Protocol Buffers - Google's data interchange format (grpc依赖)
https://developers.google.com/protocol-buffers/
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836 lines
28 KiB
836 lines
28 KiB
/* |
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* Copyright (c) 2009-2021, Google LLC |
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* All rights reserved. |
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* |
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* Redistribution and use in source and binary forms, with or without |
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* modification, are permitted provided that the following conditions are met: |
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* * Redistributions of source code must retain the above copyright |
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* notice, this list of conditions and the following disclaimer. |
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* * Redistributions in binary form must reproduce the above copyright |
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* notice, this list of conditions and the following disclaimer in the |
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* documentation and/or other materials provided with the distribution. |
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* * Neither the name of Google LLC nor the |
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* names of its contributors may be used to endorse or promote products |
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* derived from this software without specific prior written permission. |
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* |
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* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" |
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* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE |
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE |
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* ARE DISCLAIMED. IN NO EVENT SHALL Google LLC BE LIABLE FOR ANY DIRECT, |
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* INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES |
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* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; |
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* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND |
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* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
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* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS |
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* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
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*/ |
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/* |
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** Our memory representation for parsing tables and messages themselves. |
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** Functions in this file are used by generated code and possibly reflection. |
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** |
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** The definitions in this file are internal to upb. |
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**/ |
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#ifndef UPB_MSG_INT_H_ |
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#define UPB_MSG_INT_H_ |
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#include <stdint.h> |
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#include <stdlib.h> |
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#include <string.h> |
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#include "upb/msg.h" |
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#include "upb/table_internal.h" |
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#include "upb/upb.h" |
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/* Must be last. */ |
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#include "upb/port_def.inc" |
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#ifdef __cplusplus |
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extern "C" { |
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#endif |
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/** upb_*Int* conversion routines ********************************************/ |
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UPB_INLINE int32_t _upb_Int32_FromI(int v) { return (int32_t)v; } |
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UPB_INLINE int64_t _upb_Int64_FromLL(long long v) { return (int64_t)v; } |
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UPB_INLINE uint32_t _upb_UInt32_FromU(unsigned v) { return (uint32_t)v; } |
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UPB_INLINE uint64_t _upb_UInt64_FromULL(unsigned long long v) { |
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return (uint64_t)v; |
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} |
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/** upb_MiniTable *************************************************************/ |
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/* upb_MiniTable represents the memory layout of a given upb_MessageDef. The |
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* members are public so generated code can initialize them, but users MUST NOT |
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* read or write any of its members. */ |
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typedef struct { |
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uint32_t number; |
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uint16_t offset; |
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int16_t presence; // If >0, hasbit_index. If <0, ~oneof_index |
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uint16_t submsg_index; // kUpb_NoSub if descriptortype != MESSAGE/GROUP/ENUM |
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uint8_t descriptortype; |
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uint8_t mode; /* upb_FieldMode | upb_LabelFlags | |
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(upb_FieldRep << kUpb_FieldRep_Shift) */ |
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} upb_MiniTable_Field; |
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#define kUpb_NoSub ((uint16_t)-1) |
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typedef enum { |
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kUpb_FieldMode_Map = 0, |
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kUpb_FieldMode_Array = 1, |
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kUpb_FieldMode_Scalar = 2, |
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} upb_FieldMode; |
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// Mask to isolate the upb_FieldMode from field.mode. |
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#define kUpb_FieldMode_Mask 3 |
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/* Extra flags on the mode field. */ |
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typedef enum { |
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kUpb_LabelFlags_IsPacked = 4, |
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kUpb_LabelFlags_IsExtension = 8, |
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} upb_LabelFlags; |
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// Note: we sort by this number when calculating layout order. |
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typedef enum { |
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kUpb_FieldRep_1Byte = 0, |
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kUpb_FieldRep_4Byte = 1, |
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kUpb_FieldRep_StringView = 2, |
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kUpb_FieldRep_Pointer = 3, |
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kUpb_FieldRep_8Byte = 4, |
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kUpb_FieldRep_Shift = 5, // Bit offset of the rep in upb_MiniTable_Field.mode |
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kUpb_FieldRep_Max = kUpb_FieldRep_8Byte, |
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} upb_FieldRep; |
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UPB_INLINE upb_FieldMode upb_FieldMode_Get(const upb_MiniTable_Field* field) { |
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return (upb_FieldMode)(field->mode & 3); |
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} |
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UPB_INLINE bool upb_IsRepeatedOrMap(const upb_MiniTable_Field* field) { |
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/* This works because upb_FieldMode has no value 3. */ |
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return !(field->mode & kUpb_FieldMode_Scalar); |
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} |
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UPB_INLINE bool upb_IsSubMessage(const upb_MiniTable_Field* field) { |
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return field->descriptortype == kUpb_FieldType_Message || |
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field->descriptortype == kUpb_FieldType_Group; |
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} |
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struct upb_Decoder; |
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struct upb_MiniTable; |
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typedef const char* _upb_FieldParser(struct upb_Decoder* d, const char* ptr, |
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upb_Message* msg, intptr_t table, |
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uint64_t hasbits, uint64_t data); |
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typedef struct { |
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uint64_t field_data; |
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_upb_FieldParser* field_parser; |
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} _upb_FastTable_Entry; |
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typedef struct { |
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const int32_t* values; // List of values <0 or >63 |
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uint64_t mask; // Bits are set for acceptable value 0 <= x < 64 |
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int value_count; |
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} upb_MiniTable_Enum; |
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typedef union { |
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const struct upb_MiniTable* submsg; |
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const upb_MiniTable_Enum* subenum; |
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} upb_MiniTable_Sub; |
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typedef enum { |
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kUpb_ExtMode_NonExtendable = 0, // Non-extendable message. |
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kUpb_ExtMode_Extendable = 1, // Normal extendable message. |
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kUpb_ExtMode_IsMessageSet = 2, // MessageSet message. |
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kUpb_ExtMode_IsMessageSet_ITEM = |
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3, // MessageSet item (temporary only, see decode.c) |
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// During table building we steal a bit to indicate that the message is a map |
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// entry. *Only* used during table building! |
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kUpb_ExtMode_IsMapEntry = 4, |
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} upb_ExtMode; |
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/* MessageSet wire format is: |
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* message MessageSet { |
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* repeated group Item = 1 { |
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* required int32 type_id = 2; |
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* required bytes message = 3; |
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* } |
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* } |
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*/ |
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typedef enum { |
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_UPB_MSGSET_ITEM = 1, |
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_UPB_MSGSET_TYPEID = 2, |
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_UPB_MSGSET_MESSAGE = 3, |
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} upb_msgext_fieldnum; |
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struct upb_MiniTable { |
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const upb_MiniTable_Sub* subs; |
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const upb_MiniTable_Field* fields; |
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/* Must be aligned to sizeof(void*). Doesn't include internal members like |
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* unknown fields, extension dict, pointer to msglayout, etc. */ |
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uint16_t size; |
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uint16_t field_count; |
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uint8_t ext; // upb_ExtMode, declared as uint8_t so sizeof(ext) == 1 |
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uint8_t dense_below; |
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uint8_t table_mask; |
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uint8_t required_count; // Required fields have the lowest hasbits. |
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/* To statically initialize the tables of variable length, we need a flexible |
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* array member, and we need to compile in gnu99 mode (constant initialization |
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* of flexible array members is a GNU extension, not in C99 unfortunately. */ |
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_upb_FastTable_Entry fasttable[]; |
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}; |
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typedef struct { |
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upb_MiniTable_Field field; |
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const upb_MiniTable* extendee; |
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upb_MiniTable_Sub sub; /* NULL unless submessage or proto2 enum */ |
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} upb_MiniTable_Extension; |
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typedef struct { |
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const upb_MiniTable** msgs; |
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const upb_MiniTable_Enum** enums; |
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const upb_MiniTable_Extension** exts; |
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int msg_count; |
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int enum_count; |
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int ext_count; |
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} upb_MiniTable_File; |
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// Computes a bitmask in which the |l->required_count| lowest bits are set, |
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// except that we skip the lowest bit (because upb never uses hasbit 0). |
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// |
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// Sample output: |
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// requiredmask(1) => 0b10 (0x2) |
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// requiredmask(5) => 0b111110 (0x3e) |
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UPB_INLINE uint64_t upb_MiniTable_requiredmask(const upb_MiniTable* l) { |
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int n = l->required_count; |
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assert(0 < n && n <= 63); |
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return ((1ULL << n) - 1) << 1; |
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} |
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/** upb_ExtensionRegistry *****************************************************/ |
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/* Adds the given extension info for message type |l| and field number |num| |
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* into the registry. Returns false if this message type and field number were |
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* already in the map, or if memory allocation fails. */ |
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bool _upb_extreg_add(upb_ExtensionRegistry* r, |
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const upb_MiniTable_Extension** e, size_t count); |
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/* Looks up the extension (if any) defined for message type |l| and field |
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* number |num|. If an extension was found, copies the field info into |*ext| |
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* and returns true. Otherwise returns false. */ |
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const upb_MiniTable_Extension* _upb_extreg_get(const upb_ExtensionRegistry* r, |
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const upb_MiniTable* l, |
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uint32_t num); |
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/** upb_Message ***************************************************************/ |
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/* Internal members of a upb_Message that track unknown fields and/or |
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* extensions. We can change this without breaking binary compatibility. We put |
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* these before the user's data. The user's upb_Message* points after the |
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* upb_Message_Internal. */ |
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typedef struct { |
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/* Total size of this structure, including the data that follows. |
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* Must be aligned to 8, which is alignof(upb_Message_Extension) */ |
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uint32_t size; |
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/* Offsets relative to the beginning of this structure. |
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* |
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* Unknown data grows forward from the beginning to unknown_end. |
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* Extension data grows backward from size to ext_begin. |
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* When the two meet, we're out of data and have to realloc. |
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* |
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* If we imagine that the final member of this struct is: |
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* char data[size - overhead]; // overhead = |
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* sizeof(upb_Message_InternalData) |
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* |
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* Then we have: |
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* unknown data: data[0 .. (unknown_end - overhead)] |
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* extensions data: data[(ext_begin - overhead) .. (size - overhead)] */ |
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uint32_t unknown_end; |
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uint32_t ext_begin; |
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/* Data follows, as if there were an array: |
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* char data[size - sizeof(upb_Message_InternalData)]; */ |
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} upb_Message_InternalData; |
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typedef struct { |
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upb_Message_InternalData* internal; |
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/* Message data follows. */ |
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} upb_Message_Internal; |
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/* Maps upb_CType -> memory size. */ |
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extern char _upb_CTypeo_size[12]; |
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UPB_INLINE size_t upb_msg_sizeof(const upb_MiniTable* l) { |
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return l->size + sizeof(upb_Message_Internal); |
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} |
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UPB_INLINE upb_Message* _upb_Message_New_inl(const upb_MiniTable* l, |
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upb_Arena* a) { |
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size_t size = upb_msg_sizeof(l); |
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void* mem = upb_Arena_Malloc(a, size); |
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upb_Message* msg; |
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if (UPB_UNLIKELY(!mem)) return NULL; |
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msg = UPB_PTR_AT(mem, sizeof(upb_Message_Internal), upb_Message); |
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memset(mem, 0, size); |
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return msg; |
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} |
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/* Creates a new messages with the given layout on the given arena. */ |
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upb_Message* _upb_Message_New(const upb_MiniTable* l, upb_Arena* a); |
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UPB_INLINE upb_Message_Internal* upb_Message_Getinternal(upb_Message* msg) { |
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ptrdiff_t size = sizeof(upb_Message_Internal); |
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return (upb_Message_Internal*)((char*)msg - size); |
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} |
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/* Clears the given message. */ |
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void _upb_Message_Clear(upb_Message* msg, const upb_MiniTable* l); |
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/* Discards the unknown fields for this message only. */ |
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void _upb_Message_DiscardUnknown_shallow(upb_Message* msg); |
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/* Adds unknown data (serialized protobuf data) to the given message. The data |
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* is copied into the message instance. */ |
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bool _upb_Message_AddUnknown(upb_Message* msg, const char* data, size_t len, |
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upb_Arena* arena); |
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/** upb_Message_Extension *****************************************************/ |
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/* The internal representation of an extension is self-describing: it contains |
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* enough information that we can serialize it to binary format without needing |
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* to look it up in a upb_ExtensionRegistry. |
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* |
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* This representation allocates 16 bytes to data on 64-bit platforms. This is |
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* rather wasteful for scalars (in the extreme case of bool, it wastes 15 |
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* bytes). We accept this because we expect messages to be the most common |
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* extension type. */ |
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typedef struct { |
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const upb_MiniTable_Extension* ext; |
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union { |
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upb_StringView str; |
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void* ptr; |
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char scalar_data[8]; |
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} data; |
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} upb_Message_Extension; |
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/* Adds the given extension data to the given message. |ext| is copied into the |
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* message instance. This logically replaces any previously-added extension with |
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* this number */ |
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upb_Message_Extension* _upb_Message_GetOrCreateExtension( |
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upb_Message* msg, const upb_MiniTable_Extension* ext, upb_Arena* arena); |
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/* Returns an array of extensions for this message. Note: the array is |
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* ordered in reverse relative to the order of creation. */ |
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const upb_Message_Extension* _upb_Message_Getexts(const upb_Message* msg, |
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size_t* count); |
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/* Returns an extension for the given field number, or NULL if no extension |
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* exists for this field number. */ |
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const upb_Message_Extension* _upb_Message_Getext( |
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const upb_Message* msg, const upb_MiniTable_Extension* ext); |
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void _upb_Message_Clearext(upb_Message* msg, |
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const upb_MiniTable_Extension* ext); |
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void _upb_Message_Clearext(upb_Message* msg, |
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const upb_MiniTable_Extension* ext); |
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/** Hasbit access *************************************************************/ |
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UPB_INLINE bool _upb_hasbit(const upb_Message* msg, size_t idx) { |
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return (*UPB_PTR_AT(msg, idx / 8, const char) & (1 << (idx % 8))) != 0; |
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} |
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UPB_INLINE void _upb_sethas(const upb_Message* msg, size_t idx) { |
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(*UPB_PTR_AT(msg, idx / 8, char)) |= (char)(1 << (idx % 8)); |
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} |
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UPB_INLINE void _upb_clearhas(const upb_Message* msg, size_t idx) { |
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(*UPB_PTR_AT(msg, idx / 8, char)) &= (char)(~(1 << (idx % 8))); |
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} |
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UPB_INLINE size_t _upb_Message_Hasidx(const upb_MiniTable_Field* f) { |
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UPB_ASSERT(f->presence > 0); |
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return f->presence; |
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} |
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UPB_INLINE bool _upb_hasbit_field(const upb_Message* msg, |
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const upb_MiniTable_Field* f) { |
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return _upb_hasbit(msg, _upb_Message_Hasidx(f)); |
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} |
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UPB_INLINE void _upb_sethas_field(const upb_Message* msg, |
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const upb_MiniTable_Field* f) { |
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_upb_sethas(msg, _upb_Message_Hasidx(f)); |
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} |
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UPB_INLINE void _upb_clearhas_field(const upb_Message* msg, |
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const upb_MiniTable_Field* f) { |
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_upb_clearhas(msg, _upb_Message_Hasidx(f)); |
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} |
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/** Oneof case access *********************************************************/ |
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UPB_INLINE uint32_t* _upb_oneofcase(upb_Message* msg, size_t case_ofs) { |
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return UPB_PTR_AT(msg, case_ofs, uint32_t); |
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} |
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UPB_INLINE uint32_t _upb_getoneofcase(const void* msg, size_t case_ofs) { |
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return *UPB_PTR_AT(msg, case_ofs, uint32_t); |
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} |
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UPB_INLINE size_t _upb_oneofcase_ofs(const upb_MiniTable_Field* f) { |
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UPB_ASSERT(f->presence < 0); |
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return ~(ptrdiff_t)f->presence; |
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} |
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UPB_INLINE uint32_t* _upb_oneofcase_field(upb_Message* msg, |
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const upb_MiniTable_Field* f) { |
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return _upb_oneofcase(msg, _upb_oneofcase_ofs(f)); |
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} |
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UPB_INLINE uint32_t _upb_getoneofcase_field(const upb_Message* msg, |
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const upb_MiniTable_Field* f) { |
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return _upb_getoneofcase(msg, _upb_oneofcase_ofs(f)); |
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} |
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UPB_INLINE bool _upb_has_submsg_nohasbit(const upb_Message* msg, size_t ofs) { |
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return *UPB_PTR_AT(msg, ofs, const upb_Message*) != NULL; |
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} |
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/** upb_Array *****************************************************************/ |
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/* Our internal representation for repeated fields. */ |
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typedef struct { |
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uintptr_t data; /* Tagged ptr: low 3 bits of ptr are lg2(elem size). */ |
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size_t len; /* Measured in elements. */ |
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size_t size; /* Measured in elements. */ |
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uint64_t junk; |
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} upb_Array; |
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UPB_INLINE const void* _upb_array_constptr(const upb_Array* arr) { |
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UPB_ASSERT((arr->data & 7) <= 4); |
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return (void*)(arr->data & ~(uintptr_t)7); |
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} |
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UPB_INLINE uintptr_t _upb_array_tagptr(void* ptr, int elem_size_lg2) { |
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UPB_ASSERT(elem_size_lg2 <= 4); |
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return (uintptr_t)ptr | elem_size_lg2; |
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} |
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UPB_INLINE void* _upb_array_ptr(upb_Array* arr) { |
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return (void*)_upb_array_constptr(arr); |
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} |
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UPB_INLINE uintptr_t _upb_tag_arrptr(void* ptr, int elem_size_lg2) { |
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UPB_ASSERT(elem_size_lg2 <= 4); |
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UPB_ASSERT(((uintptr_t)ptr & 7) == 0); |
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return (uintptr_t)ptr | (unsigned)elem_size_lg2; |
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} |
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UPB_INLINE upb_Array* _upb_Array_New(upb_Arena* a, size_t init_size, |
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int elem_size_lg2) { |
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const size_t arr_size = UPB_ALIGN_UP(sizeof(upb_Array), 8); |
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const size_t bytes = sizeof(upb_Array) + (init_size << elem_size_lg2); |
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upb_Array* arr = (upb_Array*)upb_Arena_Malloc(a, bytes); |
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if (!arr) return NULL; |
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arr->data = _upb_tag_arrptr(UPB_PTR_AT(arr, arr_size, void), elem_size_lg2); |
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arr->len = 0; |
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arr->size = init_size; |
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return arr; |
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} |
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/* Resizes the capacity of the array to be at least min_size. */ |
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bool _upb_array_realloc(upb_Array* arr, size_t min_size, upb_Arena* arena); |
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/* Fallback functions for when the accessors require a resize. */ |
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void* _upb_Array_Resize_fallback(upb_Array** arr_ptr, size_t size, |
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int elem_size_lg2, upb_Arena* arena); |
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bool _upb_Array_Append_fallback(upb_Array** arr_ptr, const void* value, |
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int elem_size_lg2, upb_Arena* arena); |
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UPB_INLINE bool _upb_array_reserve(upb_Array* arr, size_t size, |
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upb_Arena* arena) { |
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if (arr->size < size) return _upb_array_realloc(arr, size, arena); |
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return true; |
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} |
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UPB_INLINE bool _upb_Array_Resize(upb_Array* arr, size_t size, |
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upb_Arena* arena) { |
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if (!_upb_array_reserve(arr, size, arena)) return false; |
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arr->len = size; |
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return true; |
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} |
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UPB_INLINE void _upb_array_detach(const void* msg, size_t ofs) { |
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*UPB_PTR_AT(msg, ofs, upb_Array*) = NULL; |
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} |
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UPB_INLINE const void* _upb_array_accessor(const void* msg, size_t ofs, |
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size_t* size) { |
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const upb_Array* arr = *UPB_PTR_AT(msg, ofs, const upb_Array*); |
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if (arr) { |
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if (size) *size = arr->len; |
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return _upb_array_constptr(arr); |
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} else { |
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if (size) *size = 0; |
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return NULL; |
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} |
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} |
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UPB_INLINE void* _upb_array_mutable_accessor(void* msg, size_t ofs, |
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size_t* size) { |
|
upb_Array* arr = *UPB_PTR_AT(msg, ofs, upb_Array*); |
|
if (arr) { |
|
if (size) *size = arr->len; |
|
return _upb_array_ptr(arr); |
|
} else { |
|
if (size) *size = 0; |
|
return NULL; |
|
} |
|
} |
|
|
|
UPB_INLINE void* _upb_Array_Resize_accessor2(void* msg, size_t ofs, size_t size, |
|
int elem_size_lg2, |
|
upb_Arena* arena) { |
|
upb_Array** arr_ptr = UPB_PTR_AT(msg, ofs, upb_Array*); |
|
upb_Array* arr = *arr_ptr; |
|
if (!arr || arr->size < size) { |
|
return _upb_Array_Resize_fallback(arr_ptr, size, elem_size_lg2, arena); |
|
} |
|
arr->len = size; |
|
return _upb_array_ptr(arr); |
|
} |
|
|
|
UPB_INLINE bool _upb_Array_Append_accessor2(void* msg, size_t ofs, |
|
int elem_size_lg2, |
|
const void* value, |
|
upb_Arena* arena) { |
|
upb_Array** arr_ptr = UPB_PTR_AT(msg, ofs, upb_Array*); |
|
size_t elem_size = 1 << elem_size_lg2; |
|
upb_Array* arr = *arr_ptr; |
|
void* ptr; |
|
if (!arr || arr->len == arr->size) { |
|
return _upb_Array_Append_fallback(arr_ptr, value, elem_size_lg2, arena); |
|
} |
|
ptr = _upb_array_ptr(arr); |
|
memcpy(UPB_PTR_AT(ptr, arr->len * elem_size, char), value, elem_size); |
|
arr->len++; |
|
return true; |
|
} |
|
|
|
/* Used by old generated code, remove once all code has been regenerated. */ |
|
UPB_INLINE int _upb_sizelg2(upb_CType type) { |
|
switch (type) { |
|
case kUpb_CType_Bool: |
|
return 0; |
|
case kUpb_CType_Float: |
|
case kUpb_CType_Int32: |
|
case kUpb_CType_UInt32: |
|
case kUpb_CType_Enum: |
|
return 2; |
|
case kUpb_CType_Message: |
|
return UPB_SIZE(2, 3); |
|
case kUpb_CType_Double: |
|
case kUpb_CType_Int64: |
|
case kUpb_CType_UInt64: |
|
return 3; |
|
case kUpb_CType_String: |
|
case kUpb_CType_Bytes: |
|
return UPB_SIZE(3, 4); |
|
} |
|
UPB_UNREACHABLE(); |
|
} |
|
UPB_INLINE void* _upb_Array_Resize_accessor(void* msg, size_t ofs, size_t size, |
|
upb_CType type, upb_Arena* arena) { |
|
return _upb_Array_Resize_accessor2(msg, ofs, size, _upb_sizelg2(type), arena); |
|
} |
|
UPB_INLINE bool _upb_Array_Append_accessor(void* msg, size_t ofs, |
|
size_t elem_size, upb_CType type, |
|
const void* value, |
|
upb_Arena* arena) { |
|
(void)elem_size; |
|
return _upb_Array_Append_accessor2(msg, ofs, _upb_sizelg2(type), value, |
|
arena); |
|
} |
|
|
|
/** upb_Map *******************************************************************/ |
|
|
|
/* Right now we use strmaps for everything. We'll likely want to use |
|
* integer-specific maps for integer-keyed maps.*/ |
|
typedef struct { |
|
/* Size of key and val, based on the map type. Strings are represented as '0' |
|
* because they must be handled specially. */ |
|
char key_size; |
|
char val_size; |
|
|
|
upb_strtable table; |
|
} upb_Map; |
|
|
|
/* Map entries aren't actually stored, they are only used during parsing. For |
|
* parsing, it helps a lot if all map entry messages have the same layout. |
|
* The compiler and def.c must ensure that all map entries have this layout. */ |
|
typedef struct { |
|
upb_Message_Internal internal; |
|
union { |
|
upb_StringView str; /* For str/bytes. */ |
|
upb_value val; /* For all other types. */ |
|
} k; |
|
union { |
|
upb_StringView str; /* For str/bytes. */ |
|
upb_value val; /* For all other types. */ |
|
} v; |
|
} upb_MapEntry; |
|
|
|
/* Creates a new map on the given arena with this key/value type. */ |
|
upb_Map* _upb_Map_New(upb_Arena* a, size_t key_size, size_t value_size); |
|
|
|
/* Converting between internal table representation and user values. |
|
* |
|
* _upb_map_tokey() and _upb_map_fromkey() are inverses. |
|
* _upb_map_tovalue() and _upb_map_fromvalue() are inverses. |
|
* |
|
* These functions account for the fact that strings are treated differently |
|
* from other types when stored in a map. |
|
*/ |
|
|
|
UPB_INLINE upb_StringView _upb_map_tokey(const void* key, size_t size) { |
|
if (size == UPB_MAPTYPE_STRING) { |
|
return *(upb_StringView*)key; |
|
} else { |
|
return upb_StringView_FromDataAndSize((const char*)key, size); |
|
} |
|
} |
|
|
|
UPB_INLINE void _upb_map_fromkey(upb_StringView key, void* out, size_t size) { |
|
if (size == UPB_MAPTYPE_STRING) { |
|
memcpy(out, &key, sizeof(key)); |
|
} else { |
|
memcpy(out, key.data, size); |
|
} |
|
} |
|
|
|
UPB_INLINE bool _upb_map_tovalue(const void* val, size_t size, |
|
upb_value* msgval, upb_Arena* a) { |
|
if (size == UPB_MAPTYPE_STRING) { |
|
upb_StringView* strp = (upb_StringView*)upb_Arena_Malloc(a, sizeof(*strp)); |
|
if (!strp) return false; |
|
*strp = *(upb_StringView*)val; |
|
*msgval = upb_value_ptr(strp); |
|
} else { |
|
memcpy(msgval, val, size); |
|
} |
|
return true; |
|
} |
|
|
|
UPB_INLINE void _upb_map_fromvalue(upb_value val, void* out, size_t size) { |
|
if (size == UPB_MAPTYPE_STRING) { |
|
const upb_StringView* strp = (const upb_StringView*)upb_value_getptr(val); |
|
memcpy(out, strp, sizeof(upb_StringView)); |
|
} else { |
|
memcpy(out, &val, size); |
|
} |
|
} |
|
|
|
/* Map operations, shared by reflection and generated code. */ |
|
|
|
UPB_INLINE size_t _upb_Map_Size(const upb_Map* map) { |
|
return map->table.t.count; |
|
} |
|
|
|
UPB_INLINE bool _upb_Map_Get(const upb_Map* map, const void* key, |
|
size_t key_size, void* val, size_t val_size) { |
|
upb_value tabval; |
|
upb_StringView k = _upb_map_tokey(key, key_size); |
|
bool ret = upb_strtable_lookup2(&map->table, k.data, k.size, &tabval); |
|
if (ret && val) { |
|
_upb_map_fromvalue(tabval, val, val_size); |
|
} |
|
return ret; |
|
} |
|
|
|
UPB_INLINE void* _upb_map_next(const upb_Map* map, size_t* iter) { |
|
upb_strtable_iter it; |
|
it.t = &map->table; |
|
it.index = *iter; |
|
upb_strtable_next(&it); |
|
*iter = it.index; |
|
if (upb_strtable_done(&it)) return NULL; |
|
return (void*)str_tabent(&it); |
|
} |
|
|
|
typedef enum { |
|
// LINT.IfChange |
|
_kUpb_MapInsertStatus_Inserted = 0, |
|
_kUpb_MapInsertStatus_Replaced = 1, |
|
_kUpb_MapInsertStatus_OutOfMemory = 2, |
|
// LINT.ThenChange(//depot/google3/third_party/upb/upb/collections.h) |
|
} _upb_MapInsertStatus; |
|
|
|
UPB_INLINE _upb_MapInsertStatus _upb_Map_Insert(upb_Map* map, const void* key, |
|
size_t key_size, void* val, |
|
size_t val_size, upb_Arena* a) { |
|
upb_StringView strkey = _upb_map_tokey(key, key_size); |
|
upb_value tabval = {0}; |
|
if (!_upb_map_tovalue(val, val_size, &tabval, a)) { |
|
return _kUpb_MapInsertStatus_OutOfMemory; |
|
} |
|
|
|
/* TODO(haberman): add overwrite operation to minimize number of lookups. */ |
|
bool removed = |
|
upb_strtable_remove2(&map->table, strkey.data, strkey.size, NULL); |
|
if (!upb_strtable_insert(&map->table, strkey.data, strkey.size, tabval, a)) { |
|
return _kUpb_MapInsertStatus_OutOfMemory; |
|
} |
|
return removed ? _kUpb_MapInsertStatus_Replaced |
|
: _kUpb_MapInsertStatus_Inserted; |
|
} |
|
|
|
UPB_INLINE bool _upb_Map_Delete(upb_Map* map, const void* key, |
|
size_t key_size) { |
|
upb_StringView k = _upb_map_tokey(key, key_size); |
|
return upb_strtable_remove2(&map->table, k.data, k.size, NULL); |
|
} |
|
|
|
UPB_INLINE void _upb_Map_Clear(upb_Map* map) { |
|
upb_strtable_clear(&map->table); |
|
} |
|
|
|
/* Message map operations, these get the map from the message first. */ |
|
|
|
UPB_INLINE size_t _upb_msg_map_size(const upb_Message* msg, size_t ofs) { |
|
upb_Map* map = *UPB_PTR_AT(msg, ofs, upb_Map*); |
|
return map ? _upb_Map_Size(map) : 0; |
|
} |
|
|
|
UPB_INLINE bool _upb_msg_map_get(const upb_Message* msg, size_t ofs, |
|
const void* key, size_t key_size, void* val, |
|
size_t val_size) { |
|
upb_Map* map = *UPB_PTR_AT(msg, ofs, upb_Map*); |
|
if (!map) return false; |
|
return _upb_Map_Get(map, key, key_size, val, val_size); |
|
} |
|
|
|
UPB_INLINE void* _upb_msg_map_next(const upb_Message* msg, size_t ofs, |
|
size_t* iter) { |
|
upb_Map* map = *UPB_PTR_AT(msg, ofs, upb_Map*); |
|
if (!map) return NULL; |
|
return _upb_map_next(map, iter); |
|
} |
|
|
|
UPB_INLINE bool _upb_msg_map_set(upb_Message* msg, size_t ofs, const void* key, |
|
size_t key_size, void* val, size_t val_size, |
|
upb_Arena* arena) { |
|
upb_Map** map = UPB_PTR_AT(msg, ofs, upb_Map*); |
|
if (!*map) { |
|
*map = _upb_Map_New(arena, key_size, val_size); |
|
} |
|
return _upb_Map_Insert(*map, key, key_size, val, val_size, arena) != |
|
_kUpb_MapInsertStatus_OutOfMemory; |
|
} |
|
|
|
UPB_INLINE bool _upb_msg_map_delete(upb_Message* msg, size_t ofs, |
|
const void* key, size_t key_size) { |
|
upb_Map* map = *UPB_PTR_AT(msg, ofs, upb_Map*); |
|
if (!map) return false; |
|
return _upb_Map_Delete(map, key, key_size); |
|
} |
|
|
|
UPB_INLINE void _upb_msg_map_clear(upb_Message* msg, size_t ofs) { |
|
upb_Map* map = *UPB_PTR_AT(msg, ofs, upb_Map*); |
|
if (!map) return; |
|
_upb_Map_Clear(map); |
|
} |
|
|
|
/* Accessing map key/value from a pointer, used by generated code only. */ |
|
|
|
UPB_INLINE void _upb_msg_map_key(const void* msg, void* key, size_t size) { |
|
const upb_tabent* ent = (const upb_tabent*)msg; |
|
uint32_t u32len; |
|
upb_StringView k; |
|
k.data = upb_tabstr(ent->key, &u32len); |
|
k.size = u32len; |
|
_upb_map_fromkey(k, key, size); |
|
} |
|
|
|
UPB_INLINE void _upb_msg_map_value(const void* msg, void* val, size_t size) { |
|
const upb_tabent* ent = (const upb_tabent*)msg; |
|
upb_value v = {ent->val.val}; |
|
_upb_map_fromvalue(v, val, size); |
|
} |
|
|
|
UPB_INLINE void _upb_msg_map_set_value(void* msg, const void* val, |
|
size_t size) { |
|
upb_tabent* ent = (upb_tabent*)msg; |
|
/* This is like _upb_map_tovalue() except the entry already exists so we can |
|
* reuse the allocated upb_StringView for string fields. */ |
|
if (size == UPB_MAPTYPE_STRING) { |
|
upb_StringView* strp = (upb_StringView*)(uintptr_t)ent->val.val; |
|
memcpy(strp, val, sizeof(*strp)); |
|
} else { |
|
memcpy(&ent->val.val, val, size); |
|
} |
|
} |
|
|
|
/** _upb_mapsorter ************************************************************/ |
|
|
|
/* _upb_mapsorter sorts maps and provides ordered iteration over the entries. |
|
* Since maps can be recursive (map values can be messages which contain other |
|
* maps). _upb_mapsorter can contain a stack of maps. */ |
|
|
|
typedef struct { |
|
upb_tabent const** entries; |
|
int size; |
|
int cap; |
|
} _upb_mapsorter; |
|
|
|
typedef struct { |
|
int start; |
|
int pos; |
|
int end; |
|
} _upb_sortedmap; |
|
|
|
UPB_INLINE void _upb_mapsorter_init(_upb_mapsorter* s) { |
|
s->entries = NULL; |
|
s->size = 0; |
|
s->cap = 0; |
|
} |
|
|
|
UPB_INLINE void _upb_mapsorter_destroy(_upb_mapsorter* s) { |
|
if (s->entries) free(s->entries); |
|
} |
|
|
|
bool _upb_mapsorter_pushmap(_upb_mapsorter* s, upb_FieldType key_type, |
|
const upb_Map* map, _upb_sortedmap* sorted); |
|
|
|
UPB_INLINE void _upb_mapsorter_popmap(_upb_mapsorter* s, |
|
_upb_sortedmap* sorted) { |
|
s->size = sorted->start; |
|
} |
|
|
|
UPB_INLINE bool _upb_sortedmap_next(_upb_mapsorter* s, const upb_Map* map, |
|
_upb_sortedmap* sorted, upb_MapEntry* ent) { |
|
if (sorted->pos == sorted->end) return false; |
|
const upb_tabent* tabent = s->entries[sorted->pos++]; |
|
upb_StringView key = upb_tabstrview(tabent->key); |
|
_upb_map_fromkey(key, &ent->k, map->key_size); |
|
upb_value val = {tabent->val.val}; |
|
_upb_map_fromvalue(val, &ent->v, map->val_size); |
|
return true; |
|
} |
|
|
|
#ifdef __cplusplus |
|
} /* extern "C" */ |
|
#endif |
|
|
|
#include "upb/port_undef.inc" |
|
|
|
#endif /* UPB_MSG_INT_H_ */
|
|
|