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109 lines
3.5 KiB
Elixir
109 lines
3.5 KiB
Elixir
defmodule PhilomenaQuery.IpMask do
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@moduledoc """
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Postgres IP masks.
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"""
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@doc """
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Parse a netmask from a string parameter, producing an `m:Postgrex.INET` type suitable for use in
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a containment (<<=, <<, >>, >>=) query. Ignores invalid strings and passes the IP through on
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error. [Postgres documentation](https://www.postgresql.org/docs/current/functions-net.html)
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has more information on `inet` operations.
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> #### Info {: .info}
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>
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> Netmasks lower than /8 are clamped to a minimum of /8. Such low masks are unlikely to be
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> useful and this avoids producing very expensive masks to evaluate.
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## Examples
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iex> parse_mask(%Postgrex.INET{address: {192, 168, 1, 1}, netmask: 32}, %{"mask" => "12"})
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%Postgrex.INET{address: {192, 160, 0, 0}, netmask: 12}
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iex> parse_mask(%Postgrex.INET{address: {192, 168, 1, 1}, netmask: 32}, %{"mask" => "4"})
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%Postgrex.INET{address: {192, 0, 0, 0}, netmask: 8}
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iex> parse_mask(%Postgrex.INET{address: {192, 168, 1, 1}, netmask: 32}, %{"mask" => "64"})
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%Postgrex.INET{address: {192, 168, 1, 1}, netmask: 32}
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iex> parse_mask(%Postgrex.INET{address: {192, 168, 1, 1}, netmask: 32}, %{"mask" => "e"})
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%Postgrex.INET{address: {192, 168, 1, 1}, netmask: 32}
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iex> parse_mask(%Postgrex.INET{address: {192, 168, 1, 1}, netmask: 32}, %{})
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%Postgrex.INET{address: {192, 168, 1, 1}, netmask: 32}
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iex> parse_mask(%Postgrex.INET{
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...> address: {0x2001, 0xab0, 0x33a8, 0xd6e2, 0x10e9, 0xac1b, 0x9b0f, 0x67bc},
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...> netmask: 128
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...> }, %{"mask" => "64"})
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%Postgrex.INET{address: {8193, 2736, 13224, 55010, 0, 0, 0, 0}, netmask: 64}
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"""
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@spec parse_mask(Postgrex.INET.t(), map()) :: Postgrex.INET.t()
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def parse_mask(ip, params)
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def parse_mask(ip, %{"mask" => mask}) when is_binary(mask) do
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case Integer.parse(mask) do
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{mask, _rest} ->
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mask = clamp_mask(ip.address, mask)
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address = apply_mask(ip.address, mask)
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%Postgrex.INET{address: address, netmask: mask}
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_ ->
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ip
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end
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end
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def parse_mask(ip, _params), do: ip
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defp clamp(n, min, _max) when n < min, do: min
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defp clamp(n, _min, max) when n > max, do: max
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defp clamp(n, _min, _max), do: n
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defp clamp_mask(ip, mask) do
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# Clamp mask length:
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# - low end 8 (too taxing to evaluate)
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# - high end address_bits (limit of address)
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case tuple_size(ip) do
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4 ->
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clamp(mask, 8, 32)
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8 ->
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clamp(mask, 8, 128)
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end
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end
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defp unit_length(ip) when tuple_size(ip) == 4, do: 8
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defp unit_length(ip) when tuple_size(ip) == 8, do: 16
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defp apply_mask(ip, mask) when is_tuple(ip) do
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# Determine whether elements are octets or hexadectets
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length = unit_length(ip)
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# 1. Convert tuple to list of octets/hexadectets
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# 2. Convert list to bitstring
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# 3. Perform truncation operation on bitstring
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# 4. Convert bitstring back to list of octets/hexadectets
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# 5. Convert list to tuple
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ip
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|> Tuple.to_list()
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|> list_to_bits(length)
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|> apply_mask(mask)
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|> bits_to_list(length)
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|> List.to_tuple()
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end
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defp apply_mask(ip, mask) when is_binary(ip) do
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# Truncate bit size of ip to mask length and zero-fill the remainder
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<<ip::bits-size(mask), 0::integer-size(bit_size(ip) - mask)>>
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end
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defp list_to_bits(list, unit_length) do
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for u <- list, into: <<>>, do: <<u::integer-size(unit_length)>>
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end
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defp bits_to_list(bits, unit_length) do
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for <<u::integer-size(unit_length) <- bits>>, do: u
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end
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end
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