visualsubnetcalc/dist/main.js
2023-05-20 23:05:19 -07:00

396 lines
No EOL
15 KiB
JavaScript

let subnetMap = {};
let subnetNotes = {};
let maxNetSize = 0;
let infoColumnCount = 5
// NORMAL mode:
// - Smallest subnet: /30
// - Two reserved addresses per subnet:
// - Network Address (network + 0)
// - Broadcast Address (last network address)
// AWS mode (future):
// - Smallest subnet: /28
// - Two reserved addresses per subnet:
// - Network Address (network + 0)
// - AWS Reserved - VPC Router
// - AWS Reserved - VPC DNS
// - AWS Reserved - Future Use
// - Broadcast Address (last network address)
let operatingMode = 'NORMAL'
let noteTimeout;
let minSubnetSize = 30
$('input#network,input#netsize').on('input', function() {
$('#input_form')[0].classList.add('was-validated');
})
$('#btn_go').on('click', function() {
reset();
})
$('#importBtn').on('click', function() {
importConfig($('#importExportArea').val())
})
$('#btn_import_export').on('click', function() {
$('#importExportArea').val(JSON.stringify(exportConfig(), null, 2))
})
function reset() {
if (operatingMode === 'AWS') {
minSubnetSize = 28
} else {
minSubnetSize = 30
}
let cidrInput = $('#network').val() + '/' + $('#netsize').val()
let rootNetwork = get_network($('#network').val(), $('#netsize').val())
let rootCidr = rootNetwork + '/' + $('#netsize').val()
if (cidrInput !== rootCidr) {
show_warning_modal('<div>Your network input is not on a network boundary for this network size. It has been automatically changed:</div><div class="font-monospace pt-2">' + $('#network').val() + ' -> ' + rootNetwork + '</div>')
}
$('#network').val(rootNetwork)
subnetMap = {}
subnetMap[rootCidr] = {}
maxNetSize = parseInt($('#netsize').val())
/*
subnetMap = {
'10.0.0.0/16': {
'10.0.0.0/17': {},
'10.0.128.0/17': {
'10.0.128.0/18': {
'10.0.128.0/19': {},
'10.0.160.0/19': {
'10.0.160.0/20': {},
'10.0.176.0/20': {
'10.0.176.0/21': {
'10.0.176.0/22': {
'10.0.176.0/23': {},
'10.0.178.0/23': {}
},
'10.0.180.0/22': {}
},
'10.0.184.0/21': {}
}
}
},
'10.0.192.0/18': {
'10.0.192.0/19': {},
'10.0.224.0/19': {
'10.0.224.0/20': {},
'10.0.240.0/20': {
'10.0.240.0/21': {},
'10.0.248.0/21': {
'10.0.248.0/22': {},
'10.0.252.0/22': {
'10.0.252.0/23': {},
'10.0.254.0/23': {
'10.0.254.0/24': {},
'10.0.255.0/24': {}
}
}
}
}
}
}
}
}
}
*/
renderTable();
}
$('#calcbody').on('click', 'td.split,td.join', function(event) {
// HTML DOM Data elements! Yay! See the `data-*` attributes of the HTML tags
mutate_subnet_map(this.dataset.mutateVerb, this.dataset.subnet, subnetMap)
renderTable();
})
$('#calcbody').on('keyup', 'td.note input', function(event) {
// HTML DOM Data elements! Yay! See the `data-*` attributes of the HTML tags
let delay = 1000;
clearTimeout(noteTimeout);
noteTimeout = setTimeout(function(element) {
console.log('CAP')
subnetNotes[element.dataset.subnet] = element.value
}, delay, this);
})
$('#calcbody').on('focusout', 'td.note input', function(event) {
// HTML DOM Data elements! Yay! See the `data-*` attributes of the HTML tags
clearTimeout(noteTimeout);
subnetNotes[this.dataset.subnet] = this.value
})
function renderTable() {
// TODO: Validation Code
$('#calcbody').empty();
let maxDepth = get_dict_max_depth(subnetMap, 0)
addRowTree(subnetMap, 0, maxDepth)
}
function addRowTree(subnetTree, depth, maxDepth) {
for (let mapKey in subnetTree) {
if (Object.keys(subnetTree[mapKey]).length > 0) {
addRowTree(subnetTree[mapKey], depth + 1, maxDepth)
} else {
let subnet_split = mapKey.split('/')
addRow(subnet_split[0], parseInt(subnet_split[1]), (infoColumnCount + maxDepth - depth))
}
}
}
function addRow(network, netSize, colspan) {
// TODO: do some checking here for smaller networks like /32, probably some edge cases to watch for.
let addressFirst = ip2int(network)
let addressLast = subnet_last_address(addressFirst, netSize)
// Will need to adjust this for AWS mode
let usableFirst = addressFirst + 1
let usableLast = addressLast - 1
let hostCount = 1 + usableLast - usableFirst
let newRow =
' <tr id="row_' + network.replace('.', '-') + '_' + netSize + '">\n' +
' <td class="row_address">' + network + '/' + netSize + '</td>\n' +
' <td class="row_range">' + int2ip(addressFirst) + ' - ' + int2ip(addressLast) + '</td>\n' +
' <td class="row_usable">' + int2ip(usableFirst) + ' - ' + int2ip(usableLast) + '</td>\n' +
' <td class="row_hosts">' + hostCount + '</td>\n' +
' <td class="note"><label><input type="text" class="form-control shadow-none p-0" data-subnet="' + network + '/' + netSize + '" value="' + (subnetNotes[network + '/' + netSize] || '') + '"></label></td>\n' +
' <td rowspan="1" colspan="' + colspan + '" class="split rotate" data-subnet="' + network + '/' + netSize + '" data-mutate-verb="split"><span>/' + netSize + '</span></td>\n'
if (netSize > maxNetSize) {
// This is wrong. Need to figure out a way to get the number of children so you can set rowspan and the number
// of ancestors so you can set colspan.
// DONE: If the subnet address (without the mask) matches a larger subnet address
// in the heirarchy that is a signal to add more join buttons to that row, since they start at the top row and
// via rowspan extend downward.
let matchingNetworkList = get_matching_network_list(network, subnetMap).slice(1)
for (const i in matchingNetworkList) {
let matchingNetwork = matchingNetworkList[i]
let networkChildrenCount = count_network_children(matchingNetwork, subnetMap, [])
newRow += ' <td rowspan="' + networkChildrenCount + '" colspan="1" class="join rotate" data-subnet="' + matchingNetwork + '" data-mutate-verb="join"><span>/' + matchingNetwork.split('/')[1] + '</span></td>\n'
}
}
newRow += ' </tr>';
$('#calcbody').append(newRow)
}
// Helper Functions
function ip2int(ip) {
return ip.split('.').reduce(function(ipInt, octet) { return (ipInt<<8) + parseInt(octet, 10)}, 0) >>> 0;
}
function int2ip (ipInt) {
return ( (ipInt>>>24) +'.' + (ipInt>>16 & 255) +'.' + (ipInt>>8 & 255) +'.' + (ipInt & 255) );
}
function subnet_last_address(subnet, netSize) {
return subnet + subnet_addresses(netSize) - 1;
}
function subnet_addresses(netSize) {
return 2**(32-netSize);
}
function get_dict_max_depth(dict, curDepth) {
let maxDepth = curDepth
for (let mapKey in dict) {
let newDepth = get_dict_max_depth(dict[mapKey], curDepth + 1)
if (newDepth > maxDepth) { maxDepth = newDepth }
}
return maxDepth
}
function get_join_children(subnetTree, childCount) {
for (let mapKey in subnetTree) {
if (Object.keys(subnetTree[mapKey]).length > 0) {
childCount += get_join_children(subnetTree[mapKey])
} else {
return childCount
}
}
}
function count_network_children(network, subnetTree, ancestryList) {
// TODO: This might be able to be optimized. Ultimately it needs to count the number of keys underneath
// the current key are unsplit networks (IE rows in the table, IE keys with a value of {}).
let childCount = 0
for (let mapKey in subnetTree) {
if (Object.keys(subnetTree[mapKey]).length > 0) {
childCount += count_network_children(network, subnetTree[mapKey], ancestryList.concat([mapKey]))
} else {
if (ancestryList.includes(network)) {
childCount += 1
}
}
}
return childCount
}
function get_network_children(network, subnetTree) {
// TODO: This might be able to be optimized. Ultimately it needs to count the number of keys underneath
// the current key are unsplit networks (IE rows in the table, IE keys with a value of {}).
let subnetList = []
for (let mapKey in subnetTree) {
if (Object.keys(subnetTree[mapKey]).length > 0) {
subnetList.push.apply(subnetList, get_network_children(network, subnetTree[mapKey]))
} else {
subnetList.push(mapKey)
}
}
return subnetList
}
function get_matching_network_list(network, subnetTree) {
let subnetList = []
for (let mapKey in subnetTree) {
if (Object.keys(subnetTree[mapKey]).length > 0) {
subnetList.push.apply(subnetList, get_matching_network_list(network, subnetTree[mapKey]))
}
if (mapKey.split('/')[0] === network) {
subnetList.push(mapKey)
}
}
return subnetList
}
function get_network(networkInput, netSize) {
let ipInt = ip2int(networkInput)
netSize = parseInt(netSize)
for (let i=31-netSize; i>=0; i--) {
ipInt &= ~ 1<<i;
}
return int2ip(ipInt);
}
function split_network(networkInput, netSize) {
let subnets = [networkInput + '/' + (netSize + 1)]
let newSubnet = ip2int(networkInput) + 2**(32-netSize-1);
subnets.push(int2ip(newSubnet) + '/' + (netSize + 1))
return subnets;
}
function mutate_subnet_map(verb, network, subnetTree) {
for (let mapKey in subnetTree) {
if (Object.keys(subnetTree[mapKey]).length > 0) {
mutate_subnet_map(verb, network, subnetTree[mapKey])
}
if (mapKey === network) {
let netSplit = mapKey.split('/')
let netSize = parseInt(netSplit[1])
if (verb === 'split') {
if (netSize < minSubnetSize) {
let new_networks = split_network(netSplit[0], netSize)
subnetTree[mapKey][new_networks[0]] = {}
subnetTree[mapKey][new_networks[1]] = {}
// Copy note to both children and delete Delete parent note
subnetNotes[new_networks[0]] = subnetNotes[mapKey]
subnetNotes[new_networks[1]] = subnetNotes[mapKey]
delete subnetNotes[mapKey]
}
} else if (verb === 'join') {
// Keep the note of the first subnet (which matches the network address) and lose the second subnet's note
// Could consider changing this to concatenate the notes into the parent, but I think this is more intuitive
// Find first (smallest) subnet note which matches the exact network address (this would be the top network in the join scope)
let smallestMatchingNetworkSize = 0
for (let subnetCidr in subnetNotes) {
if (subnetCidr.startsWith(netSplit[0])) {
if (parseInt(subnetCidr.split('/')[1]) > smallestMatchingNetworkSize) {
smallestMatchingNetworkSize = subnetCidr.split('/')[1]
}
}
}
subnetNotes[mapKey] = subnetNotes[netSplit[0] + '/' + smallestMatchingNetworkSize]
// Delete all notes of subnets under this collapsed subnet
let removeKeys = get_network_children(mapKey, subnetTree[mapKey], [])
for (let removeKey in removeKeys) {
subnetNotes[removeKey] = ''
}
// And delete the subnets themselves
subnetTree[mapKey] = {}
} else {
// How did you get here?
}
}
}
}
/*
function validate_cidr(network, netSize) {
let returnObj = {
'valid': false,
'errorNetwork': true,
'errorSize': true,
'cidr': false,
'network': false,
'netSize': false
}
returnObj['network'] = validate_network(network)
if (returnObj['network']) {
returnObj['errorNetwork'] = false;
}
if (!/^\d+$/.test(netSize)) {
returnObj['errorSize'] = true;
} else {
netSize = parseInt(netSize)
if ((netSize > 32) || (netSize < 0)) {
returnObj['errorSize'] = true;
} else {
returnObj['errorSize'] = false;
returnObj['netSize'] = netSize.toString()
}
}
if ((returnObj['errorNetwork'] === false) && (returnObj['errorSize'] === false)) {
returnObj['cidr'] = returnObj['network'] + '/' + returnObj['netSize']
returnObj['valid'] = true
}
return returnObj;
}
function validate_network(network) {
// This can probably be done with Regex but this is better.
let octets = network.split('.');
if (octets.length !== 4) { return false }
if (!/^\d+$/.test(octets[0])) { return false }
if (!/^\d+$/.test(octets[1])) { return false }
if (!/^\d+$/.test(octets[2])) { return false }
if (!/^\d+$/.test(octets[3])) { return false }
octets[0] = parseInt(octets[0])
octets[1] = parseInt(octets[1])
octets[2] = parseInt(octets[2])
octets[3] = parseInt(octets[3])
if ((octets[0] < 0) || (octets[0] > 255)) { return false }
if ((octets[1] < 0) || (octets[1] > 255)) { return false }
if ((octets[2] < 0) || (octets[2] > 255)) { return false }
if ((octets[3] < 0) || (octets[3] > 255)) { return false }
return octets.join('.')
}
*/
function show_warning_modal(message) {
var notifyModal = new bootstrap.Modal(document.getElementById("notifyModal"), {});
$('#notifyModal .modal-body').html(message)
notifyModal.show()
}
$( document ).ready(function() {
reset();
});
function exportConfig() {
return {
'config_version': '1',
'subnets': subnetMap,
'notes': subnetNotes
}
}
function importConfig(text) {
// TODO: Probably need error checking here
text = JSON.parse(text)
if (text['config_version'] === '1') {
subnetMap = text['subnets'];
subnetNotes = text['notes'];
renderTable()
}
}