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consul/agent/grpc-internal/resolver/resolver_test.go

197 lines
4.6 KiB

grpc: ensure grpc resolver correctly uses lan/wan addresses on servers (#17270) The grpc resolver implementation is fed from changes to the router.Router. Within the router there is a map of various areas storing the addressing information for servers in those areas. All map entries are of the WAN variety except a single special entry for the LAN. Addressing information in the LAN "area" are local addresses intended for use when making a client-to-server or server-to-server request. The client agent correctly updates this LAN area when receiving lan serf events, so by extension the grpc resolver works fine in that scenario. The server agent only initially populates a single entry in the LAN area (for itself) on startup, and then never mutates that area map again. For normal RPCs a different structure is used for LAN routing. Additionally when selecting a server to contact in the local datacenter it will randomly select addresses from either the LAN or WAN addressed entries in the map. Unfortunately this means that the grpc resolver stack as it exists on server agents is either broken or only accidentally functions by having servers dial each other over the WAN-accessible address. If the operator disables the serf wan port completely likely this incidental functioning would break. This PR enforces that local requests for servers (both for stale reads or leader forwarded requests) exclusively use the LAN "area" information and also fixes it so that servers keep that area up to date in the router. A test for the grpc resolver logic was added, as well as a higher level full-stack test to ensure the externally perceived bug does not return.
2 years ago
package resolver
import (
"fmt"
"net"
"net/url"
grpc: ensure grpc resolver correctly uses lan/wan addresses on servers (#17270) The grpc resolver implementation is fed from changes to the router.Router. Within the router there is a map of various areas storing the addressing information for servers in those areas. All map entries are of the WAN variety except a single special entry for the LAN. Addressing information in the LAN "area" are local addresses intended for use when making a client-to-server or server-to-server request. The client agent correctly updates this LAN area when receiving lan serf events, so by extension the grpc resolver works fine in that scenario. The server agent only initially populates a single entry in the LAN area (for itself) on startup, and then never mutates that area map again. For normal RPCs a different structure is used for LAN routing. Additionally when selecting a server to contact in the local datacenter it will randomly select addresses from either the LAN or WAN addressed entries in the map. Unfortunately this means that the grpc resolver stack as it exists on server agents is either broken or only accidentally functions by having servers dial each other over the WAN-accessible address. If the operator disables the serf wan port completely likely this incidental functioning would break. This PR enforces that local requests for servers (both for stale reads or leader forwarded requests) exclusively use the LAN "area" information and also fixes it so that servers keep that area up to date in the router. A test for the grpc resolver logic was added, as well as a higher level full-stack test to ensure the externally perceived bug does not return.
2 years ago
"strings"
"testing"
"github.com/stretchr/testify/assert"
"github.com/stretchr/testify/require"
"google.golang.org/grpc/resolver"
"google.golang.org/grpc/serviceconfig"
"github.com/hashicorp/consul/agent/metadata"
"github.com/hashicorp/consul/types"
)
func TestServerResolverBuilder(t *testing.T) {
const agentDC = "dc1"
type testcase struct {
name string
agentType string // server/client
serverType string // server/leader
requestDC string
expectLAN bool
}
run := func(t *testing.T, tc testcase) {
rs := NewServerResolverBuilder(newConfig(t, agentDC, tc.agentType))
endpoint := ""
if tc.serverType == "leader" {
endpoint = "leader.local"
} else {
endpoint = tc.serverType + "." + tc.requestDC
}
cc := &fakeClientConn{}
_, err := rs.Build(resolver.Target{
Scheme: "consul",
Authority: rs.Authority(),
URL: url.URL{Opaque: endpoint},
grpc: ensure grpc resolver correctly uses lan/wan addresses on servers (#17270) The grpc resolver implementation is fed from changes to the router.Router. Within the router there is a map of various areas storing the addressing information for servers in those areas. All map entries are of the WAN variety except a single special entry for the LAN. Addressing information in the LAN "area" are local addresses intended for use when making a client-to-server or server-to-server request. The client agent correctly updates this LAN area when receiving lan serf events, so by extension the grpc resolver works fine in that scenario. The server agent only initially populates a single entry in the LAN area (for itself) on startup, and then never mutates that area map again. For normal RPCs a different structure is used for LAN routing. Additionally when selecting a server to contact in the local datacenter it will randomly select addresses from either the LAN or WAN addressed entries in the map. Unfortunately this means that the grpc resolver stack as it exists on server agents is either broken or only accidentally functions by having servers dial each other over the WAN-accessible address. If the operator disables the serf wan port completely likely this incidental functioning would break. This PR enforces that local requests for servers (both for stale reads or leader forwarded requests) exclusively use the LAN "area" information and also fixes it so that servers keep that area up to date in the router. A test for the grpc resolver logic was added, as well as a higher level full-stack test to ensure the externally perceived bug does not return.
2 years ago
}, cc, resolver.BuildOptions{})
require.NoError(t, err)
for i := 0; i < 3; i++ {
dc := fmt.Sprintf("dc%d", i+1)
for j := 0; j < 3; j++ {
wanIP := fmt.Sprintf("127.1.%d.%d", i+1, j+10)
name := fmt.Sprintf("%s-server-%d", dc, j+1)
wanMeta := newServerMeta(name, dc, wanIP, true)
if tc.agentType == "server" {
rs.AddServer(types.AreaWAN, wanMeta)
}
if dc == agentDC {
// register LAN/WAN pairs for the same instances
lanIP := fmt.Sprintf("127.0.%d.%d", i+1, j+10)
lanMeta := newServerMeta(name, dc, lanIP, false)
rs.AddServer(types.AreaLAN, lanMeta)
if j == 0 {
rs.UpdateLeaderAddr(dc, lanIP)
}
}
}
}
if tc.serverType == "leader" {
assert.Len(t, cc.state.Addresses, 1)
} else {
assert.Len(t, cc.state.Addresses, 3)
}
for _, addr := range cc.state.Addresses {
addrPrefix := tc.requestDC + "-"
if tc.expectLAN {
addrPrefix += "127.0."
} else {
addrPrefix += "127.1."
}
assert.True(t, strings.HasPrefix(addr.Addr, addrPrefix),
"%q does not start with %q (returned WAN for LAN request)", addr.Addr, addrPrefix)
if tc.expectLAN {
assert.False(t, strings.Contains(addr.ServerName, ".dc"),
"%q ends with datacenter suffix (returned WAN for LAN request)", addr.ServerName)
} else {
assert.True(t, strings.HasSuffix(addr.ServerName, "."+tc.requestDC),
"%q does not end with %q", addr.ServerName, "."+tc.requestDC)
}
}
}
cases := []testcase{
{
name: "server requesting local servers",
agentType: "server",
serverType: "server",
requestDC: agentDC,
expectLAN: true,
},
{
name: "server requesting remote servers in dc2",
agentType: "server",
serverType: "server",
requestDC: "dc2",
expectLAN: false,
},
{
name: "server requesting remote servers in dc3",
agentType: "server",
serverType: "server",
requestDC: "dc3",
expectLAN: false,
},
// ---------------
{
name: "server requesting local leader",
agentType: "server",
serverType: "leader",
requestDC: agentDC,
expectLAN: true,
},
// ---------------
{
name: "client requesting local server",
agentType: "client",
serverType: "server",
requestDC: agentDC,
expectLAN: true,
},
{
name: "client requesting local leader",
agentType: "client",
serverType: "leader",
requestDC: agentDC,
expectLAN: true,
},
}
for _, tc := range cases {
tc := tc
t.Run(tc.name, func(t *testing.T) {
run(t, tc)
})
}
}
func newServerMeta(name, dc, ip string, wan bool) *metadata.Server {
fullname := name
if wan {
fullname = name + "." + dc
}
return &metadata.Server{
ID: name,
Name: fullname,
ShortName: name,
Datacenter: dc,
Addr: &net.IPAddr{IP: net.ParseIP(ip)},
UseTLS: false,
}
}
func newConfig(t *testing.T, dc, agentType string) Config {
n := t.Name()
s := strings.Replace(n, "/", "", -1)
s = strings.Replace(s, "_", "", -1)
return Config{
Datacenter: dc,
AgentType: agentType,
Authority: strings.ToLower(s),
}
}
// fakeClientConn implements resolver.ClientConn for tests
type fakeClientConn struct {
state resolver.State
}
var _ resolver.ClientConn = (*fakeClientConn)(nil)
func (f *fakeClientConn) UpdateState(state resolver.State) error {
f.state = state
return nil
}
func (*fakeClientConn) ReportError(error) {}
func (*fakeClientConn) NewAddress(addresses []resolver.Address) {}
func (*fakeClientConn) NewServiceConfig(serviceConfig string) {}
func (*fakeClientConn) ParseServiceConfig(serviceConfigJSON string) *serviceconfig.ParseResult {
return nil
}