] = @cloud_condition_array[$1] @decoded['cloud_layer'+ (@cloud_layers.to_s) +'_coverage'] = @cloud_coverage[$1] elsif (part =~ /^(VV|FEW|SCT|BKN|OVC)([0-9]{3})(CB|TCU)?$/) # We have found (another) a cloud-layer-group. There can be up # to three of these groups, so we store them as cloud_layer1, # cloud_layer2 and cloud_layer3. @cloud_layers += 1; # Again we have to translate the code-characters to a meaningful string. if ($3 == 'CB') # cumulonimbus (CB) clouds were observed. */ @decoded['cloud_layer'+ (@cloud_layers.to_s) +'_condition'] = @cloud_condition_array[$1] + @strings['clouds_cb'] elsif ($3 == 'TCU') # towering cumulus (TCU) clouds were observed. @decoded['cloud_layer'+ (@cloud_layers.to_s) +'_condition'] = @cloud_condition_array[$1] + @strings['clouds_tcu'] else @decoded['cloud_layer'+ (@cloud_layers.to_s) +'_condition'] = @cloud_condition_array[$1] + @strings['clouds'] end @decoded['cloud_layer'+ (@cloud_layers.to_s) +'_coverage'] = @cloud_coverage[$1] @decoded['cloud_layer'+ (@cloud_layers.to_s) +'_altitude_ft'] = $2.to_i * 100 @decoded['cloud_layer'+ (@cloud_layers.to_s) +'_altitude_m'] = ($2.to_f * 30.48).round elsif (part =~ /^T([0-9]{4})$/) store_temp($1,'temp_c','temp_f') elsif (part =~ /^T?(M?[0-9]{2})\/(M?[0-9\/]{1,2})?$/) # Temperature/Dew Point Group # The temperature and dew-point measured in Celsius. @decoded['temp_c'] = sprintf("%d", $1.tr('M', '-')) if $2 == "//" || !$2 @decoded['dew_c'] = 0 else @decoded['dew_c'] = sprintf("%.1f", $2.tr('M', '-')) end # The temperature and dew-point measured in Fahrenheit, rounded to # the nearest degree. @decoded['temp_f'] = ((@decoded['temp_c'].to_f * 9 / 5) + 32).round @decoded['dew_f'] = ((@decoded['dew_c'].to_f * 9 / 5) + 32).round elsif(part =~ /A([0-9]{4})/) # Altimeter # The pressure measured in inHg @decoded['altimeter_inhg'] = sprintf("%.2f", $1.to_i/100) # The pressure measured in mmHg, hPa and atm @decoded['altimeter_mmhg'] = sprintf("%.1f", $1.to_f * 0.254) @decoded['altimeter_hpa'] = sprintf("%d", ($1.to_f * 0.33863881578947).to_i) @decoded['altimeter_atm'] = sprintf("%.3f", $1.to_f * 3.3421052631579e-4) elsif(part =~ /Q([0-9]{4})/) # Altimeter # This is strange, the specification doesnt say anything about # the Qxxxx-form, but it's in the METARs. # The pressure measured in hPa @decoded['altimeter_hpa'] = sprintf("%d", $1.to_i) # The pressure measured in mmHg, inHg and atm @decoded['altimeter_mmhg'] = sprintf("%.1f", $1.to_f * 0.7500616827) @decoded['altimeter_inhg'] = sprintf("%.2f", $1.to_f * 0.0295299875) @decoded['altimeter_atm'] = sprintf("%.3f", $1.to_f * 9.869232667e-4) elsif (part =~ /^T([0-9]{4})([0-9]{4})/) # Temperature/Dew Point Group, coded to tenth of degree. # The temperature and dew-point measured in Celsius. store_temp($1,'temp_c','temp_f') store_temp($2,'dew_c','dew_f') elsif (part =~ /^1([0-9]{4}$)/) # 6 hour maximum temperature Celsius, coded to tenth of degree store_temp($1,'temp_max6h_c','temp_max6h_f') elsif (part =~ /^2([0-9]{4}$)/) # 6 hour minimum temperature Celsius, coded to tenth of degree store_temp($1,'temp_min6h_c','temp_min6h_f') elsif (part =~ /^4([0-9]{4})([0-9]{4})$/) # 24 hour maximum and minimum temperature Celsius, coded to # tenth of degree store_temp($1,'temp_max24h_c','temp_max24h_f') store_temp($2,'temp_min24h_c','temp_min24h_f') elsif (part =~ /^P([0-9]{4})/) # Precipitation during last hour in hundredths of an inch # (store as inches) @decoded['precip_in'] = sprintf("%.2f", $1.to_f/100) @decoded['precip_mm'] = sprintf("%.2f", $1.to_f * 0.254) elsif (part =~ /^6([0-9]{4})/) # Precipitation during last 3 or 6 hours in hundredths of an # inch (store as inches) @decoded['precip_6h_in'] = sprintf("%.2f", $1.to_f/100) @decoded['precip_6h_mm'] = sprintf("%.2f", $1.to_f * 0.254) elsif (part =~ /^7([0-9]{4})/) # Precipitation during last 24 hours in hundredths of an inch # (store as inches) @decoded['precip_24h_in'] = sprintf("%.2f", $1.to_f/100) @decoded['precip_24h_mm'] = sprintf("%.2f", $1.to_f * 0.254) elsif(part =~ /^4\/([0-9]{3})/) # Snow depth in inches @decoded['snow_in'] = sprintf("%.2f", $1); @decoded['snow_mm'] = sprintf("%.2f", $1.to_f * 25.4) else # If we couldn't match the group, we assume that it was a # remark. @decoded['remarks'] = '' unless @decoded.has_key?("remarks") @decoded['remarks'] += ' ' + part; end } # Relative humidity # p @decoded['dew_c'] # 11.0 # p @decoded['temp_c'] # 21.0 # => 56.1 @decoded['rel_humidity'] = sprintf("%.1f",100 * (6.11 * (10.0**(7.5 * @decoded['dew_c'].to_f / (237.7 + @decoded['dew_c'].to_f)))) / (6.11 * (10.0 ** (7.5 * @decoded['temp_c'].to_f / (237.7 + @decoded['temp_c'].to_f))))) if @decoded.has_key?('dew_c') end def store_temp(temp,temp_cname,temp_fname) # Given a numerical temperature temp in Celsius, coded to tenth of # degree, store in @decoded[temp_cname], convert to Fahrenheit # and store in @decoded[temp_fname] # Note: temp is converted to negative if temp > 100.0 (See # Federal Meteorological Handbook for groups T, 1, 2 and 4) # Temperature measured in Celsius, coded to tenth of degree temp = temp.to_f/10 if (temp >100.0) # first digit = 1 means minus temperature temp = -(temp - 100.0) end @decoded[temp_cname] = sprintf("%.1f", temp) # The temperature in Fahrenheit. @decoded[temp_fname] = sprintf("%.1f", (temp * 9 / 5) + 32) end def pretty_print_precip(precip_mm, precip_in) # Returns amount if $precip_mm > 0, otherwise "trace" (see Federal # Meteorological Handbook No. 1 for code groups P, 6 and 7) used in # several places, so standardized in one function. if (precip_mm.to_i > 0) amount = sprintf(@strings['mm_inches'], precip_mm, precip_in) else amount = @strings['a_trace'] end return sprintf(@strings['precip_there_was'], amount) end def pretty_print if @nodata return "The weather stored for #{@decoded['station']} consists of the string 'NIL' :(" end ["temp_c", "altimeter_hpa"].each {|key| if !@decoded.has_key?(key) return "The weather stored for #{@decoded['station']} could not be parsed (#{@input})" end } mins_old = ((Time.now - @date.to_i).to_f/60).round if (mins_old <= 60) weather_age = mins_old.to_s + " minutes ago," elsif (mins_old <= 60 * 25) weather_age = (mins_old / 60).to_s + " hours, " weather_age += (mins_old % 60).to_s + " minutes ago," else # return "The weather stored for #{@decoded['station']} is hideously out of date :( (Last update #{@date})" weather_age = "The weather stored for #{@decoded['station']} is hideously out of date :( here it is anyway:" end if(@decoded.has_key?("cloud_layer1_altitude_ft")) sky_str = sprintf(@strings['sky_str_format1'], @decoded["cloud_layer1_condition"], @decoded["cloud_layer1_altitude_m"], @decoded["cloud_layer1_altitude_ft"]) else sky_str = @strings['sky_str_clear'] end if(@decoded.has_key?("cloud_layer2_altitude_ft")) if(@decoded.has_key?("cloud_layer3_altitude_ft")) sky_str += sprintf(@strings['sky_str_format2'], @decoded["cloud_layer2_condition"], @decoded["cloud_layer2_altitude_m"], @decoded["cloud_layer2_altitude_ft"], @decoded["cloud_layer3_condition"], @decoded["cloud_layer3_altitude_m"], @decoded["cloud_layer3_altitude_ft"]) else sky_str += sprintf(@strings['sky_str_format3'], @decoded["cloud_layer2_condition"], @decoded["cloud_layer2_altitude_m"], @decoded["cloud_layer2_altitude_ft"]) end end sky_str += "." if(@decoded.has_key?("visibility_miles")) visibility = sprintf(@strings['visibility_format'], @decoded["visibility_km"], @decoded["visibility_miles"]) else visibility = "" end if (@decoded.has_key?("wind_meters_per_second") && @decoded["wind_meters_per_second"].to_i > 0) wind_str = sprintf(@strings['wind_str_format1'], @decoded["wind_meters_per_second"], @decoded["wind_miles_per_hour"]) if (@decoded.has_key?("wind_gust_meters_per_second") && @decoded["wind_gust_meters_per_second"].to_i > 0) wind_str += sprintf(@strings['wind_str_format2'], @decoded["wind_gust_meters_per_second"], @decoded["wind_gust_miles_per_hour"]) end wind_str += sprintf(@strings['wind_str_format3'], @decoded["wind_dir_text"]) else wind_str = @strings['wind_str_calm'] end prec_str = "" if (@decoded.has_key?("precip_in")) prec_str += pretty_print_precip(@decoded["precip_mm"], @decoded["precip_in"]) + @strings['precip_last_hour'] end if (@decoded.has_key?("precip_6h_in")) prec_str += pretty_print_precip(@decoded["precip_6h_mm"], @decoded["precip_6h_in"]) + @strings['precip_last_6_hours'] end if (@decoded.has_key?("precip_24h_in")) prec_str += pretty_print_precip(@decoded["precip_24h_mm"], @decoded["precip_24h_in"]) + @strings['precip_last_24_hours'] end if (@decoded.has_key?("snow_in")) prec_str += sprintf(@strings['precip_snow'], @decoded["snow_mm"], @decoded["snow_in"]) end temp_str = "" if (@decoded.has_key?("temp_max6h_c") && @decoded.has_key?("temp_min6h_c")) temp_str += sprintf(@strings['temp_min_max_6_hours'], @decoded["temp_max6h_c"], @decoded["temp_min6h_c"], @decoded["temp_max6h_f"], @decoded["temp_min6h_f"]) else if (@decoded.has_key?("temp_max6h_c")) temp_str += sprintf(@strings['temp_max_6_hours'], @decoded["temp_max6h_c"], @decoded["temp_max6h_f"]) end if (@decoded.has_key?("temp_min6h_c")) temp_str += sprintf(@strings['temp_max_6_hours'], @decoded["temp_min6h_c"], @decoded["temp_min6h_f"]) end end if (@decoded.has_key?("temp_max24h_c")) temp_str += sprintf(@strings['temp_min_max_24_hours'], @decoded["temp_max24h_c"], @decoded["temp_min24h_c"], @decoded["temp_max24h_f"], @decoded["temp_min24h_f"]) end if (@decoded.has_key?("weather")) weather_str = sprintf(@strings['current_weather'], @decoded["weather"]) else weather_str = '' end return sprintf(@strings['pretty_print_metar'], weather_age, @date, wind_str, @decoded["station"], @decoded["temp_c"], @decoded["temp_f"], @decoded["altimeter_hpa"], @decoded["altimeter_inhg"], @decoded["rel_humidity"], sky_str, visibility, weather_str, prec_str, temp_str).strip end def to_s @input end end def Utils.get_metar(station) station.upcase! result = Utils.http_get("http://weather.noaa.gov/pub/data/observations/metar/stations/#{station}.TXT") return nil unless result return Metar.new(result) end end end