// noinspection JSUnresolvedReference /** * Field Google Map */ /* global jQuery, document, redux_change, redux, google */ (function ( $ ) { 'use strict'; redux.field_objects = redux.field_objects || {}; redux.field_objects.google_maps = redux.field_objects.google_maps || {}; /* LIBRARY INIT */ redux.field_objects.google_maps.init = function ( selector ) { if ( ! selector ) { selector = $( document ).find( '.redux-group-tab:visible' ).find( '.redux-container-google_maps:visible' ); } $( selector ).each( function ( i ) { let delayRender; const el = $( this ); let parent = el; if ( ! el.hasClass( 'redux-field-container' ) ) { parent = el.parents( '.redux-field-container:first' ); } if ( parent.is( ':hidden' ) ) { return; } if ( parent.hasClass( 'redux-field-init' ) ) { parent.removeClass( 'redux-field-init' ); } else { return; } // Check for delay render, which is useful for calling a map // render after JavaScript load. delayRender = Boolean( el.find( '.redux_framework_google_maps' ).data( 'delay-render' ) ); // API Key button. redux.field_objects.google_maps.clickHandler( el ); // Init our maps. redux.field_objects.google_maps.initMap( el, i, delayRender ); } ); }; /* INIT MAP FUNCTION */ redux.field_objects.google_maps.initMap = async function ( el, idx, delayRender ) { let delayed; let scrollWheel; let streetView; let mapType; let address; let defLat; let defLong; let defaultZoom; let mapOptions; let geocoder; let g_autoComplete; let g_LatLng; let g_map; let noLatLng = false; // Pull the map class. const mapClass = el.find( '.redux_framework_google_maps' ); const containerID = mapClass.attr( 'id' ); const autocomplete = containerID + '_autocomplete'; const canvas = containerID + '_map_canvas'; const canvasId = $( '#' + canvas ); const latitude = containerID + '_latitude'; const longitude = containerID + '_longitude'; // Add map index to data attr. // Why, say we want to use delay_render, // and want to init the map later on. // You'd need the index number in the // event of multiple map instances. // This allows one to retrieve it // later. $( mapClass ).attr( 'data-idx', idx ); if ( true === delayRender ) { return; } // Map has been rendered, no need to process again. if ( $( '#' + containerID ).hasClass( 'rendered' ) ) { return; } // If a map is set to delay render and has been initiated // from another scrip, add the 'render' class so rendering // does not occur. // It messes things up. delayed = Boolean( mapClass.data( 'delay-render' ) ); if ( true === delayed ) { mapClass.addClass( 'rendered' ); } // Create the autocomplete object, restricting the search // to geographical location types. g_autoComplete = await google.maps.importLibrary( 'places' ); g_autoComplete = new google.maps.places.Autocomplete( document.getElementById( autocomplete ), {types: ['geocode']} ); // Data bindings. scrollWheel = Boolean( mapClass.data( 'scroll-wheel' ) ); streetView = Boolean( mapClass.data( 'street-view' ) ); mapType = Boolean( mapClass.data( 'map-type' ) ); address = mapClass.data( 'address' ); address = decodeURIComponent( address ); address = address.trim(); // Set default Lat/lng. defLat = canvasId.data( 'default-lat' ); defLong = canvasId.data( 'default-long' ); defaultZoom = canvasId.data( 'default-zoom' ); // Eval whether to set maps based on lat/lng or address. if ( '' !== address ) { if ( '' === defLat || '' === defLong ) { noLatLng = true; } } else { noLatLng = false; } // Can't have empty values, or the map API will complain. // Set default for the middle of the United States. defLat = defLat ? defLat : 39.11676722061108; defLong = defLong ? defLong : -100.47761000000003; if ( noLatLng ) { // If displaying a map based on an address. geocoder = new google.maps.Geocoder(); // Set up Geocode and pass address. geocoder.geocode( {'address': address}, function ( results, status ) { let latitude; let longitude; // Function results. if ( status === google.maps.GeocoderStatus.OK ) { // A good address was passed. g_LatLng = results[0].geometry.location; // Set map options. mapOptions = { center: g_LatLng, zoom: defaultZoom, streetViewControl: streetView, mapTypeControl: mapType, scrollwheel: scrollWheel, mapTypeControlOptions: { style: google.maps.MapTypeControlStyle.HORIZONTAL_BAR, position: google.maps.ControlPosition.LEFT_BOTTOM }, mapId: 'REDUX_GOOGLE_MAPS', }; // Create map. g_map = new google.maps.Map( document.getElementById( canvas ), mapOptions ); // Get and set lat/long data. latitude = el.find( '#' + containerID + '_latitude' ); latitude.val( results[0].geometry.location.lat() ); longitude = el.find( '#' + containerID + '_longitude' ); longitude.val( results[0].geometry.location.lng() ); redux.field_objects.google_maps.renderControls( el, latitude, longitude, g_autoComplete, g_map, autocomplete, mapClass, g_LatLng, containerID ); } else { // No data found, alert the user. alert( 'Geocode was not successful for the following reason: ' + status ); } } ); } else { // If displaying map based on an lat/lng. g_LatLng = new google.maps.LatLng( defLat, defLong ); // Set map options. mapOptions = { center: g_LatLng, zoom: defaultZoom, // Start off far unless an item is selected, set by php. streetViewControl: streetView, mapTypeControl: mapType, scrollwheel: scrollWheel, mapTypeControlOptions: { style: google.maps.MapTypeControlStyle.HORIZONTAL_BAR, position: google.maps.ControlPosition.LEFT_BOTTOM }, mapId: 'REDUX_GOOGLE_MAPS', }; // Create the map. g_map = new google.maps.Map( document.getElementById( canvas ), mapOptions ); redux.field_objects.google_maps.renderControls( el, latitude, longitude, g_autoComplete, g_map, autocomplete, mapClass, g_LatLng, containerID ); } }; redux.field_objects.google_maps.renderControls = function ( el, latitude, longitude, g_autoComplete, g_map, autocomplete, mapClass, g_LatLng, containerID ) { let markerTooltip; let infoWindow; let g_marker; let geoAlert = mapClass.data( 'geo-alert' ); // Get HTML. const input = document.getElementById( autocomplete ); // Set objects into the map. g_map.controls[google.maps.ControlPosition.TOP_LEFT].push( input ); // Bind objects to the map. g_autoComplete = new google.maps.places.Autocomplete( input ); g_autoComplete.bindTo( 'bounds', g_map ); // Get the marker tooltip data. markerTooltip = mapClass.data( 'marker-tooltip' ); markerTooltip = decodeURIComponent( markerTooltip ); // Create infoWindow. infoWindow = new google.maps.InfoWindow(); // Create marker. g_marker = new google.maps.Marker( { position: g_LatLng, map: g_map, anchorPoint: new google.maps.Point( 0, - 29 ), draggable: true, title: markerTooltip, animation: google.maps.Animation.DROP } ); geoAlert = decodeURIComponent( geoAlert ); // Place change. google.maps.event.addListener( g_autoComplete, 'place_changed', function () { let place; let address; let markerTooltip; infoWindow.close(); // Get place data. place = g_autoComplete.getPlace(); // Display alert if something went wrong. if ( ! place.geometry ) { window.alert( geoAlert ); return; } console.log( place.geometry.viewport ); // If the place has a geometry, then present it on a map. if ( place.geometry.viewport ) { g_map.fitBounds( place.geometry.viewport ); } else { g_map.setCenter( place.geometry.location ); g_map.setZoom( 17 ); // Why 17? Because it looks good. } markerTooltip = mapClass.data( 'marker-tooltip' ); markerTooltip = decodeURIComponent( markerTooltip ); // Set the marker icon. g_marker = new google.maps.Marker( { position: g_LatLng, map: g_map, anchorPoint: new google.maps.Point( 0, - 29 ), title: markerTooltip, clickable: true, draggable: true, animation: google.maps.Animation.DROP } ); // Set marker position and display. g_marker.setPosition( place.geometry.location ); g_marker.setVisible( true ); // Form array of address components. address = ''; if ( place.address_components ) { address = [( place.address_components[0] && place.address_components[0].short_name || '' ), ( place.address_components[1] && place.address_components[1].short_name || '' ), ( place.address_components[2] && place.address_components[2].short_name || '' )].join( ' ' ); } // Set the default marker info window with address data. infoWindow.setContent( '
' + place.name + '
' + address ); infoWindow.open( g_map, g_marker ); // Run Geolocation. redux.field_objects.google_maps.geoLocate( g_autoComplete ); // Fill in address inputs. redux.field_objects.google_maps.fillInAddress( el, latitude, longitude, g_autoComplete ); } ); // Marker drag. google.maps.event.addListener( g_marker, 'drag', function ( event ) { document.getElementById( latitude ).value = event.latLng.lat(); document.getElementById( longitude ).value = event.latLng.lng(); } ); // End marker drag. google.maps.event.addListener( g_marker, 'dragend', function () { redux_change( el.find( '.redux_framework_google_maps' ) ); } ); // Zoom Changed. g_map.addListener( 'zoom_changed', function () { el.find( '.google_m_zoom_input' ).val( g_map.getZoom() ); } ); // Marker Info Window. infoWindow = new google.maps.InfoWindow(); google.maps.event.addListener( g_marker, 'click', function () { const marker_info = containerID + '_marker_info'; const infoValue = document.getElementById( marker_info ).value; if ( '' !== infoValue ) { infoWindow.setContent( infoValue ); infoWindow.open( g_map, g_marker ); } } ); }; /* FILL IN ADDRESS FUNCTION */ redux.field_objects.google_maps.fillInAddress = function ( el, latitude, longitude, g_autoComplete ) { // Set variables. const containerID = el.find( '.redux_framework_google_maps' ).attr( 'id' ); // What if someone only wants city, or state, ect... // gotta do it this way to check for the address! // Need to check each of the returned components to see what is returned. const componentForm = { street_number: 'short_name', route: 'long_name', locality: 'long_name', administrative_area_level_1: 'short_name', country: 'long_name', postal_code: 'short_name' }; // Get the place details from the autocomplete object. const place = g_autoComplete.getPlace(); let component; let i; let addressType; let _d_addressType; let val; let len; document.getElementById( latitude ).value = place.geometry.location.lat(); document.getElementById( longitude ).value = place.geometry.location.lng(); for ( component in componentForm ) { if ( componentForm.hasOwnProperty( component ) ) { // Push in the dynamic form element ID again. component = containerID + '_' + component; // Assign to proper place. document.getElementById( component ).value = ''; document.getElementById( component ).disabled = false; } } // Get each component of the address from the place details // and fill the corresponding field on the form. len = place.address_components.length; for ( i = 0; i < len; i += 1 ) { addressType = place.address_components[i].types[0]; if ( componentForm[addressType] ) { // Push in the dynamic form element ID again. _d_addressType = containerID + '_' + addressType; // Get the original. val = place.address_components[i][componentForm[addressType]]; // Assign to proper place. document.getElementById( _d_addressType ).value = val; } } }; redux.field_objects.google_maps.geoLocate = function ( g_autoComplete ) { if ( navigator.geolocation ) { navigator.geolocation.getCurrentPosition( function ( position ) { const geolocation = new google.maps.LatLng( position.coords.latitude, position.coords.longitude ); const circle = new google.maps.Circle( { center: geolocation, radius: position.coords.accuracy } ); g_autoComplete.setBounds( circle.getBounds() ); } ); } }; /* API BUTTON CLICK HANDLER */ redux.field_objects.google_maps.clickHandler = function ( el ) { // Find the API Key button and react on click. el.find( '.google_m_api_key_button' ).on( 'click', function () { // Find message wrapper. const wrapper = el.find( '.google_m_api_key_wrapper' ); if ( wrapper.is( ':visible' ) ) { // If the wrapper is visible, close it. wrapper.slideUp( 'fast', function () { el.find( '#google_m_api_key_input' ).trigger( 'focus' ); } ); } else { // If the wrapper is visible, open it. wrapper.slideDown( 'medium', function () { el.find( '#google_m_api_key_input' ).trigger( 'focus' ); } ); } } ); el.find( '.google_m_autocomplete' ).on( 'keypress', function ( e ) { if ( 13 === e.keyCode ) { e.preventDefault(); } } ); // Auto select autocomplete contents, // since Google doesn't do this inherently. el.find( '.google_m_autocomplete' ).on( 'click', function ( e ) { $( this ).trigger( 'focus' ); $( this ).trigger( 'select' ); e.preventDefault(); } ); }; } )( jQuery );
Warning: Cannot modify header information - headers already sent by (output started at /home/u674585327/domains/orchidbuildcon.in/public_html/wp-content/plugins/wps-hide-login/wps-hide-login.php:1) in /home/u674585327/domains/orchidbuildcon.in/public_html/wp-includes/feed-rss2-comments.php on line 8
Comments on: Tornei da casinò sotto la lente: la matematica che demistifica i miti del gioco – un’analisi approfondita delle dinamiche competitive dei tornei di poker, blackjack e roulette nei casinò tradizionali e online, con focus su probabilità teoriche, strutture di premio top‑heavy, l’interazione tra fortuna e abilità, le regole nascoste che influenzano il risultato finale, le strategie basate sul valore atteso (EV) e sul rischio di rovina, la gestione del bankroll nei formati a eliminazione singola e re‑entry, l’impatto psicologico delle leaderboard e delle statistiche visibili ai tavoli, il ruolo delle tecnologie emergenti come l’intelligenza artificiale e le simulazioni Monte‑Carlo nella preparazione dei giocatori professionisti, ed una panoramica dei casi studio più emblematici come il World Series of Poker Main Event; tutto questo accompagnato da consigli pratici su bonus di benvenuto, multipla e sicurezza dei pagamenti e dei prelievi nelle piattaforme di gioco certificato. Si esaminano inoltre i parametri chiave quali RTP medio del torneo (solitamente intorno al 96 percento), la volatilità alta che premia i giocatori con decisioni aggressive ma calcolate, le condizioni di wagering richieste per sbloccare i bonus di benvenuto offerti dalle piattaforme leader come SNAI o altri bookmaker non AAMS che operano anche nel segmento tournament‑play; si confrontano i tempi medi di pagamento e prelievo tra casinò fisici e operatori online certificati da autorità europee garantendo trasparenza e protezione dei fondi dei clienti; infine si analizzano le politiche anti‑fraud e i sistemi di crittografia SSL che assicurano che ogni transazione sia sicura. L’articolo conclude con una prospettiva sul futuro dell’analisi statistica nei tornei grazie all’integrazione di algoritmi predittivi basati su machine learning che consentono ai giocatori di simulare migliaia di scenari in tempo reale prima dell’iscrizione al torneo. Inoltre vengono illustrati esempi concreti di payout strutturati con jackpot progressivi fino al 500 000 euro per i migliori piazzamenti. https://orchidbuildcon.in/tornei-da-casino-sotto-la-lente-la-matematica-che-demistifica-i-miti-del-gioco-un-analisi-approfondita-delle-dinamiche-competitive-dei-tornei-di-poker-blackjack-e-roulette-nei-casino-tradizionali-e-3/ Fri, 01 May 2026 15:23:52 +0000 hourly 1 https://wordpress.org/?v=6.9.4