mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-11-10 08:20:23 +00:00
07b05616a0
Bumps [k8s.io/kubernetes](https://github.com/kubernetes/kubernetes) from 1.26.2 to 1.27.2. - [Release notes](https://github.com/kubernetes/kubernetes/releases) - [Commits](https://github.com/kubernetes/kubernetes/compare/v1.26.2...v1.27.2) --- updated-dependencies: - dependency-name: k8s.io/kubernetes dependency-type: direct:production update-type: version-update:semver-minor ... Signed-off-by: dependabot[bot] <support@github.com>
642 lines
19 KiB
Go
642 lines
19 KiB
Go
// Copyright 2018 Google LLC
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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// Package checker defines functions to type-checked a parsed expression
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// against a set of identifier and function declarations.
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package checker
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import (
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"fmt"
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"reflect"
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"github.com/google/cel-go/checker/decls"
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"github.com/google/cel-go/common"
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"github.com/google/cel-go/common/containers"
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"github.com/google/cel-go/common/types/ref"
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"google.golang.org/protobuf/proto"
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exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
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)
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type checker struct {
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env *Env
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errors *typeErrors
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mappings *mapping
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freeTypeVarCounter int
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sourceInfo *exprpb.SourceInfo
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types map[int64]*exprpb.Type
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references map[int64]*exprpb.Reference
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}
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// Check performs type checking, giving a typed AST.
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// The input is a ParsedExpr proto and an env which encapsulates
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// type binding of variables, declarations of built-in functions,
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// descriptions of protocol buffers, and a registry for errors.
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// Returns a CheckedExpr proto, which might not be usable if
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// there are errors in the error registry.
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func Check(parsedExpr *exprpb.ParsedExpr,
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source common.Source,
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env *Env) (*exprpb.CheckedExpr, *common.Errors) {
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c := checker{
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env: env,
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errors: &typeErrors{common.NewErrors(source)},
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mappings: newMapping(),
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freeTypeVarCounter: 0,
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sourceInfo: parsedExpr.GetSourceInfo(),
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types: make(map[int64]*exprpb.Type),
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references: make(map[int64]*exprpb.Reference),
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}
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c.check(parsedExpr.GetExpr())
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// Walk over the final type map substituting any type parameters either by their bound value or
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// by DYN.
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m := make(map[int64]*exprpb.Type)
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for k, v := range c.types {
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m[k] = substitute(c.mappings, v, true)
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}
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return &exprpb.CheckedExpr{
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Expr: parsedExpr.GetExpr(),
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SourceInfo: parsedExpr.GetSourceInfo(),
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TypeMap: m,
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ReferenceMap: c.references,
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}, c.errors.Errors
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}
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func (c *checker) check(e *exprpb.Expr) {
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if e == nil {
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return
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}
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switch e.GetExprKind().(type) {
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case *exprpb.Expr_ConstExpr:
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literal := e.GetConstExpr()
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switch literal.GetConstantKind().(type) {
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case *exprpb.Constant_BoolValue:
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c.checkBoolLiteral(e)
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case *exprpb.Constant_BytesValue:
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c.checkBytesLiteral(e)
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case *exprpb.Constant_DoubleValue:
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c.checkDoubleLiteral(e)
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case *exprpb.Constant_Int64Value:
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c.checkInt64Literal(e)
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case *exprpb.Constant_NullValue:
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c.checkNullLiteral(e)
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case *exprpb.Constant_StringValue:
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c.checkStringLiteral(e)
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case *exprpb.Constant_Uint64Value:
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c.checkUint64Literal(e)
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}
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case *exprpb.Expr_IdentExpr:
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c.checkIdent(e)
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case *exprpb.Expr_SelectExpr:
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c.checkSelect(e)
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case *exprpb.Expr_CallExpr:
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c.checkCall(e)
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case *exprpb.Expr_ListExpr:
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c.checkCreateList(e)
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case *exprpb.Expr_StructExpr:
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c.checkCreateStruct(e)
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case *exprpb.Expr_ComprehensionExpr:
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c.checkComprehension(e)
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default:
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c.errors.ReportError(
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c.location(e), "Unrecognized ast type: %v", reflect.TypeOf(e))
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}
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}
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func (c *checker) checkInt64Literal(e *exprpb.Expr) {
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c.setType(e, decls.Int)
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}
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func (c *checker) checkUint64Literal(e *exprpb.Expr) {
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c.setType(e, decls.Uint)
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}
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func (c *checker) checkStringLiteral(e *exprpb.Expr) {
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c.setType(e, decls.String)
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}
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func (c *checker) checkBytesLiteral(e *exprpb.Expr) {
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c.setType(e, decls.Bytes)
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}
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func (c *checker) checkDoubleLiteral(e *exprpb.Expr) {
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c.setType(e, decls.Double)
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}
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func (c *checker) checkBoolLiteral(e *exprpb.Expr) {
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c.setType(e, decls.Bool)
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}
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func (c *checker) checkNullLiteral(e *exprpb.Expr) {
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c.setType(e, decls.Null)
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}
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func (c *checker) checkIdent(e *exprpb.Expr) {
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identExpr := e.GetIdentExpr()
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// Check to see if the identifier is declared.
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if ident := c.env.LookupIdent(identExpr.GetName()); ident != nil {
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c.setType(e, ident.GetIdent().GetType())
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c.setReference(e, newIdentReference(ident.GetName(), ident.GetIdent().GetValue()))
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// Overwrite the identifier with its fully qualified name.
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identExpr.Name = ident.GetName()
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return
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}
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c.setType(e, decls.Error)
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c.errors.undeclaredReference(
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c.location(e), c.env.container.Name(), identExpr.GetName())
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}
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func (c *checker) checkSelect(e *exprpb.Expr) {
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sel := e.GetSelectExpr()
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// Before traversing down the tree, try to interpret as qualified name.
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qname, found := containers.ToQualifiedName(e)
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if found {
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ident := c.env.LookupIdent(qname)
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if ident != nil {
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// We don't check for a TestOnly expression here since the `found` result is
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// always going to be false for TestOnly expressions.
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// Rewrite the node to be a variable reference to the resolved fully-qualified
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// variable name.
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c.setType(e, ident.GetIdent().Type)
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c.setReference(e, newIdentReference(ident.GetName(), ident.GetIdent().Value))
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identName := ident.GetName()
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e.ExprKind = &exprpb.Expr_IdentExpr{
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IdentExpr: &exprpb.Expr_Ident{
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Name: identName,
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},
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}
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return
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}
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}
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// Interpret as field selection, first traversing down the operand.
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c.check(sel.GetOperand())
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targetType := substitute(c.mappings, c.getType(sel.GetOperand()), false)
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// Assume error type by default as most types do not support field selection.
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resultType := decls.Error
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switch kindOf(targetType) {
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case kindMap:
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// Maps yield their value type as the selection result type.
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mapType := targetType.GetMapType()
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resultType = mapType.GetValueType()
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case kindObject:
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// Objects yield their field type declaration as the selection result type, but only if
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// the field is defined.
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messageType := targetType
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if fieldType, found := c.lookupFieldType(c.location(e), messageType.GetMessageType(), sel.GetField()); found {
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resultType = fieldType.Type
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}
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case kindTypeParam:
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// Set the operand type to DYN to prevent assignment to a potentially incorrect type
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// at a later point in type-checking. The isAssignable call will update the type
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// substitutions for the type param under the covers.
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c.isAssignable(decls.Dyn, targetType)
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// Also, set the result type to DYN.
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resultType = decls.Dyn
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default:
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// Dynamic / error values are treated as DYN type. Errors are handled this way as well
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// in order to allow forward progress on the check.
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if isDynOrError(targetType) {
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resultType = decls.Dyn
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} else {
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c.errors.typeDoesNotSupportFieldSelection(c.location(e), targetType)
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}
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}
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if sel.TestOnly {
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resultType = decls.Bool
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}
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c.setType(e, substitute(c.mappings, resultType, false))
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}
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func (c *checker) checkCall(e *exprpb.Expr) {
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// Note: similar logic exists within the `interpreter/planner.go`. If making changes here
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// please consider the impact on planner.go and consolidate implementations or mirror code
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// as appropriate.
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call := e.GetCallExpr()
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target := call.GetTarget()
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args := call.GetArgs()
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fnName := call.GetFunction()
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// Traverse arguments.
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for _, arg := range args {
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c.check(arg)
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}
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// Regular static call with simple name.
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if target == nil {
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// Check for the existence of the function.
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fn := c.env.LookupFunction(fnName)
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if fn == nil {
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c.errors.undeclaredReference(
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c.location(e), c.env.container.Name(), fnName)
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c.setType(e, decls.Error)
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return
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}
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// Overwrite the function name with its fully qualified resolved name.
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call.Function = fn.GetName()
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// Check to see whether the overload resolves.
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c.resolveOverloadOrError(c.location(e), e, fn, nil, args)
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return
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}
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// If a receiver 'target' is present, it may either be a receiver function, or a namespaced
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// function, but not both. Given a.b.c() either a.b.c is a function or c is a function with
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// target a.b.
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//
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// Check whether the target is a namespaced function name.
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qualifiedPrefix, maybeQualified := containers.ToQualifiedName(target)
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if maybeQualified {
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maybeQualifiedName := qualifiedPrefix + "." + fnName
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fn := c.env.LookupFunction(maybeQualifiedName)
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if fn != nil {
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// The function name is namespaced and so preserving the target operand would
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// be an inaccurate representation of the desired evaluation behavior.
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// Overwrite with fully-qualified resolved function name sans receiver target.
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call.Target = nil
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call.Function = fn.GetName()
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c.resolveOverloadOrError(c.location(e), e, fn, nil, args)
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return
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}
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}
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// Regular instance call.
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c.check(call.Target)
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fn := c.env.LookupFunction(fnName)
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// Function found, attempt overload resolution.
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if fn != nil {
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c.resolveOverloadOrError(c.location(e), e, fn, target, args)
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return
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}
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// Function name not declared, record error.
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c.errors.undeclaredReference(c.location(e), c.env.container.Name(), fnName)
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}
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func (c *checker) resolveOverloadOrError(
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loc common.Location,
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e *exprpb.Expr,
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fn *exprpb.Decl, target *exprpb.Expr, args []*exprpb.Expr) {
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// Attempt to resolve the overload.
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resolution := c.resolveOverload(loc, fn, target, args)
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// No such overload, error noted in the resolveOverload call, type recorded here.
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if resolution == nil {
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c.setType(e, decls.Error)
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return
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}
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// Overload found.
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c.setType(e, resolution.Type)
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c.setReference(e, resolution.Reference)
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}
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func (c *checker) resolveOverload(
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loc common.Location,
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fn *exprpb.Decl, target *exprpb.Expr, args []*exprpb.Expr) *overloadResolution {
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var argTypes []*exprpb.Type
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if target != nil {
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argTypes = append(argTypes, c.getType(target))
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}
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for _, arg := range args {
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argTypes = append(argTypes, c.getType(arg))
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}
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var resultType *exprpb.Type
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var checkedRef *exprpb.Reference
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for _, overload := range fn.GetFunction().GetOverloads() {
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// Determine whether the overload is currently considered.
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if c.env.isOverloadDisabled(overload.GetOverloadId()) {
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continue
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}
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// Ensure the call style for the overload matches.
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if (target == nil && overload.GetIsInstanceFunction()) ||
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(target != nil && !overload.GetIsInstanceFunction()) {
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// not a compatible call style.
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continue
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}
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overloadType := decls.NewFunctionType(overload.ResultType, overload.Params...)
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if len(overload.GetTypeParams()) > 0 {
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// Instantiate overload's type with fresh type variables.
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substitutions := newMapping()
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for _, typePar := range overload.GetTypeParams() {
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substitutions.add(decls.NewTypeParamType(typePar), c.newTypeVar())
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}
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overloadType = substitute(substitutions, overloadType, false)
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}
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candidateArgTypes := overloadType.GetFunction().GetArgTypes()
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if c.isAssignableList(argTypes, candidateArgTypes) {
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if checkedRef == nil {
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checkedRef = newFunctionReference(overload.GetOverloadId())
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} else {
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checkedRef.OverloadId = append(checkedRef.GetOverloadId(), overload.GetOverloadId())
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}
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// First matching overload, determines result type.
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fnResultType := substitute(c.mappings, overloadType.GetFunction().GetResultType(), false)
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if resultType == nil {
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resultType = fnResultType
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} else if !isDyn(resultType) && !proto.Equal(fnResultType, resultType) {
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resultType = decls.Dyn
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}
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}
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}
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if resultType == nil {
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c.errors.noMatchingOverload(loc, fn.GetName(), argTypes, target != nil)
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resultType = decls.Error
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return nil
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}
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return newResolution(checkedRef, resultType)
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}
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func (c *checker) checkCreateList(e *exprpb.Expr) {
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create := e.GetListExpr()
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var elemType *exprpb.Type
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for _, e := range create.GetElements() {
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c.check(e)
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elemType = c.joinTypes(c.location(e), elemType, c.getType(e))
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}
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if elemType == nil {
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// If the list is empty, assign free type var to elem type.
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elemType = c.newTypeVar()
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}
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c.setType(e, decls.NewListType(elemType))
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}
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func (c *checker) checkCreateStruct(e *exprpb.Expr) {
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str := e.GetStructExpr()
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if str.GetMessageName() != "" {
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c.checkCreateMessage(e)
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} else {
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c.checkCreateMap(e)
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}
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}
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func (c *checker) checkCreateMap(e *exprpb.Expr) {
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mapVal := e.GetStructExpr()
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var keyType *exprpb.Type
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var valueType *exprpb.Type
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for _, ent := range mapVal.GetEntries() {
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key := ent.GetMapKey()
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c.check(key)
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keyType = c.joinTypes(c.location(key), keyType, c.getType(key))
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c.check(ent.Value)
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valueType = c.joinTypes(c.location(ent.Value), valueType, c.getType(ent.Value))
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}
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if keyType == nil {
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// If the map is empty, assign free type variables to typeKey and value type.
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keyType = c.newTypeVar()
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valueType = c.newTypeVar()
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}
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c.setType(e, decls.NewMapType(keyType, valueType))
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}
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func (c *checker) checkCreateMessage(e *exprpb.Expr) {
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msgVal := e.GetStructExpr()
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// Determine the type of the message.
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messageType := decls.Error
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decl := c.env.LookupIdent(msgVal.GetMessageName())
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if decl == nil {
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c.errors.undeclaredReference(
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c.location(e), c.env.container.Name(), msgVal.GetMessageName())
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return
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}
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// Ensure the type name is fully qualified in the AST.
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msgVal.MessageName = decl.GetName()
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c.setReference(e, newIdentReference(decl.GetName(), nil))
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ident := decl.GetIdent()
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identKind := kindOf(ident.GetType())
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if identKind != kindError {
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if identKind != kindType {
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c.errors.notAType(c.location(e), ident.GetType())
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} else {
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messageType = ident.GetType().GetType()
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if kindOf(messageType) != kindObject {
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c.errors.notAMessageType(c.location(e), messageType)
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messageType = decls.Error
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}
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}
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}
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if isObjectWellKnownType(messageType) {
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c.setType(e, getObjectWellKnownType(messageType))
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} else {
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c.setType(e, messageType)
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}
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// Check the field initializers.
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for _, ent := range msgVal.GetEntries() {
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field := ent.GetFieldKey()
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value := ent.GetValue()
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c.check(value)
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fieldType := decls.Error
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if t, found := c.lookupFieldType(
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c.locationByID(ent.GetId()),
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messageType.GetMessageType(),
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field); found {
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fieldType = t.Type
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}
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if !c.isAssignable(fieldType, c.getType(value)) {
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c.errors.fieldTypeMismatch(
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c.locationByID(ent.Id), field, fieldType, c.getType(value))
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}
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}
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}
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func (c *checker) checkComprehension(e *exprpb.Expr) {
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comp := e.GetComprehensionExpr()
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c.check(comp.GetIterRange())
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c.check(comp.GetAccuInit())
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accuType := c.getType(comp.GetAccuInit())
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rangeType := substitute(c.mappings, c.getType(comp.GetIterRange()), false)
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var varType *exprpb.Type
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switch kindOf(rangeType) {
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case kindList:
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varType = rangeType.GetListType().GetElemType()
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case kindMap:
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// Ranges over the keys.
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varType = rangeType.GetMapType().GetKeyType()
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case kindDyn, kindError, kindTypeParam:
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// Set the range type to DYN to prevent assignment to a potentially incorrect type
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// at a later point in type-checking. The isAssignable call will update the type
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// substitutions for the type param under the covers.
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c.isAssignable(decls.Dyn, rangeType)
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// Set the range iteration variable to type DYN as well.
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varType = decls.Dyn
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default:
|
|
c.errors.notAComprehensionRange(c.location(comp.GetIterRange()), rangeType)
|
|
varType = decls.Error
|
|
}
|
|
|
|
// Create a scope for the comprehension since it has a local accumulation variable.
|
|
// This scope will contain the accumulation variable used to compute the result.
|
|
c.env = c.env.enterScope()
|
|
c.env.Add(decls.NewVar(comp.GetAccuVar(), accuType))
|
|
// Create a block scope for the loop.
|
|
c.env = c.env.enterScope()
|
|
c.env.Add(decls.NewVar(comp.GetIterVar(), varType))
|
|
// Check the variable references in the condition and step.
|
|
c.check(comp.GetLoopCondition())
|
|
c.assertType(comp.GetLoopCondition(), decls.Bool)
|
|
c.check(comp.GetLoopStep())
|
|
c.assertType(comp.GetLoopStep(), accuType)
|
|
// Exit the loop's block scope before checking the result.
|
|
c.env = c.env.exitScope()
|
|
c.check(comp.GetResult())
|
|
// Exit the comprehension scope.
|
|
c.env = c.env.exitScope()
|
|
c.setType(e, substitute(c.mappings, c.getType(comp.GetResult()), false))
|
|
}
|
|
|
|
// Checks compatibility of joined types, and returns the most general common type.
|
|
func (c *checker) joinTypes(loc common.Location,
|
|
previous *exprpb.Type,
|
|
current *exprpb.Type) *exprpb.Type {
|
|
if previous == nil {
|
|
return current
|
|
}
|
|
if c.isAssignable(previous, current) {
|
|
return mostGeneral(previous, current)
|
|
}
|
|
if c.dynAggregateLiteralElementTypesEnabled() {
|
|
return decls.Dyn
|
|
}
|
|
c.errors.typeMismatch(loc, previous, current)
|
|
return decls.Error
|
|
}
|
|
|
|
func (c *checker) dynAggregateLiteralElementTypesEnabled() bool {
|
|
return c.env.aggLitElemType == dynElementType
|
|
}
|
|
|
|
func (c *checker) newTypeVar() *exprpb.Type {
|
|
id := c.freeTypeVarCounter
|
|
c.freeTypeVarCounter++
|
|
return decls.NewTypeParamType(fmt.Sprintf("_var%d", id))
|
|
}
|
|
|
|
func (c *checker) isAssignable(t1 *exprpb.Type, t2 *exprpb.Type) bool {
|
|
subs := isAssignable(c.mappings, t1, t2)
|
|
if subs != nil {
|
|
c.mappings = subs
|
|
return true
|
|
}
|
|
|
|
return false
|
|
}
|
|
|
|
func (c *checker) isAssignableList(l1 []*exprpb.Type, l2 []*exprpb.Type) bool {
|
|
subs := isAssignableList(c.mappings, l1, l2)
|
|
if subs != nil {
|
|
c.mappings = subs
|
|
return true
|
|
}
|
|
|
|
return false
|
|
}
|
|
|
|
func (c *checker) lookupFieldType(l common.Location, messageType string, fieldName string) (*ref.FieldType, bool) {
|
|
if _, found := c.env.provider.FindType(messageType); !found {
|
|
// This should not happen, anyway, report an error.
|
|
c.errors.unexpectedFailedResolution(l, messageType)
|
|
return nil, false
|
|
}
|
|
|
|
if ft, found := c.env.provider.FindFieldType(messageType, fieldName); found {
|
|
return ft, found
|
|
}
|
|
|
|
c.errors.undefinedField(l, fieldName)
|
|
return nil, false
|
|
}
|
|
|
|
func (c *checker) setType(e *exprpb.Expr, t *exprpb.Type) {
|
|
if old, found := c.types[e.GetId()]; found && !proto.Equal(old, t) {
|
|
c.errors.ReportError(c.location(e),
|
|
"(Incompatible) Type already exists for expression: %v(%d) old:%v, new:%v", e, e.GetId(), old, t)
|
|
return
|
|
}
|
|
c.types[e.GetId()] = t
|
|
}
|
|
|
|
func (c *checker) getType(e *exprpb.Expr) *exprpb.Type {
|
|
return c.types[e.GetId()]
|
|
}
|
|
|
|
func (c *checker) setReference(e *exprpb.Expr, r *exprpb.Reference) {
|
|
if old, found := c.references[e.GetId()]; found && !proto.Equal(old, r) {
|
|
c.errors.ReportError(c.location(e),
|
|
"Reference already exists for expression: %v(%d) old:%v, new:%v", e, e.GetId(), old, r)
|
|
return
|
|
}
|
|
c.references[e.GetId()] = r
|
|
}
|
|
|
|
func (c *checker) assertType(e *exprpb.Expr, t *exprpb.Type) {
|
|
if !c.isAssignable(t, c.getType(e)) {
|
|
c.errors.typeMismatch(c.location(e), t, c.getType(e))
|
|
}
|
|
}
|
|
|
|
type overloadResolution struct {
|
|
Reference *exprpb.Reference
|
|
Type *exprpb.Type
|
|
}
|
|
|
|
func newResolution(checkedRef *exprpb.Reference, t *exprpb.Type) *overloadResolution {
|
|
return &overloadResolution{
|
|
Reference: checkedRef,
|
|
Type: t,
|
|
}
|
|
}
|
|
|
|
func (c *checker) location(e *exprpb.Expr) common.Location {
|
|
return c.locationByID(e.GetId())
|
|
}
|
|
|
|
func (c *checker) locationByID(id int64) common.Location {
|
|
positions := c.sourceInfo.GetPositions()
|
|
var line = 1
|
|
if offset, found := positions[id]; found {
|
|
col := int(offset)
|
|
for _, lineOffset := range c.sourceInfo.GetLineOffsets() {
|
|
if lineOffset < offset {
|
|
line++
|
|
col = int(offset - lineOffset)
|
|
} else {
|
|
break
|
|
}
|
|
}
|
|
return common.NewLocation(line, col)
|
|
}
|
|
return common.NoLocation
|
|
}
|
|
|
|
func newIdentReference(name string, value *exprpb.Constant) *exprpb.Reference {
|
|
return &exprpb.Reference{Name: name, Value: value}
|
|
}
|
|
|
|
func newFunctionReference(overloads ...string) *exprpb.Reference {
|
|
return &exprpb.Reference{OverloadId: overloads}
|
|
}
|