Protocol Buffers - Google's data interchange format (grpc依赖)
https://developers.google.com/protocol-buffers/
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564 lines
18 KiB
564 lines
18 KiB
/* |
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** upb::Encoder |
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** |
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** Since we are implementing pure handlers (ie. without any out-of-band access |
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** to pre-computed lengths), we have to buffer all submessages before we can |
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** emit even their first byte. |
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** |
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** Not knowing the size of submessages also means we can't write a perfect |
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** zero-copy implementation, even with buffering. Lengths are stored as |
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** varints, which means that we don't know how many bytes to reserve for the |
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** length until we know what the length is. |
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** |
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** This leaves us with three main choices: |
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** |
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** 1. buffer all submessage data in a temporary buffer, then copy it exactly |
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** once into the output buffer. |
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** |
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** 2. attempt to buffer data directly into the output buffer, estimating how |
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** many bytes each length will take. When our guesses are wrong, use |
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** memmove() to grow or shrink the allotted space. |
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** |
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** 3. buffer directly into the output buffer, allocating a max length |
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** ahead-of-time for each submessage length. If we overallocated, we waste |
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** space, but no memcpy() or memmove() is required. This approach requires |
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** defining a maximum size for submessages and rejecting submessages that |
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** exceed that size. |
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** |
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** (2) and (3) have the potential to have better performance, but they are more |
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** complicated and subtle to implement: |
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** |
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** (3) requires making an arbitrary choice of the maximum message size; it |
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** wastes space when submessages are shorter than this and fails |
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** completely when they are longer. This makes it more finicky and |
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** requires configuration based on the input. It also makes it impossible |
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** to perfectly match the output of reference encoders that always use the |
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** optimal amount of space for each length. |
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** |
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** (2) requires guessing the the size upfront, and if multiple lengths are |
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** guessed wrong the minimum required number of memmove() operations may |
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** be complicated to compute correctly. Implemented properly, it may have |
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** a useful amortized or average cost, but more investigation is required |
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** to determine this and what the optimal algorithm is to achieve it. |
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** |
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** (1) makes you always pay for exactly one copy, but its implementation is |
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** the simplest and its performance is predictable. |
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** |
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** So for now, we implement (1) only. If we wish to optimize later, we should |
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** be able to do it without affecting users. |
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** |
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** The strategy is to buffer the segments of data that do *not* depend on |
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** unknown lengths in one buffer, and keep a separate buffer of segment pointers |
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** and lengths. When the top-level submessage ends, we can go beginning to end, |
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** alternating the writing of lengths with memcpy() of the rest of the data. |
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** At the top level though, no buffering is required. |
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*/ |
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#include "upb/pb/encoder.h" |
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#include "upb/pb/varint.int.h" |
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#include "upb/port_def.inc" |
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/* The output buffer is divided into segments; a segment is a string of data |
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* that is "ready to go" -- it does not need any varint lengths inserted into |
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* the middle. The seams between segments are where varints will be inserted |
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* once they are known. |
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* |
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* We also use the concept of a "run", which is a range of encoded bytes that |
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* occur at a single submessage level. Every segment contains one or more runs. |
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* |
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* A segment can span messages. Consider: |
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* |
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* .--Submessage lengths---------. |
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* | | | |
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* | V V |
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* V | |--------------- | |----------------- |
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* Submessages: | |----------------------------------------------- |
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* Top-level msg: ------------------------------------------------------------ |
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* |
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* Segments: ----- ------------------- ----------------- |
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* Runs: *---- *--------------*--- *---------------- |
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* (* marks the start) |
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* |
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* Note that the top-level menssage is not in any segment because it does not |
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* have any length preceding it. |
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* |
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* A segment is only interrupted when another length needs to be inserted. So |
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* observe how the second segment spans both the inner submessage and part of |
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* the next enclosing message. */ |
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typedef struct { |
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uint32_t msglen; /* The length to varint-encode before this segment. */ |
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uint32_t seglen; /* Length of the segment. */ |
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} upb_pb_encoder_segment; |
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struct upb_pb_encoder { |
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upb_arena *arena; |
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/* Our input and output. */ |
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upb_sink input_; |
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upb_bytessink output_; |
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/* The "subclosure" -- used as the inner closure as part of the bytessink |
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* protocol. */ |
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void *subc; |
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/* The output buffer and limit, and our current write position. "buf" |
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* initially points to "initbuf", but is dynamically allocated if we need to |
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* grow beyond the initial size. */ |
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char *buf, *ptr, *limit; |
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/* The beginning of the current run, or undefined if we are at the top |
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* level. */ |
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char *runbegin; |
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/* The list of segments we are accumulating. */ |
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upb_pb_encoder_segment *segbuf, *segptr, *seglimit; |
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/* The stack of enclosing submessages. Each entry in the stack points to the |
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* segment where this submessage's length is being accumulated. */ |
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int *stack, *top, *stacklimit; |
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/* Depth of startmsg/endmsg calls. */ |
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int depth; |
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}; |
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/* low-level buffering ********************************************************/ |
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/* Low-level functions for interacting with the output buffer. */ |
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/* TODO(haberman): handle pushback */ |
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static void putbuf(upb_pb_encoder *e, const char *buf, size_t len) { |
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size_t n = upb_bytessink_putbuf(e->output_, e->subc, buf, len, NULL); |
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UPB_ASSERT(n == len); |
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} |
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static upb_pb_encoder_segment *top(upb_pb_encoder *e) { |
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return &e->segbuf[*e->top]; |
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} |
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/* Call to ensure that at least "bytes" bytes are available for writing at |
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* e->ptr. Returns false if the bytes could not be allocated. */ |
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static bool reserve(upb_pb_encoder *e, size_t bytes) { |
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if ((size_t)(e->limit - e->ptr) < bytes) { |
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/* Grow buffer. */ |
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char *new_buf; |
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size_t needed = bytes + (e->ptr - e->buf); |
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size_t old_size = e->limit - e->buf; |
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size_t new_size = old_size; |
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while (new_size < needed) { |
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new_size *= 2; |
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} |
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new_buf = upb_arena_realloc(e->arena, e->buf, old_size, new_size); |
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if (new_buf == NULL) { |
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return false; |
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} |
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e->ptr = new_buf + (e->ptr - e->buf); |
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e->runbegin = new_buf + (e->runbegin - e->buf); |
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e->limit = new_buf + new_size; |
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e->buf = new_buf; |
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} |
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return true; |
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} |
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/* Call when "bytes" bytes have been writte at e->ptr. The caller *must* have |
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* previously called reserve() with at least this many bytes. */ |
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static void encoder_advance(upb_pb_encoder *e, size_t bytes) { |
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UPB_ASSERT((size_t)(e->limit - e->ptr) >= bytes); |
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e->ptr += bytes; |
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} |
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/* Call when all of the bytes for a handler have been written. Flushes the |
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* bytes if possible and necessary, returning false if this failed. */ |
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static bool commit(upb_pb_encoder *e) { |
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if (!e->top) { |
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/* We aren't inside a delimited region. Flush our accumulated bytes to |
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* the output. |
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* |
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* TODO(haberman): in the future we may want to delay flushing for |
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* efficiency reasons. */ |
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putbuf(e, e->buf, e->ptr - e->buf); |
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e->ptr = e->buf; |
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} |
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return true; |
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} |
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/* Writes the given bytes to the buffer, handling reserve/advance. */ |
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static bool encode_bytesval(upb_pb_encoder *e, const void *data, size_t len) { |
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if (!reserve(e, len)) { |
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return false; |
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} |
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memcpy(e->ptr, data, len); |
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encoder_advance(e, len); |
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return true; |
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} |
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/* Finish the current run by adding the run totals to the segment and message |
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* length. */ |
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static void accumulate(upb_pb_encoder *e) { |
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size_t run_len; |
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UPB_ASSERT(e->ptr >= e->runbegin); |
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run_len = e->ptr - e->runbegin; |
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e->segptr->seglen += run_len; |
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top(e)->msglen += run_len; |
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e->runbegin = e->ptr; |
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} |
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/* Call to indicate the start of delimited region for which the full length is |
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* not yet known. All data will be buffered until the length is known. |
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* Delimited regions may be nested; their lengths will all be tracked properly. */ |
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static bool start_delim(upb_pb_encoder *e) { |
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if (e->top) { |
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/* We are already buffering, advance to the next segment and push it on the |
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* stack. */ |
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accumulate(e); |
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if (++e->top == e->stacklimit) { |
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/* TODO(haberman): grow stack? */ |
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return false; |
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} |
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if (++e->segptr == e->seglimit) { |
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/* Grow segment buffer. */ |
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size_t old_size = |
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(e->seglimit - e->segbuf) * sizeof(upb_pb_encoder_segment); |
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size_t new_size = old_size * 2; |
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upb_pb_encoder_segment *new_buf = |
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upb_arena_realloc(e->arena, e->segbuf, old_size, new_size); |
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if (new_buf == NULL) { |
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return false; |
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} |
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e->segptr = new_buf + (e->segptr - e->segbuf); |
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e->seglimit = new_buf + (new_size / sizeof(upb_pb_encoder_segment)); |
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e->segbuf = new_buf; |
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} |
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} else { |
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/* We were previously at the top level, start buffering. */ |
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e->segptr = e->segbuf; |
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e->top = e->stack; |
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e->runbegin = e->ptr; |
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} |
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*e->top = (int)(e->segptr - e->segbuf); |
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e->segptr->seglen = 0; |
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e->segptr->msglen = 0; |
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return true; |
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} |
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/* Call to indicate the end of a delimited region. We now know the length of |
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* the delimited region. If we are not nested inside any other delimited |
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* regions, we can now emit all of the buffered data we accumulated. */ |
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static bool end_delim(upb_pb_encoder *e) { |
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size_t msglen; |
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accumulate(e); |
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msglen = top(e)->msglen; |
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if (e->top == e->stack) { |
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/* All lengths are now available, emit all buffered data. */ |
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char buf[UPB_PB_VARINT_MAX_LEN]; |
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upb_pb_encoder_segment *s; |
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const char *ptr = e->buf; |
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for (s = e->segbuf; s <= e->segptr; s++) { |
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size_t lenbytes = upb_vencode64(s->msglen, buf); |
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putbuf(e, buf, lenbytes); |
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putbuf(e, ptr, s->seglen); |
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ptr += s->seglen; |
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} |
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e->ptr = e->buf; |
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e->top = NULL; |
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} else { |
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/* Need to keep buffering; propagate length info into enclosing |
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* submessages. */ |
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--e->top; |
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top(e)->msglen += msglen + upb_varint_size(msglen); |
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} |
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return true; |
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} |
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/* tag_t **********************************************************************/ |
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/* A precomputed (pre-encoded) tag and length. */ |
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typedef struct { |
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uint8_t bytes; |
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char tag[7]; |
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} tag_t; |
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/* Allocates a new tag for this field, and sets it in these handlerattr. */ |
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static void new_tag(upb_handlers *h, const upb_fielddef *f, upb_wiretype_t wt, |
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upb_handlerattr *attr) { |
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uint32_t n = upb_fielddef_number(f); |
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tag_t *tag = upb_gmalloc(sizeof(tag_t)); |
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tag->bytes = upb_vencode64((n << 3) | wt, tag->tag); |
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attr->handler_data = tag; |
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upb_handlers_addcleanup(h, tag, upb_gfree); |
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} |
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static bool encode_tagval(upb_pb_encoder *e, const tag_t *tag) { |
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return encode_bytesval(e, tag->tag, tag->bytes); |
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} |
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/* encoding of wire types *****************************************************/ |
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static bool doencode_fixed64(upb_pb_encoder *e, uint64_t val) { |
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/* TODO(haberman): byte-swap for big endian. */ |
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return encode_bytesval(e, &val, sizeof(uint64_t)); |
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} |
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static bool doencode_fixed32(upb_pb_encoder *e, uint32_t val) { |
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/* TODO(haberman): byte-swap for big endian. */ |
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return encode_bytesval(e, &val, sizeof(uint32_t)); |
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} |
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static bool doencode_varint(upb_pb_encoder *e, uint64_t val) { |
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if (!reserve(e, UPB_PB_VARINT_MAX_LEN)) { |
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return false; |
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} |
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encoder_advance(e, upb_vencode64(val, e->ptr)); |
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return true; |
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} |
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static uint64_t dbl2uint64(double d) { |
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uint64_t ret; |
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memcpy(&ret, &d, sizeof(uint64_t)); |
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return ret; |
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} |
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static uint32_t flt2uint32(float d) { |
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uint32_t ret; |
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memcpy(&ret, &d, sizeof(uint32_t)); |
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return ret; |
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} |
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/* encoding of proto types ****************************************************/ |
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static bool startmsg(void *c, const void *hd) { |
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upb_pb_encoder *e = c; |
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UPB_UNUSED(hd); |
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if (e->depth++ == 0) { |
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upb_bytessink_start(e->output_, 0, &e->subc); |
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} |
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return true; |
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} |
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static bool endmsg(void *c, const void *hd, upb_status *status) { |
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upb_pb_encoder *e = c; |
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UPB_UNUSED(hd); |
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UPB_UNUSED(status); |
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if (--e->depth == 0) { |
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upb_bytessink_end(e->output_); |
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} |
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return true; |
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} |
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static void *encode_startdelimfield(void *c, const void *hd) { |
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bool ok = encode_tagval(c, hd) && commit(c) && start_delim(c); |
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return ok ? c : UPB_BREAK; |
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} |
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static bool encode_unknown(void *c, const void *hd, const char *buf, |
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size_t len) { |
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UPB_UNUSED(hd); |
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return encode_bytesval(c, buf, len) && commit(c); |
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} |
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static bool encode_enddelimfield(void *c, const void *hd) { |
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UPB_UNUSED(hd); |
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return end_delim(c); |
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} |
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static void *encode_startgroup(void *c, const void *hd) { |
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return (encode_tagval(c, hd) && commit(c)) ? c : UPB_BREAK; |
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} |
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static bool encode_endgroup(void *c, const void *hd) { |
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return encode_tagval(c, hd) && commit(c); |
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} |
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static void *encode_startstr(void *c, const void *hd, size_t size_hint) { |
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UPB_UNUSED(size_hint); |
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return encode_startdelimfield(c, hd); |
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} |
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static size_t encode_strbuf(void *c, const void *hd, const char *buf, |
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size_t len, const upb_bufhandle *h) { |
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UPB_UNUSED(hd); |
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UPB_UNUSED(h); |
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return encode_bytesval(c, buf, len) ? len : 0; |
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} |
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#define T(type, ctype, convert, encode) \ |
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static bool encode_scalar_##type(void *e, const void *hd, ctype val) { \ |
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return encode_tagval(e, hd) && encode(e, (convert)(val)) && commit(e); \ |
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} \ |
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static bool encode_packed_##type(void *e, const void *hd, ctype val) { \ |
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UPB_UNUSED(hd); \ |
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return encode(e, (convert)(val)); \ |
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} |
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T(double, double, dbl2uint64, doencode_fixed64) |
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T(float, float, flt2uint32, doencode_fixed32) |
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T(int64, int64_t, uint64_t, doencode_varint) |
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T(int32, int32_t, int64_t, doencode_varint) |
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T(fixed64, uint64_t, uint64_t, doencode_fixed64) |
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T(fixed32, uint32_t, uint32_t, doencode_fixed32) |
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T(bool, bool, bool, doencode_varint) |
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T(uint32, uint32_t, uint32_t, doencode_varint) |
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T(uint64, uint64_t, uint64_t, doencode_varint) |
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T(enum, int32_t, uint32_t, doencode_varint) |
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T(sfixed32, int32_t, uint32_t, doencode_fixed32) |
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T(sfixed64, int64_t, uint64_t, doencode_fixed64) |
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T(sint32, int32_t, upb_zzenc_32, doencode_varint) |
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T(sint64, int64_t, upb_zzenc_64, doencode_varint) |
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#undef T |
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/* code to build the handlers *************************************************/ |
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#include <stdio.h> |
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static void newhandlers_callback(const void *closure, upb_handlers *h) { |
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const upb_msgdef *m; |
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upb_msg_field_iter i; |
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UPB_UNUSED(closure); |
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upb_handlers_setstartmsg(h, startmsg, NULL); |
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upb_handlers_setendmsg(h, endmsg, NULL); |
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upb_handlers_setunknown(h, encode_unknown, NULL); |
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m = upb_handlers_msgdef(h); |
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for(upb_msg_field_begin(&i, m); |
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!upb_msg_field_done(&i); |
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upb_msg_field_next(&i)) { |
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const upb_fielddef *f = upb_msg_iter_field(&i); |
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bool packed = upb_fielddef_isseq(f) && upb_fielddef_isprimitive(f) && |
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upb_fielddef_packed(f); |
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upb_handlerattr attr = UPB_HANDLERATTR_INIT; |
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upb_wiretype_t wt = |
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packed ? UPB_WIRE_TYPE_DELIMITED |
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: upb_pb_native_wire_types[upb_fielddef_descriptortype(f)]; |
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/* Pre-encode the tag for this field. */ |
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new_tag(h, f, wt, &attr); |
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if (packed) { |
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upb_handlers_setstartseq(h, f, encode_startdelimfield, &attr); |
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upb_handlers_setendseq(h, f, encode_enddelimfield, &attr); |
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} |
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#define T(upper, lower, upbtype) \ |
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case UPB_DESCRIPTOR_TYPE_##upper: \ |
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if (packed) { \ |
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upb_handlers_set##upbtype(h, f, encode_packed_##lower, &attr); \ |
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} else { \ |
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upb_handlers_set##upbtype(h, f, encode_scalar_##lower, &attr); \ |
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} \ |
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break; |
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switch (upb_fielddef_descriptortype(f)) { |
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T(DOUBLE, double, double); |
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T(FLOAT, float, float); |
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T(INT64, int64, int64); |
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T(INT32, int32, int32); |
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T(FIXED64, fixed64, uint64); |
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T(FIXED32, fixed32, uint32); |
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T(BOOL, bool, bool); |
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T(UINT32, uint32, uint32); |
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T(UINT64, uint64, uint64); |
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T(ENUM, enum, int32); |
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T(SFIXED32, sfixed32, int32); |
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T(SFIXED64, sfixed64, int64); |
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T(SINT32, sint32, int32); |
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T(SINT64, sint64, int64); |
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case UPB_DESCRIPTOR_TYPE_STRING: |
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case UPB_DESCRIPTOR_TYPE_BYTES: |
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upb_handlers_setstartstr(h, f, encode_startstr, &attr); |
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upb_handlers_setendstr(h, f, encode_enddelimfield, &attr); |
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upb_handlers_setstring(h, f, encode_strbuf, &attr); |
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break; |
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case UPB_DESCRIPTOR_TYPE_MESSAGE: |
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upb_handlers_setstartsubmsg(h, f, encode_startdelimfield, &attr); |
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upb_handlers_setendsubmsg(h, f, encode_enddelimfield, &attr); |
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break; |
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case UPB_DESCRIPTOR_TYPE_GROUP: { |
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/* Endgroup takes a different tag (wire_type = END_GROUP). */ |
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upb_handlerattr attr2 = UPB_HANDLERATTR_INIT; |
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new_tag(h, f, UPB_WIRE_TYPE_END_GROUP, &attr2); |
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upb_handlers_setstartsubmsg(h, f, encode_startgroup, &attr); |
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upb_handlers_setendsubmsg(h, f, encode_endgroup, &attr2); |
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break; |
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} |
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} |
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#undef T |
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} |
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} |
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void upb_pb_encoder_reset(upb_pb_encoder *e) { |
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e->segptr = NULL; |
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e->top = NULL; |
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e->depth = 0; |
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} |
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/* public API *****************************************************************/ |
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upb_handlercache *upb_pb_encoder_newcache(void) { |
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return upb_handlercache_new(newhandlers_callback, NULL); |
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} |
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upb_pb_encoder *upb_pb_encoder_create(upb_arena *arena, const upb_handlers *h, |
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upb_bytessink output) { |
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const size_t initial_bufsize = 256; |
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const size_t initial_segbufsize = 16; |
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/* TODO(haberman): make this configurable. */ |
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const size_t stack_size = 64; |
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upb_pb_encoder *e = upb_arena_malloc(arena, sizeof(upb_pb_encoder)); |
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if (!e) return NULL; |
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e->buf = upb_arena_malloc(arena, initial_bufsize); |
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e->segbuf = upb_arena_malloc(arena, initial_segbufsize * sizeof(*e->segbuf)); |
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e->stack = upb_arena_malloc(arena, stack_size * sizeof(*e->stack)); |
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if (!e->buf || !e->segbuf || !e->stack) { |
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return NULL; |
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} |
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e->limit = e->buf + initial_bufsize; |
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e->seglimit = e->segbuf + initial_segbufsize; |
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e->stacklimit = e->stack + stack_size; |
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upb_pb_encoder_reset(e); |
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upb_sink_reset(&e->input_, h, e); |
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e->arena = arena; |
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e->output_ = output; |
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e->subc = output.closure; |
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e->ptr = e->buf; |
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return e; |
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} |
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upb_sink upb_pb_encoder_input(upb_pb_encoder *e) { return e->input_; }
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