// Copyright 2010 Google Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package gomock
import (
"fmt"
"reflect"
"strings"
)
// Call represents an expected call to a mock.
type Call struct {
t TestReporter // for triggering test failures on invalid call setup
receiver interface{} // the receiver of the method call
method string // the name of the method
methodType reflect.Type // the type of the method
args []Matcher // the args
rets []interface{} // the return values (if any)
preReqs []*Call // prerequisite calls
// Expectations
minCalls, maxCalls int
numCalls int // actual number made
// Actions
doFunc reflect.Value
setArgs map[int]reflect.Value
}
// AnyTimes allows the expectation to be called 0 or more times
func (c *Call) AnyTimes() *Call {
c.minCalls, c.maxCalls = 0, 1e8 // close enough to infinity
return c
}
// MinTimes requires the call to occur at least n times. If AnyTimes or MaxTimes have not been called, MinTimes also
// sets the maximum number of calls to infinity.
func (c *Call) MinTimes(n int) *Call {
c.minCalls = n
if c.maxCalls == 1 {
c.maxCalls = 1e8
}
return c
}
// MaxTimes limits the number of calls to n times. If AnyTimes or MinTimes have not been called, MaxTimes also
// sets the minimum number of calls to 0.
func (c *Call) MaxTimes(n int) *Call {
c.maxCalls = n
if c.minCalls == 1 {
c.minCalls = 0
}
return c
}
// Do declares the action to run when the call is matched.
// It takes an interface{} argument to support n-arity functions.
func (c *Call) Do(f interface{}) *Call {
// TODO: Check arity and types here, rather than dying badly elsewhere.
c.doFunc = reflect.ValueOf(f)
return c
}
func (c *Call) Return(rets ...interface{}) *Call {
mt := c.methodType
if len(rets) != mt.NumOut() {
c.t.Fatalf("wrong number of arguments to Return for %T.%v: got %d, want %d",
c.receiver, c.method, len(rets), mt.NumOut())
}
for i, ret := range rets {
if got, want := reflect.TypeOf(ret), mt.Out(i); got == want {
// Identical types; nothing to do.
} else if got == nil {
// Nil needs special handling.
switch want.Kind() {
case reflect.Chan, reflect.Func, reflect.Interface, reflect.Map, reflect.Ptr, reflect.Slice:
// ok
default:
c.t.Fatalf("argument %d to Return for %T.%v is nil, but %v is not nillable",
i, c.receiver, c.method, want)
}
} else if got.AssignableTo(want) {
// Assignable type relation. Make the assignment now so that the generated code
// can return the values with a type assertion.
v := reflect.New(want).Elem()
v.Set(reflect.ValueOf(ret))
rets[i] = v.Interface()
} else {
c.t.Fatalf("wrong type of argument %d to Return for %T.%v: %v is not assignable to %v",
i, c.receiver, c.method, got, want)
}
}
c.rets = rets
return c
}
func (c *Call) Times(n int) *Call {
c.minCalls, c.maxCalls = n, n
return c
}
// SetArg declares an action that will set the nth argument's value,
// indirected through a pointer.
func (c *Call) SetArg(n int, value interface{}) *Call {
if c.setArgs == nil {
c.setArgs = make(map[int]reflect.Value)
}
mt := c.methodType
// TODO: This will break on variadic methods.
// We will need to check those at invocation time.
if n < 0 || n >= mt.NumIn() {
c.t.Fatalf("SetArg(%d, ...) called for a method with %d args", n, mt.NumIn())
}
// Permit setting argument through an interface.
// In the interface case, we don't (nay, can't) check the type here.
at := mt.In(n)
switch at.Kind() {
case reflect.Ptr:
dt := at.Elem()
if vt := reflect.TypeOf(value); !vt.AssignableTo(dt) {
c.t.Fatalf("SetArg(%d, ...) argument is a %v, not assignable to %v", n, vt, dt)
}
case reflect.Interface:
// nothing to do
default:
c.t.Fatalf("SetArg(%d, ...) referring to argument of non-pointer non-interface type %v", n, at)
}
c.setArgs[n] = reflect.ValueOf(value)
return c
}
// isPreReq returns true if other is a direct or indirect prerequisite to c.
func (c *Call) isPreReq(other *Call) bool {
for _, preReq := range c.preReqs {
if other == preReq || preReq.isPreReq(other) {
return true
}
}
return false
}
// After declares that the call may only match after preReq has been exhausted.
func (c *Call) After(preReq *Call) *Call {
if c == preReq {
c.t.Fatalf("A call isn't allowed to be it's own prerequisite")
}
if preReq.isPreReq(c) {
c.t.Fatalf("Loop in call order: %v is a prerequisite to %v (possibly indirectly).", c, preReq)
}
c.preReqs = append(c.preReqs, preReq)
return c
}
// Returns true iff the minimum number of calls have been made.
func (c *Call) satisfied() bool {
return c.numCalls >= c.minCalls
}
// Returns true iff the maximum number of calls have been made.
func (c *Call) exhausted() bool {
return c.numCalls >= c.maxCalls
}
func (c *Call) String() string {
args := make([]string, len(c.args))
for i, arg := range c.args {
args[i] = arg.String()
}
arguments := strings.Join(args, ", ")
return fmt.Sprintf("%T.%v(%s)", c.receiver, c.method, arguments)
}
// Tests if the given call matches the expected call.
func (c *Call) matches(args []interface{}) bool {
if len(args) != len(c.args) {
return false
}
for i, m := range c.args {
if !m.Matches(args[i]) {
return false
}
}
// Check that all prerequisite calls have been satisfied.
for _, preReqCall := range c.preReqs {
if !preReqCall.satisfied() {
return false
}
}
return true
}
// dropPrereqs tells the expected Call to not re-check prerequite calls any
// longer, and to return its current set.
func (c *Call) dropPrereqs() (preReqs []*Call) {
preReqs = c.preReqs
c.preReqs = nil
return
}
func (c *Call) call(args []interface{}) (rets []interface{}, action func()) {
c.numCalls++
// Actions
if c.doFunc.IsValid() {
doArgs := make([]reflect.Value, len(args))
ft := c.doFunc.Type()
for i := 0; i < len(args); i++ {
if args[i] != nil {
doArgs[i] = reflect.ValueOf(args[i])
} else {
// Use the zero value for the arg.
doArgs[i] = reflect.Zero(ft.In(i))
}
}
action = func() { c.doFunc.Call(doArgs) }
}
for n, v := range c.setArgs {
reflect.ValueOf(args[n]).Elem().Set(v)
}
rets = c.rets
if rets == nil {
// Synthesize the zero value for each of the return args' types.
mt := c.methodType
rets = make([]interface{}, mt.NumOut())
for i := 0; i < mt.NumOut(); i++ {
rets[i] = reflect.Zero(mt.Out(i)).Interface()
}
}
return
}
// InOrder declares that the given calls should occur in order.
func InOrder(calls ...*Call) {
for i := 1; i < len(calls); i++ {
calls[i].After(calls[i-1])
}
}