proto/google/api/expr/v1beta1/expr.proto

266 lines
8.7 KiB
Protocol Buffer
Raw Normal View History

2023-11-27 09:36:02 +00:00
// Copyright 2019 Google LLC.
//
// 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.
//
syntax = "proto3";
package google.api.expr.v1beta1;
import "google/api/expr/v1beta1/source.proto";
import "google/protobuf/struct.proto";
option cc_enable_arenas = true;
option go_package = "google.golang.org/genproto/googleapis/api/expr/v1beta1;expr";
option java_multiple_files = true;
option java_outer_classname = "ExprProto";
option java_package = "com.google.api.expr.v1beta1";
// An expression together with source information as returned by the parser.
message ParsedExpr {
// The parsed expression.
Expr expr = 2;
// The source info derived from input that generated the parsed `expr`.
SourceInfo source_info = 3;
// The syntax version of the source, e.g. `cel1`.
string syntax_version = 4;
}
// An abstract representation of a common expression.
//
// Expressions are abstractly represented as a collection of identifiers,
// select statements, function calls, literals, and comprehensions. All
// operators with the exception of the '.' operator are modelled as function
// calls. This makes it easy to represent new operators into the existing AST.
//
// All references within expressions must resolve to a [Decl][google.api.expr.v1beta1.Decl] provided at
// type-check for an expression to be valid. A reference may either be a bare
// identifier `name` or a qualified identifier `google.api.name`. References
// may either refer to a value or a function declaration.
//
// For example, the expression `google.api.name.startsWith('expr')` references
// the declaration `google.api.name` within a [Expr.Select][google.api.expr.v1beta1.Expr.Select] expression, and
// the function declaration `startsWith`.
message Expr {
// An identifier expression. e.g. `request`.
message Ident {
// Required. Holds a single, unqualified identifier, possibly preceded by a
// '.'.
//
// Qualified names are represented by the [Expr.Select][google.api.expr.v1beta1.Expr.Select] expression.
string name = 1;
}
// A field selection expression. e.g. `request.auth`.
message Select {
// Required. The target of the selection expression.
//
// For example, in the select expression `request.auth`, the `request`
// portion of the expression is the `operand`.
Expr operand = 1;
// Required. The name of the field to select.
//
// For example, in the select expression `request.auth`, the `auth` portion
// of the expression would be the `field`.
string field = 2;
// Whether the select is to be interpreted as a field presence test.
//
// This results from the macro `has(request.auth)`.
bool test_only = 3;
}
// A call expression, including calls to predefined functions and operators.
//
// For example, `value == 10`, `size(map_value)`.
message Call {
// The target of an method call-style expression. For example, `x` in
// `x.f()`.
Expr target = 1;
// Required. The name of the function or method being called.
string function = 2;
// The arguments.
repeated Expr args = 3;
}
// A list creation expression.
//
// Lists may either be homogenous, e.g. `[1, 2, 3]`, or heterogenous, e.g.
// `dyn([1, 'hello', 2.0])`
message CreateList {
// The elements part of the list.
repeated Expr elements = 1;
}
// A map or message creation expression.
//
// Maps are constructed as `{'key_name': 'value'}`. Message construction is
// similar, but prefixed with a type name and composed of field ids:
// `types.MyType{field_id: 'value'}`.
message CreateStruct {
// Represents an entry.
message Entry {
// Required. An id assigned to this node by the parser which is unique
// in a given expression tree. This is used to associate type
// information and other attributes to the node.
int32 id = 1;
// The `Entry` key kinds.
oneof key_kind {
// The field key for a message creator statement.
string field_key = 2;
// The key expression for a map creation statement.
Expr map_key = 3;
}
// Required. The value assigned to the key.
Expr value = 4;
}
// The type name of the message to be created, empty when creating map
// literals.
string type = 1;
// The entries in the creation expression.
repeated Entry entries = 2;
}
// A comprehension expression applied to a list or map.
//
// Comprehensions are not part of the core syntax, but enabled with macros.
// A macro matches a specific call signature within a parsed AST and replaces
// the call with an alternate AST block. Macro expansion happens at parse
// time.
//
// The following macros are supported within CEL:
//
// Aggregate type macros may be applied to all elements in a list or all keys
// in a map:
//
// * `all`, `exists`, `exists_one` - test a predicate expression against
// the inputs and return `true` if the predicate is satisfied for all,
// any, or only one value `list.all(x, x < 10)`.
// * `filter` - test a predicate expression against the inputs and return
// the subset of elements which satisfy the predicate:
// `payments.filter(p, p > 1000)`.
// * `map` - apply an expression to all elements in the input and return the
// output aggregate type: `[1, 2, 3].map(i, i * i)`.
//
// The `has(m.x)` macro tests whether the property `x` is present in struct
// `m`. The semantics of this macro depend on the type of `m`. For proto2
// messages `has(m.x)` is defined as 'defined, but not set`. For proto3, the
// macro tests whether the property is set to its default. For map and struct
// types, the macro tests whether the property `x` is defined on `m`.
message Comprehension {
// The name of the iteration variable.
string iter_var = 1;
// The range over which var iterates.
Expr iter_range = 2;
// The name of the variable used for accumulation of the result.
string accu_var = 3;
// The initial value of the accumulator.
Expr accu_init = 4;
// An expression which can contain iter_var and accu_var.
//
// Returns false when the result has been computed and may be used as
// a hint to short-circuit the remainder of the comprehension.
Expr loop_condition = 5;
// An expression which can contain iter_var and accu_var.
//
// Computes the next value of accu_var.
Expr loop_step = 6;
// An expression which can contain accu_var.
//
// Computes the result.
Expr result = 7;
}
// Required. An id assigned to this node by the parser which is unique in a
// given expression tree. This is used to associate type information and other
// attributes to a node in the parse tree.
int32 id = 2;
// Required. Variants of expressions.
oneof expr_kind {
// A literal expression.
Literal literal_expr = 3;
// An identifier expression.
Ident ident_expr = 4;
// A field selection expression, e.g. `request.auth`.
Select select_expr = 5;
// A call expression, including calls to predefined functions and operators.
Call call_expr = 6;
// A list creation expression.
CreateList list_expr = 7;
// A map or object creation expression.
CreateStruct struct_expr = 8;
// A comprehension expression.
Comprehension comprehension_expr = 9;
}
}
// Represents a primitive literal.
//
// This is similar to the primitives supported in the well-known type
// `google.protobuf.Value`, but richer so it can represent CEL's full range of
// primitives.
//
// Lists and structs are not included as constants as these aggregate types may
// contain [Expr][google.api.expr.v1beta1.Expr] elements which require evaluation and are thus not constant.
//
// Examples of literals include: `"hello"`, `b'bytes'`, `1u`, `4.2`, `-2`,
// `true`, `null`.
message Literal {
// Required. The valid constant kinds.
oneof constant_kind {
// null value.
google.protobuf.NullValue null_value = 1;
// boolean value.
bool bool_value = 2;
// int64 value.
int64 int64_value = 3;
// uint64 value.
uint64 uint64_value = 4;
// double value.
double double_value = 5;
// string value.
string string_value = 6;
// bytes value.
bytes bytes_value = 7;
}
}