Protocol Buffers - Google's data interchange format (grpc依赖) https://developers.google.com/protocol-buffers/
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/*
** upb::Handlers (upb_handlers)
**
** A upb_handlers is like a virtual table for a upb_msgdef. Each field of the
** message can have associated functions that will be called when we are
** parsing or visiting a stream of data. This is similar to how handlers work
** in SAX (the Simple API for XML).
**
** The handlers have no idea where the data is coming from, so a single set of
** handlers could be used with two completely different data sources (for
** example, a parser and a visitor over in-memory objects). This decoupling is
** the most important feature of upb, because it allows parsers and serializers
** to be highly reusable.
**
** This is a mixed C/C++ interface that offers a full API to both languages.
** See the top-level README for more information.
*/
#ifndef UPB_HANDLERS_H
#define UPB_HANDLERS_H
#include "upb/def.h"
#include "upb/table.int.h"
#include "upb/refcounted.h"
#ifdef __cplusplus
namespace upb {
class BufferHandle;
class BytesHandler;
class HandlerAttributes;
class Handlers;
template <class T> class Handler;
template <class T> struct CanonicalType;
} /* namespace upb */
#endif
UPB_DECLARE_TYPE(upb::BufferHandle, upb_bufhandle)
UPB_DECLARE_TYPE(upb::BytesHandler, upb_byteshandler)
UPB_DECLARE_TYPE(upb::HandlerAttributes, upb_handlerattr)
UPB_DECLARE_DERIVED_TYPE(upb::Handlers, upb::RefCounted,
upb_handlers, upb_refcounted)
/* The maximum depth that the handler graph can have. This is a resource limit
* for the C stack since we sometimes need to recursively traverse the graph.
* Cycles are ok; the traversal will stop when it detects a cycle, but we must
* hit the cycle before the maximum depth is reached.
*
* If having a single static limit is too inflexible, we can add another variant
* of Handlers::Freeze that allows specifying this as a parameter. */
#define UPB_MAX_HANDLER_DEPTH 64
/* All the different types of handlers that can be registered.
* Only needed for the advanced functions in upb::Handlers. */
typedef enum {
UPB_HANDLER_INT32,
UPB_HANDLER_INT64,
UPB_HANDLER_UINT32,
UPB_HANDLER_UINT64,
UPB_HANDLER_FLOAT,
UPB_HANDLER_DOUBLE,
UPB_HANDLER_BOOL,
UPB_HANDLER_STARTSTR,
UPB_HANDLER_STRING,
UPB_HANDLER_ENDSTR,
UPB_HANDLER_STARTSUBMSG,
UPB_HANDLER_ENDSUBMSG,
UPB_HANDLER_STARTSEQ,
UPB_HANDLER_ENDSEQ
} upb_handlertype_t;
#define UPB_HANDLER_MAX (UPB_HANDLER_ENDSEQ+1)
#define UPB_BREAK NULL
/* A convenient definition for when no closure is needed. */
extern char _upb_noclosure;
#define UPB_NO_CLOSURE &_upb_noclosure
/* A selector refers to a specific field handler in the Handlers object
* (for example: the STARTSUBMSG handler for field "field15"). */
typedef int32_t upb_selector_t;
UPB_BEGIN_EXTERN_C
/* Forward-declares for C inline accessors. We need to declare these here
* so we can "friend" them in the class declarations in C++. */
UPB_INLINE upb_func *upb_handlers_gethandler(const upb_handlers *h,
upb_selector_t s);
UPB_INLINE const void *upb_handlerattr_handlerdata(const upb_handlerattr *attr);
UPB_INLINE const void *upb_handlers_gethandlerdata(const upb_handlers *h,
upb_selector_t s);
UPB_INLINE void upb_bufhandle_init(upb_bufhandle *h);
UPB_INLINE void upb_bufhandle_setobj(upb_bufhandle *h, const void *obj,
const void *type);
UPB_INLINE void upb_bufhandle_setbuf(upb_bufhandle *h, const char *buf,
size_t ofs);
UPB_INLINE const void *upb_bufhandle_obj(const upb_bufhandle *h);
UPB_INLINE const void *upb_bufhandle_objtype(const upb_bufhandle *h);
UPB_INLINE const char *upb_bufhandle_buf(const upb_bufhandle *h);
UPB_END_EXTERN_C
/* Static selectors for upb::Handlers. */
#define UPB_STARTMSG_SELECTOR 0
#define UPB_ENDMSG_SELECTOR 1
#define UPB_UNKNOWN_SELECTOR 2
#define UPB_STATIC_SELECTOR_COUNT 3
/* Static selectors for upb::BytesHandler. */
#define UPB_STARTSTR_SELECTOR 0
#define UPB_STRING_SELECTOR 1
#define UPB_ENDSTR_SELECTOR 2
typedef void upb_handlerfree(void *d);
#ifdef __cplusplus
/* A set of attributes that accompanies a handler's function pointer. */
class upb::HandlerAttributes {
public:
HandlerAttributes();
~HandlerAttributes();
/* Sets the handler data that will be passed as the second parameter of the
* handler. To free this pointer when the handlers are freed, call
* Handlers::AddCleanup(). */
bool SetHandlerData(const void *handler_data);
const void* handler_data() const;
/* Use this to specify the type of the closure. This will be checked against
* all other closure types for handler that use the same closure.
* Registration will fail if this does not match all other non-NULL closure
* types. */
bool SetClosureType(const void *closure_type);
const void* closure_type() const;
/* Use this to specify the type of the returned closure. Only used for
* Start*{String,SubMessage,Sequence} handlers. This must match the closure
* type of any handlers that use it (for example, the StringBuf handler must
* match the closure returned from StartString). */
bool SetReturnClosureType(const void *return_closure_type);
const void* return_closure_type() const;
/* Set to indicate that the handler always returns "ok" (either "true" or a
* non-NULL closure). This is a hint that can allow code generators to
* generate more efficient code. */
bool SetAlwaysOk(bool always_ok);
bool always_ok() const;
private:
friend UPB_INLINE const void * ::upb_handlerattr_handlerdata(
const upb_handlerattr *attr);
#else
struct upb_handlerattr {
#endif
const void *handler_data_;
const void *closure_type_;
const void *return_closure_type_;
bool alwaysok_;
};
#define UPB_HANDLERATTR_INITIALIZER {NULL, NULL, NULL, false}
typedef struct {
upb_func *func;
/* It is wasteful to include the entire attributes here:
*
* * Some of the information is redundant (like storing the closure type
* separately for each handler that must match).
* * Some of the info is only needed prior to freeze() (like closure types).
* * alignment padding wastes a lot of space for alwaysok_.
*
* If/when the size and locality of handlers is an issue, we can optimize this
* not to store the entire attr like this. We do not expose the table's
* layout to allow this optimization in the future. */
upb_handlerattr attr;
} upb_handlers_tabent;
#ifdef __cplusplus
/* Extra information about a buffer that is passed to a StringBuf handler.
* TODO(haberman): allow the handle to be pinned so that it will outlive
* the handler invocation. */
class upb::BufferHandle {
public:
BufferHandle();
~BufferHandle();
/* The beginning of the buffer. This may be different than the pointer
* passed to a StringBuf handler because the handler may receive data
* that is from the middle or end of a larger buffer. */
const char* buffer() const;
/* The offset within the attached object where this buffer begins. Only
* meaningful if there is an attached object. */
size_t object_offset() const;
/* Note that object_offset is the offset of "buf" within the attached
* object. */
void SetBuffer(const char* buf, size_t object_offset);
/* The BufferHandle can have an "attached object", which can be used to
* tunnel through a pointer to the buffer's underlying representation. */
template <class T>
void SetAttachedObject(const T* obj);
/* Returns NULL if the attached object is not of this type. */
template <class T>
const T* GetAttachedObject() const;
private:
friend UPB_INLINE void ::upb_bufhandle_init(upb_bufhandle *h);
friend UPB_INLINE void ::upb_bufhandle_setobj(upb_bufhandle *h,
const void *obj,
const void *type);
friend UPB_INLINE void ::upb_bufhandle_setbuf(upb_bufhandle *h,
const char *buf, size_t ofs);
friend UPB_INLINE const void* ::upb_bufhandle_obj(const upb_bufhandle *h);
friend UPB_INLINE const void* ::upb_bufhandle_objtype(
const upb_bufhandle *h);
friend UPB_INLINE const char* ::upb_bufhandle_buf(const upb_bufhandle *h);
#else
struct upb_bufhandle {
#endif
const char *buf_;
const void *obj_;
const void *objtype_;
size_t objofs_;
};
#ifdef __cplusplus
/* A upb::Handlers object represents the set of handlers associated with a
* message in the graph of messages. You can think of it as a big virtual
* table with functions corresponding to all the events that can fire while
* parsing or visiting a message of a specific type.
*
* Any handlers that are not set behave as if they had successfully consumed
* the value. Any unset Start* handlers will propagate their closure to the
* inner frame.
*
* The easiest way to create the *Handler objects needed by the Set* methods is
* with the UpbBind() and UpbMakeHandler() macros; see below. */
class upb::Handlers {
public:
typedef upb_selector_t Selector;
typedef upb_handlertype_t Type;
typedef Handler<void *(*)(void *, const void *)> StartFieldHandler;
typedef Handler<bool (*)(void *, const void *)> EndFieldHandler;
typedef Handler<bool (*)(void *, const void *)> StartMessageHandler;
typedef Handler<bool (*)(void *, const void *, Status*)> EndMessageHandler;
typedef Handler<void *(*)(void *, const void *, size_t)> StartStringHandler;
typedef Handler<size_t (*)(void *, const void *, const char *, size_t,
const BufferHandle *)> StringHandler;
template <class T> struct ValueHandler {
typedef Handler<bool(*)(void *, const void *, T)> H;
};
typedef ValueHandler<int32_t>::H Int32Handler;
typedef ValueHandler<int64_t>::H Int64Handler;
typedef ValueHandler<uint32_t>::H UInt32Handler;
typedef ValueHandler<uint64_t>::H UInt64Handler;
typedef ValueHandler<float>::H FloatHandler;
typedef ValueHandler<double>::H DoubleHandler;
typedef ValueHandler<bool>::H BoolHandler;
/* Any function pointer can be converted to this and converted back to its
* correct type. */
typedef void GenericFunction();
typedef void HandlersCallback(const void *closure, upb_handlers *h);
/* Returns a new handlers object for the given frozen msgdef.
* Returns NULL if memory allocation failed. */
static reffed_ptr<Handlers> New(const MessageDef *m);
/* Convenience function for registering a graph of handlers that mirrors the
* graph of msgdefs for some message. For "m" and all its children a new set
* of handlers will be created and the given callback will be invoked,
* allowing the client to register handlers for this message. Note that any
* subhandlers set by the callback will be overwritten. */
static reffed_ptr<const Handlers> NewFrozen(const MessageDef *m,
HandlersCallback *callback,
const void *closure);
/* Functionality from upb::RefCounted. */
UPB_REFCOUNTED_CPPMETHODS
/* All handler registration functions return bool to indicate success or
* failure; details about failures are stored in this status object. If a
* failure does occur, it must be cleared before the Handlers are frozen,
* otherwise the freeze() operation will fail. The functions may *only* be
* used while the Handlers are mutable. */
const Status* status();
void ClearError();
/* Call to freeze these Handlers. Requires that any SubHandlers are already
* frozen. For cycles, you must use the static version below and freeze the
* whole graph at once. */
bool Freeze(Status* s);
/* Freezes the given set of handlers. You may not freeze a handler without
* also freezing any handlers they point to. */
static bool Freeze(Handlers*const* handlers, int n, Status* s);
static bool Freeze(const std::vector<Handlers*>& handlers, Status* s);
/* Returns the msgdef associated with this handlers object. */
const MessageDef* message_def() const;
/* Adds the given pointer and function to the list of cleanup functions that
* will be run when these handlers are freed. If this pointer has previously
* been registered, the function returns false and does nothing. */
bool AddCleanup(void *ptr, upb_handlerfree *cleanup);
/* Sets the startmsg handler for the message, which is defined as follows:
*
* bool startmsg(MyType* closure) {
* // Called when the message begins. Returns true if processing should
* // continue.
* return true;
* }
*/
bool SetStartMessageHandler(const StartMessageHandler& handler);
/* Sets the endmsg handler for the message, which is defined as follows:
*
* bool endmsg(MyType* closure, upb_status *status) {
* // Called when processing of this message ends, whether in success or
* // failure. "status" indicates the final status of processing, and
* // can also be modified in-place to update the final status.
* }
*/
bool SetEndMessageHandler(const EndMessageHandler& handler);
/* Sets the value handler for the given field, which is defined as follows
* (this is for an int32 field; other field types will pass their native
* C/C++ type for "val"):
*
* bool OnValue(MyClosure* c, const MyHandlerData* d, int32_t val) {
* // Called when the field's value is encountered. "d" contains
* // whatever data was bound to this field when it was registered.
* // Returns true if processing should continue.
* return true;
* }
*
* handers->SetInt32Handler(f, UpbBind(OnValue, new MyHandlerData(...)));
*
* The value type must exactly match f->type().
* For example, a handler that takes an int32_t parameter may only be used for
* fields of type UPB_TYPE_INT32 and UPB_TYPE_ENUM.
*
* Returns false if the handler failed to register; in this case the cleanup
* handler (if any) will be called immediately.
*/
bool SetInt32Handler (const FieldDef* f, const Int32Handler& h);
bool SetInt64Handler (const FieldDef* f, const Int64Handler& h);
bool SetUInt32Handler(const FieldDef* f, const UInt32Handler& h);
bool SetUInt64Handler(const FieldDef* f, const UInt64Handler& h);
bool SetFloatHandler (const FieldDef* f, const FloatHandler& h);
bool SetDoubleHandler(const FieldDef* f, const DoubleHandler& h);
bool SetBoolHandler (const FieldDef* f, const BoolHandler& h);
/* Like the previous, but templated on the type on the value (ie. int32).
* This is mostly useful to call from other templates. To call this you must
* specify the template parameter explicitly, ie:
* h->SetValueHandler<T>(f, UpbBind(MyHandler<T>, MyData)); */
template <class T>
bool SetValueHandler(
const FieldDef *f,
const typename ValueHandler<typename CanonicalType<T>::Type>::H& handler);
/* Sets handlers for a string field, which are defined as follows:
*
* MySubClosure* startstr(MyClosure* c, const MyHandlerData* d,
* size_t size_hint) {
* // Called when a string value begins. The return value indicates the
* // closure for the string. "size_hint" indicates the size of the
* // string if it is known, however if the string is length-delimited
* // and the end-of-string is not available size_hint will be zero.
* // This case is indistinguishable from the case where the size is
* // known to be zero.
* //
* // TODO(haberman): is it important to distinguish these cases?
* // If we had ssize_t as a type we could make -1 "unknown", but
* // ssize_t is POSIX (not ANSI) and therefore less portable.
* // In practice I suspect it won't be important to distinguish.
* return closure;
* }
*
* size_t str(MyClosure* closure, const MyHandlerData* d,
* const char *str, size_t len) {
* // Called for each buffer of string data; the multiple physical buffers
* // are all part of the same logical string. The return value indicates
* // how many bytes were consumed. If this number is less than "len",
* // this will also indicate that processing should be halted for now,
* // like returning false or UPB_BREAK from any other callback. If
* // number is greater than "len", the excess bytes will be skipped over
* // and not passed to the callback.
* return len;
* }
*
* bool endstr(MyClosure* c, const MyHandlerData* d) {
* // Called when a string value ends. Return value indicates whether
* // processing should continue.
* return true;
* }
*/
bool SetStartStringHandler(const FieldDef* f, const StartStringHandler& h);
bool SetStringHandler(const FieldDef* f, const StringHandler& h);
bool SetEndStringHandler(const FieldDef* f, const EndFieldHandler& h);
/* Sets the startseq handler, which is defined as follows:
*
* MySubClosure *startseq(MyClosure* c, const MyHandlerData* d) {
* // Called when a sequence (repeated field) begins. The returned
* // pointer indicates the closure for the sequence (or UPB_BREAK
* // to interrupt processing).
* return closure;
* }
*
* h->SetStartSequenceHandler(f, UpbBind(startseq, new MyHandlerData(...)));
*
* Returns "false" if "f" does not belong to this message or is not a
* repeated field.
*/
bool SetStartSequenceHandler(const FieldDef* f, const StartFieldHandler& h);
/* Sets the startsubmsg handler for the given field, which is defined as
* follows:
*
* MySubClosure* startsubmsg(MyClosure* c, const MyHandlerData* d) {
* // Called when a submessage begins. The returned pointer indicates the
* // closure for the sequence (or UPB_BREAK to interrupt processing).
* return closure;
* }
*
* h->SetStartSubMessageHandler(f, UpbBind(startsubmsg,
* new MyHandlerData(...)));
*
* Returns "false" if "f" does not belong to this message or is not a
* submessage/group field.
*/
bool SetStartSubMessageHandler(const FieldDef* f, const StartFieldHandler& h);
/* Sets the endsubmsg handler for the given field, which is defined as
* follows:
*
* bool endsubmsg(MyClosure* c, const MyHandlerData* d) {
* // Called when a submessage ends. Returns true to continue processing.
* return true;
* }
*
* Returns "false" if "f" does not belong to this message or is not a
* submessage/group field.
*/
bool SetEndSubMessageHandler(const FieldDef *f, const EndFieldHandler &h);
/* Starts the endsubseq handler for the given field, which is defined as
* follows:
*
* bool endseq(MyClosure* c, const MyHandlerData* d) {
* // Called when a sequence ends. Returns true continue processing.
* return true;
* }
*
* Returns "false" if "f" does not belong to this message or is not a
* repeated field.
*/
bool SetEndSequenceHandler(const FieldDef* f, const EndFieldHandler& h);
/* Sets or gets the object that specifies handlers for the given field, which
* must be a submessage or group. Returns NULL if no handlers are set. */
bool SetSubHandlers(const FieldDef* f, const Handlers* sub);
const Handlers* GetSubHandlers(const FieldDef* f) const;
/* Equivalent to GetSubHandlers, but takes the STARTSUBMSG selector for the
* field. */
const Handlers* GetSubHandlers(Selector startsubmsg) const;
/* A selector refers to a specific field handler in the Handlers object
* (for example: the STARTSUBMSG handler for field "field15").
* On success, returns true and stores the selector in "s".
* If the FieldDef or Type are invalid, returns false.
* The returned selector is ONLY valid for Handlers whose MessageDef
* contains this FieldDef. */
static bool GetSelector(const FieldDef* f, Type type, Selector* s);
/* Given a START selector of any kind, returns the corresponding END selector. */
static Selector GetEndSelector(Selector start_selector);
/* Returns the function pointer for this handler. It is the client's
* responsibility to cast to the correct function type before calling it. */
GenericFunction* GetHandler(Selector selector);
/* Sets the given attributes to the attributes for this selector. */
bool GetAttributes(Selector selector, HandlerAttributes* attr);
/* Returns the handler data that was registered with this handler. */
const void* GetHandlerData(Selector selector);
/* Could add any of the following functions as-needed, with some minor
* implementation changes:
*
* const FieldDef* GetFieldDef(Selector selector);
* static bool IsSequence(Selector selector); */
private:
UPB_DISALLOW_POD_OPS(Handlers, upb::Handlers)
friend UPB_INLINE GenericFunction *::upb_handlers_gethandler(
const upb_handlers *h, upb_selector_t s);
friend UPB_INLINE const void *::upb_handlers_gethandlerdata(
const upb_handlers *h, upb_selector_t s);
#else
struct upb_handlers {
#endif
upb_refcounted base;
const upb_msgdef *msg;
const upb_handlers **sub;
const void *top_closure_type;
upb_inttable cleanup_;
upb_status status_; /* Used only when mutable. */
upb_handlers_tabent table[1]; /* Dynamically-sized field handler array. */
};
#ifdef __cplusplus
namespace upb {
/* Convenience macros for creating a Handler object that is wrapped with a
* type-safe wrapper function that converts the "void*" parameters/returns
* of the underlying C API into nice C++ function.
*
* Sample usage:
* void OnValue1(MyClosure* c, const MyHandlerData* d, int32_t val) {
* // do stuff ...
* }
*
* // Handler that doesn't need any data bound to it.
* void OnValue2(MyClosure* c, int32_t val) {
* // do stuff ...
* }
*
* // Handler that returns bool so it can return failure if necessary.
* bool OnValue3(MyClosure* c, int32_t val) {
* // do stuff ...
* return ok;
* }
*
* // Member function handler.
* class MyClosure {
* public:
* void OnValue(int32_t val) {
* // do stuff ...
* }
* };
*
* // Takes ownership of the MyHandlerData.
* handlers->SetInt32Handler(f1, UpbBind(OnValue1, new MyHandlerData(...)));
* handlers->SetInt32Handler(f2, UpbMakeHandler(OnValue2));
* handlers->SetInt32Handler(f1, UpbMakeHandler(OnValue3));
* handlers->SetInt32Handler(f2, UpbMakeHandler(&MyClosure::OnValue));
*/
#ifdef UPB_CXX11
/* In C++11, the "template" disambiguator can appear even outside templates,
* so all calls can safely use this pair of macros. */
#define UpbMakeHandler(f) upb::MatchFunc(f).template GetFunc<f>()
/* We have to be careful to only evaluate "d" once. */
#define UpbBind(f, d) upb::MatchFunc(f).template GetFunc<f>((d))
#else
/* Prior to C++11, the "template" disambiguator may only appear inside a
* template, so the regular macro must not use "template" */
#define UpbMakeHandler(f) upb::MatchFunc(f).GetFunc<f>()
#define UpbBind(f, d) upb::MatchFunc(f).GetFunc<f>((d))
#endif /* UPB_CXX11 */
/* This macro must be used in C++98 for calls from inside a template. But we
* define this variant in all cases; code that wants to be compatible with both
* C++98 and C++11 should always use this macro when calling from a template. */
#define UpbMakeHandlerT(f) upb::MatchFunc(f).template GetFunc<f>()
/* We have to be careful to only evaluate "d" once. */
#define UpbBindT(f, d) upb::MatchFunc(f).template GetFunc<f>((d))
/* Handler: a struct that contains the (handler, data, deleter) tuple that is
* used to register all handlers. Users can Make() these directly but it's
* more convenient to use the UpbMakeHandler/UpbBind macros above. */
template <class T> class Handler {
public:
/* The underlying, handler function signature that upb uses internally. */
typedef T FuncPtr;
/* Intentionally implicit. */
template <class F> Handler(F func);
~Handler();
private:
void AddCleanup(Handlers* h) const {
if (cleanup_func_) {
bool ok = h->AddCleanup(cleanup_data_, cleanup_func_);
UPB_ASSERT(ok);
}
}
UPB_DISALLOW_COPY_AND_ASSIGN(Handler)
friend class Handlers;
FuncPtr handler_;
mutable HandlerAttributes attr_;
mutable bool registered_;
void *cleanup_data_;
upb_handlerfree *cleanup_func_;
};
} /* namespace upb */
#endif /* __cplusplus */
UPB_BEGIN_EXTERN_C
/* Native C API. */
/* Handler function typedefs. */
typedef bool upb_unknown_handlerfunc(void *c, const void *hd, const char *buf,
size_t n);
typedef bool upb_startmsg_handlerfunc(void *c, const void*);
typedef bool upb_endmsg_handlerfunc(void *c, const void *, upb_status *status);
typedef void* upb_startfield_handlerfunc(void *c, const void *hd);
typedef bool upb_endfield_handlerfunc(void *c, const void *hd);
typedef bool upb_int32_handlerfunc(void *c, const void *hd, int32_t val);
typedef bool upb_int64_handlerfunc(void *c, const void *hd, int64_t val);
typedef bool upb_uint32_handlerfunc(void *c, const void *hd, uint32_t val);
typedef bool upb_uint64_handlerfunc(void *c, const void *hd, uint64_t val);
typedef bool upb_float_handlerfunc(void *c, const void *hd, float val);
typedef bool upb_double_handlerfunc(void *c, const void *hd, double val);
typedef bool upb_bool_handlerfunc(void *c, const void *hd, bool val);
typedef void *upb_startstr_handlerfunc(void *c, const void *hd,
size_t size_hint);
typedef size_t upb_string_handlerfunc(void *c, const void *hd, const char *buf,
size_t n, const upb_bufhandle* handle);
/* upb_bufhandle */
size_t upb_bufhandle_objofs(const upb_bufhandle *h);
/* upb_handlerattr */
void upb_handlerattr_init(upb_handlerattr *attr);
void upb_handlerattr_uninit(upb_handlerattr *attr);
bool upb_handlerattr_sethandlerdata(upb_handlerattr *attr, const void *hd);
bool upb_handlerattr_setclosuretype(upb_handlerattr *attr, const void *type);
const void *upb_handlerattr_closuretype(const upb_handlerattr *attr);
bool upb_handlerattr_setreturnclosuretype(upb_handlerattr *attr,
const void *type);
const void *upb_handlerattr_returnclosuretype(const upb_handlerattr *attr);
bool upb_handlerattr_setalwaysok(upb_handlerattr *attr, bool alwaysok);
bool upb_handlerattr_alwaysok(const upb_handlerattr *attr);
UPB_INLINE const void *upb_handlerattr_handlerdata(
const upb_handlerattr *attr) {
return attr->handler_data_;
}
/* upb_handlers */
typedef void upb_handlers_callback(const void *closure, upb_handlers *h);
upb_handlers *upb_handlers_new(const upb_msgdef *m,
const void *owner);
const upb_handlers *upb_handlers_newfrozen(const upb_msgdef *m,
const void *owner,
upb_handlers_callback *callback,
const void *closure);
/* Include refcounted methods like upb_handlers_ref(). */
UPB_REFCOUNTED_CMETHODS(upb_handlers, upb_handlers_upcast)
const upb_status *upb_handlers_status(upb_handlers *h);
void upb_handlers_clearerr(upb_handlers *h);
const upb_msgdef *upb_handlers_msgdef(const upb_handlers *h);
bool upb_handlers_addcleanup(upb_handlers *h, void *p, upb_handlerfree *hfree);
bool upb_handlers_setunknown(upb_handlers *h, upb_unknown_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setstartmsg(upb_handlers *h, upb_startmsg_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setendmsg(upb_handlers *h, upb_endmsg_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setint32(upb_handlers *h, const upb_fielddef *f,
upb_int32_handlerfunc *func, upb_handlerattr *attr);
bool upb_handlers_setint64(upb_handlers *h, const upb_fielddef *f,
upb_int64_handlerfunc *func, upb_handlerattr *attr);
bool upb_handlers_setuint32(upb_handlers *h, const upb_fielddef *f,
upb_uint32_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setuint64(upb_handlers *h, const upb_fielddef *f,
upb_uint64_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setfloat(upb_handlers *h, const upb_fielddef *f,
upb_float_handlerfunc *func, upb_handlerattr *attr);
bool upb_handlers_setdouble(upb_handlers *h, const upb_fielddef *f,
upb_double_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setbool(upb_handlers *h, const upb_fielddef *f,
upb_bool_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setstartstr(upb_handlers *h, const upb_fielddef *f,
upb_startstr_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setstring(upb_handlers *h, const upb_fielddef *f,
upb_string_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setendstr(upb_handlers *h, const upb_fielddef *f,
upb_endfield_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setstartseq(upb_handlers *h, const upb_fielddef *f,
upb_startfield_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setstartsubmsg(upb_handlers *h, const upb_fielddef *f,
upb_startfield_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setendsubmsg(upb_handlers *h, const upb_fielddef *f,
upb_endfield_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setendseq(upb_handlers *h, const upb_fielddef *f,
upb_endfield_handlerfunc *func,
upb_handlerattr *attr);
bool upb_handlers_setsubhandlers(upb_handlers *h, const upb_fielddef *f,
const upb_handlers *sub);
const upb_handlers *upb_handlers_getsubhandlers(const upb_handlers *h,
const upb_fielddef *f);
const upb_handlers *upb_handlers_getsubhandlers_sel(const upb_handlers *h,
upb_selector_t sel);
UPB_INLINE upb_func *upb_handlers_gethandler(const upb_handlers *h,
upb_selector_t s) {
return (upb_func *)h->table[s].func;
}
bool upb_handlers_getattr(const upb_handlers *h, upb_selector_t s,
upb_handlerattr *attr);
UPB_INLINE const void *upb_handlers_gethandlerdata(const upb_handlers *h,
upb_selector_t s) {
return upb_handlerattr_handlerdata(&h->table[s].attr);
}
#ifdef __cplusplus
/* Handler types for single fields.
* Right now we only have one for TYPE_BYTES but ones for other types
* should follow.
*
* These follow the same handlers protocol for fields of a message. */
class upb::BytesHandler {
public:
BytesHandler();
~BytesHandler();
#else
struct upb_byteshandler {
#endif
upb_handlers_tabent table[3];
};
void upb_byteshandler_init(upb_byteshandler *h);
/* Caller must ensure that "d" outlives the handlers.
* TODO(haberman): should this have a "freeze" operation? It's not necessary
* for memory management, but could be useful to force immutability and provide
* a convenient moment to verify that all registration succeeded. */
bool upb_byteshandler_setstartstr(upb_byteshandler *h,
upb_startstr_handlerfunc *func, void *d);
bool upb_byteshandler_setstring(upb_byteshandler *h,
upb_string_handlerfunc *func, void *d);
bool upb_byteshandler_setendstr(upb_byteshandler *h,
upb_endfield_handlerfunc *func, void *d);
/* "Static" methods */
bool upb_handlers_freeze(upb_handlers *const *handlers, int n, upb_status *s);
upb_handlertype_t upb_handlers_getprimitivehandlertype(const upb_fielddef *f);
bool upb_handlers_getselector(const upb_fielddef *f, upb_handlertype_t type,
upb_selector_t *s);
UPB_INLINE upb_selector_t upb_handlers_getendselector(upb_selector_t start) {
return start + 1;
}
/* Internal-only. */
uint32_t upb_handlers_selectorbaseoffset(const upb_fielddef *f);
uint32_t upb_handlers_selectorcount(const upb_fielddef *f);
/** Message handlers ******************************************************************/
/* These are the handlers used internally by upb_msgfactory_getmergehandlers().
* They write scalar data to a known offset from the message pointer.
*
* These would be trivial for anyone to implement themselves, but it's better
* to use these because some JITs will recognize and specialize these instead
* of actually calling the function. */
/* Sets a handler for the given primitive field that will write the data at the
* given offset. If hasbit > 0, also sets a hasbit at the given bit offset
* (addressing each byte low to high). */
bool upb_msg_setscalarhandler(upb_handlers *h,
const upb_fielddef *f,
size_t offset,
int32_t hasbit);
/* If the given handler is a msghandlers_primitive field, returns true and sets
* *type, *offset and *hasbit. Otherwise returns false. */
bool upb_msg_getscalarhandlerdata(const upb_handlers *h,
upb_selector_t s,
upb_fieldtype_t *type,
size_t *offset,
int32_t *hasbit);
UPB_END_EXTERN_C
#include "upb/handlers-inl.h"
#endif /* UPB_HANDLERS_H */