absl/base/nullability.h - third_party/github/abseil/abseil-cpp - Git at Google

 // Copyright 2023 The Abseil Authors.
 //
 // 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
 //
 //      https://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.
 //
 // -----------------------------------------------------------------------------
 // File: nullability.h
 // -----------------------------------------------------------------------------
 //
 // This header file defines a set of "templated annotations" for designating the
 // expected nullability of pointers. These annotations allow you to designate
 // pointers in one of three classification states:
 //
 //  * "Non-null" (for pointers annotated `Nonnull<T>`), indicating that it is
 //    invalid for the given pointer to ever be null.
 //  * "Nullable" (for pointers annotated `Nullable<T>`), indicating that it is
 //    valid for the given pointer to be null.
 //  * "Unknown" (for pointers annotated `NullabilityUnknown<T>`), indicating
 //    that the given pointer has not been yet classified as either nullable or
 //    non-null. This is the default state of unannotated pointers.
 //
 // NOTE: unannotated pointers implicitly bear the annotation
 // `NullabilityUnknown<T>`; you should rarely, if ever, see this annotation used
 // in the codebase explicitly.
 //
 // -----------------------------------------------------------------------------
 // Nullability and Contracts
 // -----------------------------------------------------------------------------
 //
 // These nullability annotations allow you to more clearly specify contracts on
 // software components by narrowing the *preconditions*, *postconditions*, and
 // *invariants* of pointer state(s) in any given interface. It then depends on
 // context who is responsible for fulfilling the annotation's requirements.
 //
 // For example, a function may receive a pointer argument. Designating that
 // pointer argument as "non-null" tightens the precondition of the contract of
 // that function. It is then the responsibility of anyone calling such a
 // function to ensure that the passed pointer is not null.
 //
 // Similarly, a function may have a pointer as a return value. Designating that
 // return value as "non-null" tightens the postcondition of the contract of that
 // function. In this case, however, it is the responsibility of the function
 // itself to ensure that the returned pointer is not null.
 //
 // Clearly defining these contracts allows providers (and consumers) of such
 // pointers to have more confidence in their null state. If a function declares
 // a return value as "non-null", for example, the caller should not need to
 // check whether the returned value is `nullptr`; it can simply assume the
 // pointer is valid.
 //
 // Of course most interfaces already have expectations on the nullability state
 // of pointers, and these expectations are, in effect, a contract; often,
 // however, those contracts are either poorly or partially specified, assumed,
 // or misunderstood. These nullability annotations are designed to allow you to
 // formalize those contracts within the codebase.
 //
 // -----------------------------------------------------------------------------
 // Using Nullability Annotations
 // -----------------------------------------------------------------------------
 //
 // It is important to note that these annotations are not distinct strong
 // *types*. They are alias templates defined to be equal to the underlying
 // pointer type. A pointer annotated `Nonnull<T*>`, for example, is simply a
 // pointer of type `T*`. Each annotation acts as a form of documentation about
 // the contract for the given pointer. Each annotation requires providers or
 // consumers of these pointers across API boundaries to take appropriate steps
 // when setting or using these pointers:
 //
 // * "Non-null" pointers should never be null. It is the responsibility of the
 //   provider of this pointer to ensure that the pointer may never be set to
 //   null. Consumers of such pointers can treat such pointers as non-null.
 // * "Nullable" pointers may or may not be null. Consumers of such pointers
 //   should precede any usage of that pointer (e.g. a dereference operation)
 //   with a a `nullptr` check.
 // * "Unknown" pointers may be either "non-null" or "nullable" but have not been
 //   definitively determined to be in either classification state. Providers of
 //   such pointers across API boundaries should determine --  over time -- to
 //   annotate the pointer in either of the above two states. Consumers of such
 //   pointers across an API boundary should continue to treat such pointers as
 //   they currently do.
 //
 // Example:
 //
 // // PaySalary() requires the passed pointer to an `Employee` to be non-null.
 // void PaySalary(absl::Nonnull<Employee *> e) {
 //   pay(e->salary);  // OK to dereference
 // }
 //
 // // CompleteTransaction() guarantees the returned pointer to an `Account` to
 // // be non-null.
 // absl::Nonnull<Account *> balance CompleteTransaction(double fee) {
 // ...
 // }
 //
 // // Note that specifying a nullability annotation does not prevent someone
 // // from violating the contract:
 //
 // Nullable<Employee *> find(Map& employees, std::string_view name);
 //
 // void g(Map& employees) {
 //   Employee *e = find(employees, "Pat");
 //   // `e` can now be null.
 //   PaySalary(e); // Violates contract, but compiles!
 // }
 //
 // Nullability annotations, in other words, are useful for defining and
 // narrowing contracts; *enforcement* of those contracts depends on use and any
 // additional (static or dynamic analysis) tooling.
 //
 // NOTE: The "unknown" annotation state indicates that a pointer's contract has
 // not yet been positively identified. The unknown state therefore acts as a
 // form of documentation of your technical debt, and a codebase that adopts
 // nullability annotations should aspire to annotate every pointer as either
 // "non-null" or "nullable".
 //
 // -----------------------------------------------------------------------------
 // Applicability of Nullability Annotations
 // -----------------------------------------------------------------------------
 //
 // By default, nullability annotations are applicable to raw and smart
 // pointers. User-defined types can indicate compatibility with nullability
 // annotations by adding the ABSL_NULLABILITY_COMPATIBLE attribute.
 //
 // // Example:
 // struct ABSL_NULLABILITY_COMPATIBLE MyPtr {
 //   ...
 // };
 //
 // Note: For the time being, nullability-compatible classes should additionally
 // be marked with an `absl_nullability_compatible` nested type (this will soon
 // be deprecated). The actual definition of this inner type is not relevant as
 // it is used merely as a marker. It is common to use a using declaration of
 // `absl_nullability_compatible` set to void.
 //
 // // Example:
 // struct MyPtr {
 //   using absl_nullability_compatible = void;
 //   ...
 // };
 //
 // DISCLAIMER:
 // ===========================================================================
 // These nullability annotations are primarily a human readable signal about the
 // intended contract of the pointer. They are not *types* and do not currently
 // provide any correctness guarantees. For example, a pointer annotated as
 // `Nonnull<T*>` is *not guaranteed* to be non-null, and the compiler won't
 // alert or prevent assignment of a `Nullable<T*>` to a `Nonnull<T*>`.
 // ===========================================================================
 #ifndef ABSL_BASE_NULLABILITY_H_
 #define ABSL_BASE_NULLABILITY_H_

 #include "absl/base/config.h"
 #include "absl/base/internal/nullability_impl.h"

 namespace absl {
 ABSL_NAMESPACE_BEGIN

 // absl::Nonnull
 //
 // The indicated pointer is never null. It is the responsibility of the provider
 // of this pointer across an API boundary to ensure that the pointer is never be
 // set to null. Consumers of this pointer across an API boundary may safely
 // dereference the pointer.
 //
 // Example:
 //
 // // `employee` is designated as not null.
 // void PaySalary(absl::Nonnull<Employee *> employee) {
 //   pay(*employee);  // OK to dereference
 // }
 template <typename T>
 using Nonnull = nullability_internal::NonnullImpl<T>;

 // absl::Nullable
 //
 // The indicated pointer may, by design, be either null or non-null. Consumers
 // of this pointer across an API boundary should perform a `nullptr` check
 // before performing any operation using the pointer.
 //
 // Example:
 //
 // // `employee` may  be null.
 // void PaySalary(absl::Nullable<Employee *> employee) {
 //   if (employee != nullptr) {
 //     Pay(*employee);  // OK to dereference
 //   }
 // }
 template <typename T>
 using Nullable = nullability_internal::NullableImpl<T>;

 // absl::NullabilityUnknown (default)
 //
 // The indicated pointer has not yet been determined to be definitively
 // "non-null" or "nullable." Providers of such pointers across API boundaries
 // should, over time, annotate such pointers as either "non-null" or "nullable."
 // Consumers of these pointers across an API boundary should treat such pointers
 // with the same caution they treat currently unannotated pointers. Most
 // existing code will have "unknown"  pointers, which should eventually be
 // migrated into one of the above two nullability states: `Nonnull<T>` or
 //  `Nullable<T>`.
 //
 // NOTE: Because this annotation is the global default state, pointers without
 // any annotation are assumed to have "unknown" semantics. This assumption is
 // designed to minimize churn and reduce clutter within the codebase.
 //
 // Example:
 //
 // // `employee`s nullability state is unknown.
 // void PaySalary(absl::NullabilityUnknown<Employee *> employee) {
 //   Pay(*employee); // Potentially dangerous. API provider should investigate.
 // }
 //
 // Note that a pointer without an annotation, by default, is assumed to have the
 // annotation `NullabilityUnknown`.
 //
 // // `employee`s nullability state is unknown.
 // void PaySalary(Employee* employee) {
 //   Pay(*employee); // Potentially dangerous. API provider should investigate.
 // }
 template <typename T>
 using NullabilityUnknown = nullability_internal::NullabilityUnknownImpl<T>;

 ABSL_NAMESPACE_END
 }  // namespace absl

 // ABSL_NULLABILITY_COMPATIBLE
 //
 // Indicates that a class is compatible with nullability annotations.
 //
 // For example:
 //
 // struct ABSL_NULLABILITY_COMPATIBLE MyPtr {
 //   ...
 // };
 #if ABSL_HAVE_FEATURE(nullability_on_classes)
 #define ABSL_NULLABILITY_COMPATIBLE _Nullable
 #else
 #define ABSL_NULLABILITY_COMPATIBLE
 #endif

 #endif  // ABSL_BASE_NULLABILITY_H_
	// Copyright 2023 The Abseil Authors.
	//
	// 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
	//
	// https://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.
	//
	// -----------------------------------------------------------------------------
	// File: nullability.h
	// -----------------------------------------------------------------------------
	//
	// This header file defines a set of "templated annotations" for designating the
	// expected nullability of pointers. These annotations allow you to designate
	// pointers in one of three classification states:
	//
	// * "Non-null" (for pointers annotated `Nonnull<T>`), indicating that it is
	// invalid for the given pointer to ever be null.
	// * "Nullable" (for pointers annotated `Nullable<T>`), indicating that it is
	// valid for the given pointer to be null.
	// * "Unknown" (for pointers annotated `NullabilityUnknown<T>`), indicating
	// that the given pointer has not been yet classified as either nullable or
	// non-null. This is the default state of unannotated pointers.
	//
	// NOTE: unannotated pointers implicitly bear the annotation
	// `NullabilityUnknown<T>`; you should rarely, if ever, see this annotation used
	// in the codebase explicitly.
	//
	// -----------------------------------------------------------------------------
	// Nullability and Contracts
	// -----------------------------------------------------------------------------
	//
	// These nullability annotations allow you to more clearly specify contracts on
	// software components by narrowing the preconditions, postconditions, and
	// invariants of pointer state(s) in any given interface. It then depends on
	// context who is responsible for fulfilling the annotation's requirements.
	//
	// For example, a function may receive a pointer argument. Designating that
	// pointer argument as "non-null" tightens the precondition of the contract of
	// that function. It is then the responsibility of anyone calling such a
	// function to ensure that the passed pointer is not null.
	//
	// Similarly, a function may have a pointer as a return value. Designating that
	// return value as "non-null" tightens the postcondition of the contract of that
	// function. In this case, however, it is the responsibility of the function
	// itself to ensure that the returned pointer is not null.
	//
	// Clearly defining these contracts allows providers (and consumers) of such
	// pointers to have more confidence in their null state. If a function declares
	// a return value as "non-null", for example, the caller should not need to
	// check whether the returned value is `nullptr`; it can simply assume the
	// pointer is valid.
	//
	// Of course most interfaces already have expectations on the nullability state
	// of pointers, and these expectations are, in effect, a contract; often,
	// however, those contracts are either poorly or partially specified, assumed,
	// or misunderstood. These nullability annotations are designed to allow you to
	// formalize those contracts within the codebase.
	//
	// -----------------------------------------------------------------------------
	// Using Nullability Annotations
	// -----------------------------------------------------------------------------
	//
	// It is important to note that these annotations are not distinct strong
	// types. They are alias templates defined to be equal to the underlying
	// pointer type. A pointer annotated `Nonnull<T*>`, for example, is simply a
	// pointer of type `T*`. Each annotation acts as a form of documentation about
	// the contract for the given pointer. Each annotation requires providers or
	// consumers of these pointers across API boundaries to take appropriate steps
	// when setting or using these pointers:
	//
	// * "Non-null" pointers should never be null. It is the responsibility of the
	// provider of this pointer to ensure that the pointer may never be set to
	// null. Consumers of such pointers can treat such pointers as non-null.
	// * "Nullable" pointers may or may not be null. Consumers of such pointers
	// should precede any usage of that pointer (e.g. a dereference operation)
	// with a a `nullptr` check.
	// * "Unknown" pointers may be either "non-null" or "nullable" but have not been
	// definitively determined to be in either classification state. Providers of
	// such pointers across API boundaries should determine -- over time -- to
	// annotate the pointer in either of the above two states. Consumers of such
	// pointers across an API boundary should continue to treat such pointers as
	// they currently do.
	//
	// Example:
	//
	// // PaySalary() requires the passed pointer to an `Employee` to be non-null.
	// void PaySalary(absl::Nonnull<Employee *> e) {
	// pay(e->salary); // OK to dereference
	// }
	//
	// // CompleteTransaction() guarantees the returned pointer to an `Account` to
	// // be non-null.
	// absl::Nonnull<Account *> balance CompleteTransaction(double fee) {
	// ...
	// }
	//
	// // Note that specifying a nullability annotation does not prevent someone
	// // from violating the contract:
	//
	// Nullable<Employee *> find(Map& employees, std::string_view name);
	//
	// void g(Map& employees) {
	// Employee *e = find(employees, "Pat");
	// // `e` can now be null.
	// PaySalary(e); // Violates contract, but compiles!
	// }
	//
	// Nullability annotations, in other words, are useful for defining and
	// narrowing contracts; enforcement of those contracts depends on use and any
	// additional (static or dynamic analysis) tooling.
	//
	// NOTE: The "unknown" annotation state indicates that a pointer's contract has
	// not yet been positively identified. The unknown state therefore acts as a
	// form of documentation of your technical debt, and a codebase that adopts
	// nullability annotations should aspire to annotate every pointer as either
	// "non-null" or "nullable".
	//
	// -----------------------------------------------------------------------------
	// Applicability of Nullability Annotations
	// -----------------------------------------------------------------------------
	//
	// By default, nullability annotations are applicable to raw and smart
	// pointers. User-defined types can indicate compatibility with nullability
	// annotations by adding the ABSL_NULLABILITY_COMPATIBLE attribute.
	//
	// // Example:
	// struct ABSL_NULLABILITY_COMPATIBLE MyPtr {
	// ...
	// };
	//
	// Note: For the time being, nullability-compatible classes should additionally
	// be marked with an `absl_nullability_compatible` nested type (this will soon
	// be deprecated). The actual definition of this inner type is not relevant as
	// it is used merely as a marker. It is common to use a using declaration of
	// `absl_nullability_compatible` set to void.
	//
	// // Example:
	// struct MyPtr {
	// using absl_nullability_compatible = void;
	// ...
	// };
	//
	// DISCLAIMER:
	// ===========================================================================
	// These nullability annotations are primarily a human readable signal about the
	// intended contract of the pointer. They are not types and do not currently
	// provide any correctness guarantees. For example, a pointer annotated as
	// `Nonnull<T>` is not guaranteed* to be non-null, and the compiler won't
	// alert or prevent assignment of a `Nullable<T>` to a `Nonnull<T>`.
	// ===========================================================================
	#ifndef ABSL_BASE_NULLABILITY_H_
	#define ABSL_BASE_NULLABILITY_H_

	#include "absl/base/config.h"
	#include "absl/base/internal/nullability_impl.h"

	namespace absl {
	ABSL_NAMESPACE_BEGIN

	// absl::Nonnull
	//
	// The indicated pointer is never null. It is the responsibility of the provider
	// of this pointer across an API boundary to ensure that the pointer is never be
	// set to null. Consumers of this pointer across an API boundary may safely
	// dereference the pointer.
	//
	// Example:
	//
	// // `employee` is designated as not null.
	// void PaySalary(absl::Nonnull<Employee *> employee) {
	// pay(*employee); // OK to dereference
	// }
	template <typename T>
	using Nonnull = nullability_internal::NonnullImpl<T>;

	// absl::Nullable
	//
	// The indicated pointer may, by design, be either null or non-null. Consumers
	// of this pointer across an API boundary should perform a `nullptr` check
	// before performing any operation using the pointer.
	//
	// Example:
	//
	// // `employee` may be null.
	// void PaySalary(absl::Nullable<Employee *> employee) {
	// if (employee != nullptr) {
	// Pay(*employee); // OK to dereference
	// }
	// }
	template <typename T>
	using Nullable = nullability_internal::NullableImpl<T>;

	// absl::NullabilityUnknown (default)
	//
	// The indicated pointer has not yet been determined to be definitively
	// "non-null" or "nullable." Providers of such pointers across API boundaries
	// should, over time, annotate such pointers as either "non-null" or "nullable."
	// Consumers of these pointers across an API boundary should treat such pointers
	// with the same caution they treat currently unannotated pointers. Most
	// existing code will have "unknown" pointers, which should eventually be
	// migrated into one of the above two nullability states: `Nonnull<T>` or
	// `Nullable<T>`.
	//
	// NOTE: Because this annotation is the global default state, pointers without
	// any annotation are assumed to have "unknown" semantics. This assumption is
	// designed to minimize churn and reduce clutter within the codebase.
	//
	// Example:
	//
	// // `employee`s nullability state is unknown.
	// void PaySalary(absl::NullabilityUnknown<Employee *> employee) {
	// Pay(*employee); // Potentially dangerous. API provider should investigate.
	// }
	//
	// Note that a pointer without an annotation, by default, is assumed to have the
	// annotation `NullabilityUnknown`.
	//
	// // `employee`s nullability state is unknown.
	// void PaySalary(Employee* employee) {
	// Pay(*employee); // Potentially dangerous. API provider should investigate.
	// }
	template <typename T>
	using NullabilityUnknown = nullability_internal::NullabilityUnknownImpl<T>;

	ABSL_NAMESPACE_END
	} // namespace absl

	// ABSL_NULLABILITY_COMPATIBLE
	//
	// Indicates that a class is compatible with nullability annotations.
	//
	// For example:
	//
	// struct ABSL_NULLABILITY_COMPATIBLE MyPtr {
	// ...
	// };
	#if ABSL_HAVE_FEATURE(nullability_on_classes)
	#define ABSL_NULLABILITY_COMPATIBLE _Nullable
	#else
	#define ABSL_NULLABILITY_COMPATIBLE
	#endif

	#endif // ABSL_BASE_NULLABILITY_H_