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/*
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* upb - a minimalist implementation of protocol buffers.
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*
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* Copyright (c) 2010-2011 Google Inc. See LICENSE for details.
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* Author: Josh Haberman <jhaberman@gmail.com>
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*
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* Routines for reading and writing message data to an in-memory structure,
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* similar to a C struct.
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*
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* upb does not define one single message object that everyone must use.
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* Rather it defines an abstract interface for reading and writing members
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* of a message object, and all of the parsers and serializers use this
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* abstract interface. This allows upb's parsers and serializers to be used
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* regardless of what memory management scheme or synchronization model the
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* application is using.
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*
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* A standard set of accessors is provided for doing simple reads and writes at
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* a known offset into the message. These accessors should be used when
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* possible, because they are specially optimized -- for example, the JIT can
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* recognize them and emit specialized code instead of having to call the
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* function at all. The application can substitute its own accessors when the
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* standard accessors are not suitable.
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*/
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#ifndef UPB_MSG_H
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#define UPB_MSG_H
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#include <stdlib.h>
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#include "upb/def.h"
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#include "upb/handlers.h"
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#ifdef __cplusplus
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extern "C" {
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#endif
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/* upb_accessor ***************************************************************/
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// A upb_accessor is a table of function pointers for doing reads and writes
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// for one specific upb_fielddef. Each field has a separate accessor, which
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// lives in the fielddef.
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typedef bool upb_has_reader(void *m, upb_value fval);
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typedef upb_value upb_value_reader(void *m, upb_value fval);
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typedef void *upb_seqbegin_handler(void *s);
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typedef void *upb_seqnext_handler(void *s, void *iter);
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typedef upb_value upb_seqget_handler(void *iter);
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INLINE bool upb_seq_done(void *iter) { return iter == NULL; }
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typedef struct _upb_accessor_vtbl {
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// Writers. These take an fval as a parameter because the callbacks are used
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// as upb_handlers, but the fval is always the fielddef for that field.
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upb_startfield_handler *startsubmsg; // Non-repeated submsg fields.
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upb_value_handler *set; // Non-repeated scalar fields.
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upb_startfield_handler *startseq; // Repeated fields only.
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upb_startfield_handler *appendsubmsg; // Repeated submsg fields.
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upb_value_handler *append; // Repeated scalar fields.
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// TODO: expect to also need endsubmsg and endseq.
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// Readers.
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upb_has_reader *has;
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upb_value_reader *getseq;
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upb_value_reader *get;
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upb_seqbegin_handler *seqbegin;
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upb_seqnext_handler *seqnext;
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upb_seqget_handler *seqget;
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} upb_accessor_vtbl;
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// Registers handlers for writing into a message of the given type.
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upb_mhandlers *upb_accessors_reghandlers(upb_handlers *h, upb_msgdef *m);
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// Returns an stdmsg accessor for the given fielddef.
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upb_accessor_vtbl *upb_stdmsg_accessor(upb_fielddef *f);
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/* upb_msg/upb_seq ************************************************************/
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// upb_msg and upb_seq allow for generic access to a message through its
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// accessor vtable. Note that these do *not* allow you to create, destroy, or
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// take references on the objects -- these operations are specifically outside
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// the scope of what the accessors define.
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// Clears all hasbits.
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// TODO: Add a separate function for setting primitive values back to their
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// defaults (but not strings, submessages, or arrays).
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void upb_msg_clear(void *msg, upb_msgdef *md);
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INLINE void upb_msg_clearbit(void *msg, upb_fielddef *f) {
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((char*)msg)[f->hasbit / 8] &= ~(1 << (f->hasbit % 8));
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}
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// Could add a method that recursively clears submessages, strings, and
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// arrays if desired. This could be a win if you wanted to merge without
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// needing hasbits, because during parsing you would never clear submessages
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// or arrays. Also this could be desired to provide proto2 operations on
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// generated messages.
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INLINE bool upb_msg_has(void *m, upb_fielddef *f) {
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return f->accessor && f->accessor->has(m, f->fval);
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}
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// May only be called for fields that have accessors.
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INLINE upb_value upb_msg_get(void *m, upb_fielddef *f) {
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assert(f->accessor && !upb_isseq(f));
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return f->accessor->get(m, f->fval);
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}
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// May only be called for fields that have accessors.
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INLINE upb_value upb_msg_getseq(void *m, upb_fielddef *f) {
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assert(f->accessor && upb_isseq(f));
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return f->accessor->getseq(m, f->fval);
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}
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INLINE void upb_msg_set(void *m, upb_fielddef *f, upb_value val) {
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assert(f->accessor);
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f->accessor->set(m, f->fval, val);
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}
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INLINE void *upb_seq_begin(void *s, upb_fielddef *f) {
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assert(f->accessor);
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return f->accessor->seqbegin(s);
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}
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INLINE void *upb_seq_next(void *s, void *iter, upb_fielddef *f) {
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assert(f->accessor);
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assert(!upb_seq_done(iter));
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return f->accessor->seqnext(s, iter);
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}
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INLINE upb_value upb_seq_get(void *iter, upb_fielddef *f) {
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assert(f->accessor);
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assert(!upb_seq_done(iter));
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return f->accessor->seqget(iter);
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}
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/* upb_msgvisitor *************************************************************/
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// A upb_msgvisitor reads data from an in-memory structure using its accessors,
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// pushing the results to a given set of upb_handlers.
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// TODO: not yet implemented.
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typedef struct {
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upb_fhandlers *fh;
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upb_fielddef *f;
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uint16_t msgindex; // Only when upb_issubmsg(f).
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} upb_msgvisitor_field;
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typedef struct {
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upb_msgvisitor_field *fields;
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int fields_len;
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} upb_msgvisitor_msg;
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typedef struct {
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uint16_t msgindex;
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uint16_t fieldindex;
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uint32_t arrayindex; // UINT32_MAX if not an array frame.
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} upb_msgvisitor_frame;
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typedef struct {
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upb_msgvisitor_msg *messages;
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int messages_len;
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upb_dispatcher dispatcher;
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} upb_msgvisitor;
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// Initializes a msgvisitor that will push data from messages of the given
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// msgdef to the given set of handlers.
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void upb_msgvisitor_init(upb_msgvisitor *v, upb_msgdef *md, upb_handlers *h);
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void upb_msgvisitor_uninit(upb_msgvisitor *v);
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void upb_msgvisitor_reset(upb_msgvisitor *v, void *m);
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void upb_msgvisitor_visit(upb_msgvisitor *v, upb_status *status);
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/* Standard writers. **********************************************************/
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// Allocates a new stdmsg.
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void *upb_stdmsg_new(upb_msgdef *md);
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// Recursively frees any strings or submessages that the message refers to.
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void upb_stdmsg_free(void *m, upb_msgdef *md);
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void upb_stdmsg_sethas(void *_m, upb_value fval);
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// "hasbit" must be <= UPB_MAX_FIELDS. If it is <0, this field has no hasbit.
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upb_value upb_stdmsg_packfval(int16_t hasbit, uint16_t value_offset);
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upb_value upb_stdmsg_packfval_subm(int16_t hasbit, uint16_t value_offset,
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uint16_t subm_size, uint8_t subm_setbytes);
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// Value writers for every in-memory type: write the data to a known offset
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// from the closure "c" and set the hasbit (if any).
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// TODO: can we get away with having only one for int64, uint64, double, etc?
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// The main thing in the way atm is that the upb_value is strongly typed.
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// in debug mode.
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upb_flow_t upb_stdmsg_setint64(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setint32(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setuint64(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setuint32(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setdouble(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setfloat(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setbool(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setptr(void *c, upb_value fval, upb_value val);
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// Value writers for repeated fields: the closure points to a standard array
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// struct, appends the value to the end of the array, resizing with realloc()
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// if necessary.
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typedef struct {
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char *ptr;
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uint32_t len; // Number of elements present.
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uint32_t size; // Number of elements allocated.
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} upb_stdarray;
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void *upb_stdarray_append(upb_stdarray *a, size_t type_size);
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upb_flow_t upb_stdmsg_setint64_r(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setint32_r(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setuint64_r(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setuint32_r(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setdouble_r(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setfloat_r(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setbool_r(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setptr_r(void *c, upb_value fval, upb_value val);
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// Writers for C strings (NULL-terminated): we can find a char* at a known
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// offset from the closure "c". Calls realloc() on the pointer to allocate
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// the memory (TODO: investigate whether checking malloc_usable_size() would
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// be cheaper than realloc()). Also sets the hasbit, if any.
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//
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// Since the string is NULL terminated and does not store an explicit length,
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// these are not suitable for binary data that can contain NULLs.
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upb_flow_t upb_stdmsg_setcstr(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setcstr_r(void *c, upb_value fval, upb_value val);
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// Writers for length-delimited strings: we explicitly store the length, so
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// the data can contain NULLs. Stores the data using upb_stdarray
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// which is located at a known offset from the closure "c" (note that it
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// is included inline rather than pointed to). Also sets the hasbit, if any.
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upb_flow_t upb_stdmsg_setstr(void *c, upb_value fval, upb_value val);
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upb_flow_t upb_stdmsg_setstr_r(void *c, upb_value fval, upb_value val);
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// Writers for startseq and startmsg which allocate (or reuse, if possible)
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// a sub data structure (upb_stdarray or a submessage, respectively),
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// setting the hasbit. If the hasbit is already set, the existing data
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// structure is used verbatim. If the hasbit is not already set, the pointer
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// is checked for NULL. If it is NULL, a new substructure is allocated,
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// cleared, and used. If it is not NULL, the existing substructure is
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// cleared and reused.
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//
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// If there is no hasbit, we always behave as if the hasbit was not set,
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// so any existing data for this array or submessage is cleared. In most
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// cases this will be fine since each array or non-repeated submessage should
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// occur at most once in the stream. But if the client is using "concatenation
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// as merging", it will want to make sure hasbits are allocated so merges can
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// happen appropriately.
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//
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// If there was a demand for the behavior that absence of a hasbit acts as if
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// the bit was always set, we could provide that also. But Clear() would need
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// to act recursively, which is less efficient since it requires an extra pass
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// over the tree.
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upb_sflow_t upb_stdmsg_startseq(void *c, upb_value fval);
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upb_sflow_t upb_stdmsg_startsubmsg(void *c, upb_value fval);
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upb_sflow_t upb_stdmsg_startsubmsg_r(void *c, upb_value fval);
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/* Standard readers. **********************************************************/
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bool upb_stdmsg_has(void *c, upb_value fval);
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void *upb_stdmsg_seqbegin(void *c);
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upb_value upb_stdmsg_getint64(void *c, upb_value fval);
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upb_value upb_stdmsg_getint32(void *c, upb_value fval);
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upb_value upb_stdmsg_getuint64(void *c, upb_value fval);
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upb_value upb_stdmsg_getuint32(void *c, upb_value fval);
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upb_value upb_stdmsg_getdouble(void *c, upb_value fval);
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upb_value upb_stdmsg_getfloat(void *c, upb_value fval);
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upb_value upb_stdmsg_getbool(void *c, upb_value fval);
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upb_value upb_stdmsg_getptr(void *c, upb_value fval);
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void *upb_stdmsg_8byte_seqnext(void *c, void *iter);
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void *upb_stdmsg_4byte_seqnext(void *c, void *iter);
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void *upb_stdmsg_1byte_seqnext(void *c, void *iter);
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upb_value upb_stdmsg_seqgetint64(void *c);
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upb_value upb_stdmsg_seqgetint32(void *c);
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upb_value upb_stdmsg_seqgetuint64(void *c);
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upb_value upb_stdmsg_seqgetuint32(void *c);
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upb_value upb_stdmsg_seqgetdouble(void *c);
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upb_value upb_stdmsg_seqgetfloat(void *c);
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upb_value upb_stdmsg_seqgetbool(void *c);
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upb_value upb_stdmsg_seqgetptr(void *c);
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#ifdef __cplusplus
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} /* extern "C" */
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#endif
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#endif
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