moby/network_test.go
Victor Vieux 0de3f1ca9a add tests
2013-06-10 14:14:54 +00:00

316 lines
7.7 KiB
Go
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

package docker
import (
"net"
"os"
"testing"
)
func TestIptables(t *testing.T) {
if err := iptables("-L"); err != nil {
t.Fatal(err)
}
path := os.Getenv("PATH")
os.Setenv("PATH", "")
defer os.Setenv("PATH", path)
if err := iptables("-L"); err == nil {
t.Fatal("Not finding iptables in the PATH should cause an error")
}
}
func TestParseNat(t *testing.T) {
if nat, err := parseNat("4500"); err == nil {
if nat.Frontend != 0 || nat.Backend != 4500 {
t.Errorf("-p 4500 should produce 0->4500, got %d->%d", nat.Frontend, nat.Backend)
}
} else {
t.Fatal(err)
}
if nat, err := parseNat(":4501"); err == nil {
if nat.Frontend != 4501 || nat.Backend != 4501 {
t.Errorf("-p :4501 should produce 4501->4501, got %d->%d", nat.Frontend, nat.Backend)
}
} else {
t.Fatal(err)
}
if nat, err := parseNat("4502:4503"); err == nil {
if nat.Frontend != 4502 || nat.Backend != 4503 {
t.Errorf("-p 4502:4503 should produce 4502->4503, got %d->%d", nat.Frontend, nat.Backend)
}
} else {
t.Fatal(err)
}
}
func TestPortAllocation(t *testing.T) {
allocator, err := newPortAllocator()
if err != nil {
t.Fatal(err)
}
if port, err := allocator.Acquire(80); err != nil {
t.Fatal(err)
} else if port != 80 {
t.Fatalf("Acquire(80) should return 80, not %d", port)
}
port, err := allocator.Acquire(0)
if err != nil {
t.Fatal(err)
}
if port <= 0 {
t.Fatalf("Acquire(0) should return a non-zero port")
}
if _, err := allocator.Acquire(port); err == nil {
t.Fatalf("Acquiring a port already in use should return an error")
}
if newPort, err := allocator.Acquire(0); err != nil {
t.Fatal(err)
} else if newPort == port {
t.Fatalf("Acquire(0) allocated the same port twice: %d", port)
}
if _, err := allocator.Acquire(80); err == nil {
t.Fatalf("Acquiring a port already in use should return an error")
}
if err := allocator.Release(80); err != nil {
t.Fatal(err)
}
if _, err := allocator.Acquire(80); err != nil {
t.Fatal(err)
}
}
func TestNetworkRange(t *testing.T) {
// Simple class C test
_, network, _ := net.ParseCIDR("192.168.0.1/24")
first, last := networkRange(network)
if !first.Equal(net.ParseIP("192.168.0.0")) {
t.Error(first.String())
}
if !last.Equal(net.ParseIP("192.168.0.255")) {
t.Error(last.String())
}
if size := networkSize(network.Mask); size != 256 {
t.Error(size)
}
// Class A test
_, network, _ = net.ParseCIDR("10.0.0.1/8")
first, last = networkRange(network)
if !first.Equal(net.ParseIP("10.0.0.0")) {
t.Error(first.String())
}
if !last.Equal(net.ParseIP("10.255.255.255")) {
t.Error(last.String())
}
if size := networkSize(network.Mask); size != 16777216 {
t.Error(size)
}
// Class A, random IP address
_, network, _ = net.ParseCIDR("10.1.2.3/8")
first, last = networkRange(network)
if !first.Equal(net.ParseIP("10.0.0.0")) {
t.Error(first.String())
}
if !last.Equal(net.ParseIP("10.255.255.255")) {
t.Error(last.String())
}
// 32bit mask
_, network, _ = net.ParseCIDR("10.1.2.3/32")
first, last = networkRange(network)
if !first.Equal(net.ParseIP("10.1.2.3")) {
t.Error(first.String())
}
if !last.Equal(net.ParseIP("10.1.2.3")) {
t.Error(last.String())
}
if size := networkSize(network.Mask); size != 1 {
t.Error(size)
}
// 31bit mask
_, network, _ = net.ParseCIDR("10.1.2.3/31")
first, last = networkRange(network)
if !first.Equal(net.ParseIP("10.1.2.2")) {
t.Error(first.String())
}
if !last.Equal(net.ParseIP("10.1.2.3")) {
t.Error(last.String())
}
if size := networkSize(network.Mask); size != 2 {
t.Error(size)
}
// 26bit mask
_, network, _ = net.ParseCIDR("10.1.2.3/26")
first, last = networkRange(network)
if !first.Equal(net.ParseIP("10.1.2.0")) {
t.Error(first.String())
}
if !last.Equal(net.ParseIP("10.1.2.63")) {
t.Error(last.String())
}
if size := networkSize(network.Mask); size != 64 {
t.Error(size)
}
}
func TestConversion(t *testing.T) {
ip := net.ParseIP("127.0.0.1")
i := ipToInt(ip)
if i == 0 {
t.Fatal("converted to zero")
}
conv := intToIP(i)
if !ip.Equal(conv) {
t.Error(conv.String())
}
}
func TestIPAllocator(t *testing.T) {
expectedIPs := []net.IP{
0: net.IPv4(127, 0, 0, 2),
1: net.IPv4(127, 0, 0, 3),
2: net.IPv4(127, 0, 0, 4),
3: net.IPv4(127, 0, 0, 5),
4: net.IPv4(127, 0, 0, 6),
}
gwIP, n, _ := net.ParseCIDR("127.0.0.1/29")
alloc := newIPAllocator(&net.IPNet{IP: gwIP, Mask: n.Mask})
// Pool after initialisation (f = free, u = used)
// 2(f) - 3(f) - 4(f) - 5(f) - 6(f)
// ↑
// Check that we get 5 IPs, from 127.0.0.2127.0.0.6, in that
// order.
for i := 0; i < 5; i++ {
ip, err := alloc.Acquire()
if err != nil {
t.Fatal(err)
}
assertIPEquals(t, expectedIPs[i], ip)
}
// Before loop begin
// 2(f) - 3(f) - 4(f) - 5(f) - 6(f)
// ↑
// After i = 0
// 2(u) - 3(f) - 4(f) - 5(f) - 6(f)
// ↑
// After i = 1
// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
// ↑
// After i = 2
// 2(u) - 3(u) - 4(u) - 5(f) - 6(f)
// ↑
// After i = 3
// 2(u) - 3(u) - 4(u) - 5(u) - 6(f)
// ↑
// After i = 4
// 2(u) - 3(u) - 4(u) - 5(u) - 6(u)
// ↑
// Check that there are no more IPs
_, err := alloc.Acquire()
if err == nil {
t.Fatal("There shouldn't be any IP addresses at this point")
}
// Release some IPs in non-sequential order
alloc.Release(expectedIPs[3])
// 2(u) - 3(u) - 4(u) - 5(f) - 6(u)
// ↑
alloc.Release(expectedIPs[2])
// 2(u) - 3(u) - 4(f) - 5(f) - 6(u)
// ↑
alloc.Release(expectedIPs[4])
// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
// ↑
// Make sure that IPs are reused in sequential order, starting
// with the first released IP
newIPs := make([]net.IP, 3)
for i := 0; i < 3; i++ {
ip, err := alloc.Acquire()
if err != nil {
t.Fatal(err)
}
newIPs[i] = ip
}
// Before loop begin
// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
// ↑
// After i = 0
// 2(u) - 3(u) - 4(f) - 5(u) - 6(f)
// ↑
// After i = 1
// 2(u) - 3(u) - 4(f) - 5(u) - 6(u)
// ↑
// After i = 2
// 2(u) - 3(u) - 4(u) - 5(u) - 6(u)
// ↑
assertIPEquals(t, expectedIPs[3], newIPs[0])
assertIPEquals(t, expectedIPs[4], newIPs[1])
assertIPEquals(t, expectedIPs[2], newIPs[2])
_, err = alloc.Acquire()
if err == nil {
t.Fatal("There shouldn't be any IP addresses at this point")
}
}
func assertIPEquals(t *testing.T, ip1, ip2 net.IP) {
if !ip1.Equal(ip2) {
t.Fatalf("Expected IP %s, got %s", ip1, ip2)
}
}
func AssertOverlap(CIDRx string, CIDRy string, t *testing.T) {
_, netX, _ := net.ParseCIDR(CIDRx)
_, netY, _ := net.ParseCIDR(CIDRy)
if !networkOverlaps(netX, netY) {
t.Errorf("%v and %v should overlap", netX, netY)
}
}
func AssertNoOverlap(CIDRx string, CIDRy string, t *testing.T) {
_, netX, _ := net.ParseCIDR(CIDRx)
_, netY, _ := net.ParseCIDR(CIDRy)
if networkOverlaps(netX, netY) {
t.Errorf("%v and %v should not overlap", netX, netY)
}
}
func TestNetworkOverlaps(t *testing.T) {
//netY starts at same IP and ends within netX
AssertOverlap("172.16.0.1/24", "172.16.0.1/25", t)
//netY starts within netX and ends at same IP
AssertOverlap("172.16.0.1/24", "172.16.0.128/25", t)
//netY starts and ends within netX
AssertOverlap("172.16.0.1/24", "172.16.0.64/25", t)
//netY starts at same IP and ends outside of netX
AssertOverlap("172.16.0.1/24", "172.16.0.1/23", t)
//netY starts before and ends at same IP of netX
AssertOverlap("172.16.1.1/24", "172.16.0.1/23", t)
//netY starts before and ends outside of netX
AssertOverlap("172.16.1.1/24", "172.16.0.1/23", t)
//netY starts and ends before netX
AssertNoOverlap("172.16.1.1/25", "172.16.0.1/24", t)
//netX starts and ends before netY
AssertNoOverlap("172.16.1.1/25", "172.16.2.1/24", t)
}