/* * * Copyright 2015 gRPC authors. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * */ #include #include "src/core/ext/transport/chttp2/transport/hpack_encoder.h" #include #include /* This is here for grpc_is_binary_header * TODO(murgatroid99): Remove this */ #include #include #include #include "src/core/ext/transport/chttp2/transport/bin_encoder.h" #include "src/core/ext/transport/chttp2/transport/hpack_table.h" #include "src/core/ext/transport/chttp2/transport/varint.h" #include "src/core/lib/debug/stats.h" #include "src/core/lib/slice/slice_internal.h" #include "src/core/lib/slice/slice_string_helpers.h" #include "src/core/lib/transport/metadata.h" #include "src/core/lib/transport/static_metadata.h" #include "src/core/lib/transport/timeout_encoding.h" #define HASH_FRAGMENT_MASK (GRPC_CHTTP2_HPACKC_NUM_VALUES - 1) #define HASH_FRAGMENT_1(x) ((x)&HASH_FRAGMENT_MASK) #define HASH_FRAGMENT_2(x) \ (((x) >> GRPC_CHTTP2_HPACKC_NUM_VALUES_BITS) & HASH_FRAGMENT_MASK) #define HASH_FRAGMENT_3(x) \ (((x) >> (GRPC_CHTTP2_HPACKC_NUM_VALUES_BITS * 2)) & HASH_FRAGMENT_MASK) #define HASH_FRAGMENT_4(x) \ (((x) >> (GRPC_CHTTP2_HPACKC_NUM_VALUES_BITS * 3)) & HASH_FRAGMENT_MASK) /* if the probability of this item being seen again is < 1/x then don't add it to the table */ #define ONE_ON_ADD_PROBABILITY (GRPC_CHTTP2_HPACKC_NUM_VALUES >> 1) /* don't consider adding anything bigger than this to the hpack table */ #define MAX_DECODER_SPACE_USAGE 512 static grpc_slice_refcount terminal_slice_refcount = {nullptr, nullptr}; static const grpc_slice terminal_slice = { &terminal_slice_refcount, /* refcount */ {{nullptr, 0}} /* data.refcounted */ }; typedef struct { int is_first_frame; /* number of bytes in 'output' when we started the frame - used to calculate frame length */ size_t output_length_at_start_of_frame; /* index (in output) of the header for the current frame */ size_t header_idx; /* have we seen a regular (non-colon-prefixed) header yet? */ uint8_t seen_regular_header; /* output stream id */ uint32_t stream_id; grpc_slice_buffer* output; grpc_transport_one_way_stats* stats; /* maximum size of a frame */ size_t max_frame_size; bool use_true_binary_metadata; } framer_state; /* fills p (which is expected to be 9 bytes long) with a data frame header */ static void fill_header(uint8_t* p, uint8_t type, uint32_t id, size_t len, uint8_t flags) { GPR_ASSERT(len < 16777316); *p++ = static_cast(len >> 16); *p++ = static_cast(len >> 8); *p++ = static_cast(len); *p++ = type; *p++ = flags; *p++ = static_cast(id >> 24); *p++ = static_cast(id >> 16); *p++ = static_cast(id >> 8); *p++ = static_cast(id); } /* finish a frame - fill in the previously reserved header */ static void finish_frame(framer_state* st, int is_header_boundary, int is_last_in_stream) { uint8_t type = 0xff; type = st->is_first_frame ? GRPC_CHTTP2_FRAME_HEADER : GRPC_CHTTP2_FRAME_CONTINUATION; fill_header( GRPC_SLICE_START_PTR(st->output->slices[st->header_idx]), type, st->stream_id, st->output->length - st->output_length_at_start_of_frame, static_cast( (is_last_in_stream ? GRPC_CHTTP2_DATA_FLAG_END_STREAM : 0) | (is_header_boundary ? GRPC_CHTTP2_DATA_FLAG_END_HEADERS : 0))); st->stats->framing_bytes += 9; st->is_first_frame = 0; } /* begin a new frame: reserve off header space, remember how many bytes we'd output before beginning */ static void begin_frame(framer_state* st) { st->header_idx = grpc_slice_buffer_add_indexed(st->output, GRPC_SLICE_MALLOC(9)); st->output_length_at_start_of_frame = st->output->length; } /* make sure that the current frame is of the type desired, and has sufficient space to add at least about_to_add bytes -- finishes the current frame if needed */ static void ensure_space(framer_state* st, size_t need_bytes) { if (st->output->length - st->output_length_at_start_of_frame + need_bytes <= st->max_frame_size) { return; } finish_frame(st, 0, 0); begin_frame(st); } /* increment a filter count, halve all counts if one element reaches max */ static void inc_filter(uint8_t idx, uint32_t* sum, uint8_t* elems) { elems[idx]++; if (elems[idx] < 255) { (*sum)++; } else { int i; *sum = 0; for (i = 0; i < GRPC_CHTTP2_HPACKC_NUM_VALUES; i++) { elems[i] /= 2; (*sum) += elems[i]; } } } static void add_header_data(framer_state* st, grpc_slice slice) { size_t len = GRPC_SLICE_LENGTH(slice); size_t remaining; if (len == 0) return; remaining = st->max_frame_size + st->output_length_at_start_of_frame - st->output->length; if (len <= remaining) { st->stats->header_bytes += len; grpc_slice_buffer_add(st->output, slice); } else { st->stats->header_bytes += remaining; grpc_slice_buffer_add(st->output, grpc_slice_split_head(&slice, remaining)); finish_frame(st, 0, 0); begin_frame(st); add_header_data(st, slice); } } static uint8_t* add_tiny_header_data(framer_state* st, size_t len) { ensure_space(st, len); st->stats->header_bytes += len; return grpc_slice_buffer_tiny_add(st->output, len); } static void evict_entry(grpc_chttp2_hpack_compressor* c) { c->tail_remote_index++; GPR_ASSERT(c->tail_remote_index > 0); GPR_ASSERT(c->table_size >= c->table_elem_size[c->tail_remote_index % c->cap_table_elems]); GPR_ASSERT(c->table_elems > 0); c->table_size = static_cast( c->table_size - c->table_elem_size[c->tail_remote_index % c->cap_table_elems]); c->table_elems--; } // Reserve space in table for the new element, evict entries if needed. // Return the new index of the element. Return 0 to indicate not adding to // table. static uint32_t prepare_space_for_new_elem(grpc_chttp2_hpack_compressor* c, size_t elem_size) { uint32_t new_index = c->tail_remote_index + c->table_elems + 1; GPR_ASSERT(elem_size < 65536); if (elem_size > c->max_table_size) { while (c->table_size > 0) { evict_entry(c); } return 0; } /* Reserve space for this element in the remote table: if this overflows the current table, drop elements until it fits, matching the decompressor algorithm */ while (c->table_size + elem_size > c->max_table_size) { evict_entry(c); } GPR_ASSERT(c->table_elems < c->max_table_size); c->table_elem_size[new_index % c->cap_table_elems] = static_cast(elem_size); c->table_size = static_cast(c->table_size + elem_size); c->table_elems++; return new_index; } /* dummy function */ static void add_nothing(grpc_chttp2_hpack_compressor* c, grpc_mdelem elem, size_t elem_size) {} // Add a key to the dynamic table. Both key and value will be added to table at // the decoder. static void add_key_with_index(grpc_chttp2_hpack_compressor* c, grpc_mdelem elem, uint32_t new_index) { if (new_index == 0) { return; } uint32_t key_hash = grpc_slice_hash(GRPC_MDKEY(elem)); /* Store the key into {entries,indices}_keys */ if (grpc_slice_eq(c->entries_keys[HASH_FRAGMENT_2(key_hash)], GRPC_MDKEY(elem))) { c->indices_keys[HASH_FRAGMENT_2(key_hash)] = new_index; } else if (grpc_slice_eq(c->entries_keys[HASH_FRAGMENT_3(key_hash)], GRPC_MDKEY(elem))) { c->indices_keys[HASH_FRAGMENT_3(key_hash)] = new_index; } else if (c->entries_keys[HASH_FRAGMENT_2(key_hash)].refcount == &terminal_slice_refcount) { c->entries_keys[HASH_FRAGMENT_2(key_hash)] = grpc_slice_ref_internal(GRPC_MDKEY(elem)); c->indices_keys[HASH_FRAGMENT_2(key_hash)] = new_index; } else if (c->entries_keys[HASH_FRAGMENT_3(key_hash)].refcount == &terminal_slice_refcount) { c->entries_keys[HASH_FRAGMENT_3(key_hash)] = grpc_slice_ref_internal(GRPC_MDKEY(elem)); c->indices_keys[HASH_FRAGMENT_3(key_hash)] = new_index; } else if (c->indices_keys[HASH_FRAGMENT_2(key_hash)] < c->indices_keys[HASH_FRAGMENT_3(key_hash)]) { grpc_slice_unref_internal(c->entries_keys[HASH_FRAGMENT_2(key_hash)]); c->entries_keys[HASH_FRAGMENT_2(key_hash)] = grpc_slice_ref_internal(GRPC_MDKEY(elem)); c->indices_keys[HASH_FRAGMENT_2(key_hash)] = new_index; } else { grpc_slice_unref_internal(c->entries_keys[HASH_FRAGMENT_3(key_hash)]); c->entries_keys[HASH_FRAGMENT_3(key_hash)] = grpc_slice_ref_internal(GRPC_MDKEY(elem)); c->indices_keys[HASH_FRAGMENT_3(key_hash)] = new_index; } } /* add an element to the decoder table */ static void add_elem_with_index(grpc_chttp2_hpack_compressor* c, grpc_mdelem elem, uint32_t new_index) { if (new_index == 0) { return; } GPR_ASSERT(GRPC_MDELEM_IS_INTERNED(elem)); uint32_t key_hash = grpc_slice_hash(GRPC_MDKEY(elem)); uint32_t value_hash = grpc_slice_hash(GRPC_MDVALUE(elem)); uint32_t elem_hash = GRPC_MDSTR_KV_HASH(key_hash, value_hash); /* Store this element into {entries,indices}_elem */ if (grpc_mdelem_eq(c->entries_elems[HASH_FRAGMENT_2(elem_hash)], elem)) { /* already there: update with new index */ c->indices_elems[HASH_FRAGMENT_2(elem_hash)] = new_index; } else if (grpc_mdelem_eq(c->entries_elems[HASH_FRAGMENT_3(elem_hash)], elem)) { /* already there (cuckoo): update with new index */ c->indices_elems[HASH_FRAGMENT_3(elem_hash)] = new_index; } else if (GRPC_MDISNULL(c->entries_elems[HASH_FRAGMENT_2(elem_hash)])) { /* not there, but a free element: add */ c->entries_elems[HASH_FRAGMENT_2(elem_hash)] = GRPC_MDELEM_REF(elem); c->indices_elems[HASH_FRAGMENT_2(elem_hash)] = new_index; } else if (GRPC_MDISNULL(c->entries_elems[HASH_FRAGMENT_3(elem_hash)])) { /* not there (cuckoo), but a free element: add */ c->entries_elems[HASH_FRAGMENT_3(elem_hash)] = GRPC_MDELEM_REF(elem); c->indices_elems[HASH_FRAGMENT_3(elem_hash)] = new_index; } else if (c->indices_elems[HASH_FRAGMENT_2(elem_hash)] < c->indices_elems[HASH_FRAGMENT_3(elem_hash)]) { /* not there: replace oldest */ GRPC_MDELEM_UNREF(c->entries_elems[HASH_FRAGMENT_2(elem_hash)]); c->entries_elems[HASH_FRAGMENT_2(elem_hash)] = GRPC_MDELEM_REF(elem); c->indices_elems[HASH_FRAGMENT_2(elem_hash)] = new_index; } else { /* not there: replace oldest */ GRPC_MDELEM_UNREF(c->entries_elems[HASH_FRAGMENT_3(elem_hash)]); c->entries_elems[HASH_FRAGMENT_3(elem_hash)] = GRPC_MDELEM_REF(elem); c->indices_elems[HASH_FRAGMENT_3(elem_hash)] = new_index; } add_key_with_index(c, elem, new_index); } static void add_elem(grpc_chttp2_hpack_compressor* c, grpc_mdelem elem, size_t elem_size) { uint32_t new_index = prepare_space_for_new_elem(c, elem_size); add_elem_with_index(c, elem, new_index); } static void add_key(grpc_chttp2_hpack_compressor* c, grpc_mdelem elem, size_t elem_size) { uint32_t new_index = prepare_space_for_new_elem(c, elem_size); add_key_with_index(c, elem, new_index); } static void emit_indexed(grpc_chttp2_hpack_compressor* c, uint32_t elem_index, framer_state* st) { GRPC_STATS_INC_HPACK_SEND_INDEXED(); uint32_t len = GRPC_CHTTP2_VARINT_LENGTH(elem_index, 1); GRPC_CHTTP2_WRITE_VARINT(elem_index, 1, 0x80, add_tiny_header_data(st, len), len); } typedef struct { grpc_slice data; uint8_t huffman_prefix; bool insert_null_before_wire_value; } wire_value; static wire_value get_wire_value(grpc_mdelem elem, bool true_binary_enabled) { wire_value wire_val; if (grpc_is_binary_header(GRPC_MDKEY(elem))) { if (true_binary_enabled) { GRPC_STATS_INC_HPACK_SEND_BINARY(); wire_val.huffman_prefix = 0x00; wire_val.insert_null_before_wire_value = true; wire_val.data = grpc_slice_ref_internal(GRPC_MDVALUE(elem)); } else { GRPC_STATS_INC_HPACK_SEND_BINARY_BASE64(); wire_val.huffman_prefix = 0x80; wire_val.insert_null_before_wire_value = false; wire_val.data = grpc_chttp2_base64_encode_and_huffman_compress(GRPC_MDVALUE(elem)); } } else { /* TODO(ctiller): opportunistically compress non-binary headers */ GRPC_STATS_INC_HPACK_SEND_UNCOMPRESSED(); wire_val.huffman_prefix = 0x00; wire_val.insert_null_before_wire_value = false; wire_val.data = grpc_slice_ref_internal(GRPC_MDVALUE(elem)); } return wire_val; } static size_t wire_value_length(wire_value v) { return GPR_SLICE_LENGTH(v.data) + v.insert_null_before_wire_value; } static void add_wire_value(framer_state* st, wire_value v) { if (v.insert_null_before_wire_value) *add_tiny_header_data(st, 1) = 0; add_header_data(st, v.data); } static void emit_lithdr_incidx(grpc_chttp2_hpack_compressor* c, uint32_t key_index, grpc_mdelem elem, framer_state* st) { GRPC_STATS_INC_HPACK_SEND_LITHDR_INCIDX(); uint32_t len_pfx = GRPC_CHTTP2_VARINT_LENGTH(key_index, 2); wire_value value = get_wire_value(elem, st->use_true_binary_metadata); size_t len_val = wire_value_length(value); uint32_t len_val_len; GPR_ASSERT(len_val <= UINT32_MAX); len_val_len = GRPC_CHTTP2_VARINT_LENGTH((uint32_t)len_val, 1); GRPC_CHTTP2_WRITE_VARINT(key_index, 2, 0x40, add_tiny_header_data(st, len_pfx), len_pfx); GRPC_CHTTP2_WRITE_VARINT((uint32_t)len_val, 1, value.huffman_prefix, add_tiny_header_data(st, len_val_len), len_val_len); add_wire_value(st, value); } static void emit_lithdr_noidx(grpc_chttp2_hpack_compressor* c, uint32_t key_index, grpc_mdelem elem, framer_state* st) { GRPC_STATS_INC_HPACK_SEND_LITHDR_NOTIDX(); uint32_t len_pfx = GRPC_CHTTP2_VARINT_LENGTH(key_index, 4); wire_value value = get_wire_value(elem, st->use_true_binary_metadata); size_t len_val = wire_value_length(value); uint32_t len_val_len; GPR_ASSERT(len_val <= UINT32_MAX); len_val_len = GRPC_CHTTP2_VARINT_LENGTH((uint32_t)len_val, 1); GRPC_CHTTP2_WRITE_VARINT(key_index, 4, 0x00, add_tiny_header_data(st, len_pfx), len_pfx); GRPC_CHTTP2_WRITE_VARINT((uint32_t)len_val, 1, value.huffman_prefix, add_tiny_header_data(st, len_val_len), len_val_len); add_wire_value(st, value); } static void emit_lithdr_incidx_v(grpc_chttp2_hpack_compressor* c, uint32_t unused_index, grpc_mdelem elem, framer_state* st) { GPR_ASSERT(unused_index == 0); GRPC_STATS_INC_HPACK_SEND_LITHDR_INCIDX_V(); GRPC_STATS_INC_HPACK_SEND_UNCOMPRESSED(); uint32_t len_key = static_cast GRPC_SLICE_LENGTH(GRPC_MDKEY(elem)); wire_value value = get_wire_value(elem, st->use_true_binary_metadata); uint32_t len_val = static_cast(wire_value_length(value)); uint32_t len_key_len = GRPC_CHTTP2_VARINT_LENGTH(len_key, 1); uint32_t len_val_len = GRPC_CHTTP2_VARINT_LENGTH(len_val, 1); GPR_ASSERT(len_key <= UINT32_MAX); GPR_ASSERT(wire_value_length(value) <= UINT32_MAX); *add_tiny_header_data(st, 1) = 0x40; GRPC_CHTTP2_WRITE_VARINT(len_key, 1, 0x00, add_tiny_header_data(st, len_key_len), len_key_len); add_header_data(st, grpc_slice_ref_internal(GRPC_MDKEY(elem))); GRPC_CHTTP2_WRITE_VARINT(len_val, 1, value.huffman_prefix, add_tiny_header_data(st, len_val_len), len_val_len); add_wire_value(st, value); } static void emit_lithdr_noidx_v(grpc_chttp2_hpack_compressor* c, uint32_t unused_index, grpc_mdelem elem, framer_state* st) { GPR_ASSERT(unused_index == 0); GRPC_STATS_INC_HPACK_SEND_LITHDR_NOTIDX_V(); GRPC_STATS_INC_HPACK_SEND_UNCOMPRESSED(); uint32_t len_key = static_cast GRPC_SLICE_LENGTH(GRPC_MDKEY(elem)); wire_value value = get_wire_value(elem, st->use_true_binary_metadata); uint32_t len_val = static_cast(wire_value_length(value)); uint32_t len_key_len = GRPC_CHTTP2_VARINT_LENGTH(len_key, 1); uint32_t len_val_len = GRPC_CHTTP2_VARINT_LENGTH(len_val, 1); GPR_ASSERT(len_key <= UINT32_MAX); GPR_ASSERT(wire_value_length(value) <= UINT32_MAX); *add_tiny_header_data(st, 1) = 0x00; GRPC_CHTTP2_WRITE_VARINT(len_key, 1, 0x00, add_tiny_header_data(st, len_key_len), len_key_len); add_header_data(st, grpc_slice_ref_internal(GRPC_MDKEY(elem))); GRPC_CHTTP2_WRITE_VARINT(len_val, 1, value.huffman_prefix, add_tiny_header_data(st, len_val_len), len_val_len); add_wire_value(st, value); } static void emit_advertise_table_size_change(grpc_chttp2_hpack_compressor* c, framer_state* st) { uint32_t len = GRPC_CHTTP2_VARINT_LENGTH(c->max_table_size, 3); GRPC_CHTTP2_WRITE_VARINT(c->max_table_size, 3, 0x20, add_tiny_header_data(st, len), len); c->advertise_table_size_change = 0; } static uint32_t dynidx(grpc_chttp2_hpack_compressor* c, uint32_t elem_index) { return 1 + GRPC_CHTTP2_LAST_STATIC_ENTRY + c->tail_remote_index + c->table_elems - elem_index; } /* encode an mdelem */ static void hpack_enc(grpc_chttp2_hpack_compressor* c, grpc_mdelem elem, framer_state* st) { GPR_ASSERT(GRPC_SLICE_LENGTH(GRPC_MDKEY(elem)) > 0); if (GRPC_SLICE_START_PTR(GRPC_MDKEY(elem))[0] != ':') { /* regular header */ st->seen_regular_header = 1; } else { GPR_ASSERT( st->seen_regular_header == 0 && "Reserved header (colon-prefixed) happening after regular ones."); } if (grpc_http_trace.enabled()) { char* k = grpc_slice_to_c_string(GRPC_MDKEY(elem)); char* v = nullptr; if (grpc_is_binary_header(GRPC_MDKEY(elem))) { v = grpc_dump_slice(GRPC_MDVALUE(elem), GPR_DUMP_HEX); } else { v = grpc_slice_to_c_string(GRPC_MDVALUE(elem)); } gpr_log( GPR_INFO, "Encode: '%s: %s', elem_interned=%d [%d], k_interned=%d, v_interned=%d", k, v, GRPC_MDELEM_IS_INTERNED(elem), GRPC_MDELEM_STORAGE(elem), grpc_slice_is_interned(GRPC_MDKEY(elem)), grpc_slice_is_interned(GRPC_MDVALUE(elem))); gpr_free(k); gpr_free(v); } bool elem_interned = GRPC_MDELEM_IS_INTERNED(elem); bool key_interned = elem_interned || grpc_slice_is_interned(GRPC_MDKEY(elem)); // Key is not interned, emit literals. if (!key_interned) { emit_lithdr_noidx_v(c, 0, elem, st); return; } uint32_t key_hash = grpc_slice_hash(GRPC_MDKEY(elem)); uint32_t elem_hash = 0; if (elem_interned) { uint32_t value_hash = grpc_slice_hash(GRPC_MDVALUE(elem)); elem_hash = GRPC_MDSTR_KV_HASH(key_hash, value_hash); inc_filter(HASH_FRAGMENT_1(elem_hash), &c->filter_elems_sum, c->filter_elems); /* is this elem currently in the decoders table? */ if (grpc_mdelem_eq(c->entries_elems[HASH_FRAGMENT_2(elem_hash)], elem) && c->indices_elems[HASH_FRAGMENT_2(elem_hash)] > c->tail_remote_index) { /* HIT: complete element (first cuckoo hash) */ emit_indexed(c, dynidx(c, c->indices_elems[HASH_FRAGMENT_2(elem_hash)]), st); return; } if (grpc_mdelem_eq(c->entries_elems[HASH_FRAGMENT_3(elem_hash)], elem) && c->indices_elems[HASH_FRAGMENT_3(elem_hash)] > c->tail_remote_index) { /* HIT: complete element (second cuckoo hash) */ emit_indexed(c, dynidx(c, c->indices_elems[HASH_FRAGMENT_3(elem_hash)]), st); return; } } uint32_t indices_key; /* should this elem be in the table? */ size_t decoder_space_usage = grpc_chttp2_get_size_in_hpack_table(elem, st->use_true_binary_metadata); bool should_add_elem = elem_interned && decoder_space_usage < MAX_DECODER_SPACE_USAGE && c->filter_elems[HASH_FRAGMENT_1(elem_hash)] >= c->filter_elems_sum / ONE_ON_ADD_PROBABILITY; void (*maybe_add)(grpc_chttp2_hpack_compressor*, grpc_mdelem, size_t) = should_add_elem ? add_elem : add_nothing; void (*emit)(grpc_chttp2_hpack_compressor*, uint32_t, grpc_mdelem, framer_state*) = should_add_elem ? emit_lithdr_incidx : emit_lithdr_noidx; /* no hits for the elem... maybe there's a key? */ indices_key = c->indices_keys[HASH_FRAGMENT_2(key_hash)]; if (grpc_slice_eq(c->entries_keys[HASH_FRAGMENT_2(key_hash)], GRPC_MDKEY(elem)) && indices_key > c->tail_remote_index) { /* HIT: key (first cuckoo hash) */ emit(c, dynidx(c, indices_key), elem, st); maybe_add(c, elem, decoder_space_usage); return; } indices_key = c->indices_keys[HASH_FRAGMENT_3(key_hash)]; if (grpc_slice_eq(c->entries_keys[HASH_FRAGMENT_3(key_hash)], GRPC_MDKEY(elem)) && indices_key > c->tail_remote_index) { /* HIT: key (first cuckoo hash) */ emit(c, dynidx(c, indices_key), elem, st); maybe_add(c, elem, decoder_space_usage); return; } /* no elem, key in the table... fall back to literal emission */ bool should_add_key = !elem_interned && decoder_space_usage < MAX_DECODER_SPACE_USAGE; emit = (should_add_elem || should_add_key) ? emit_lithdr_incidx_v : emit_lithdr_noidx_v; maybe_add = should_add_elem ? add_elem : (should_add_key ? add_key : add_nothing); emit(c, 0, elem, st); maybe_add(c, elem, decoder_space_usage); } #define STRLEN_LIT(x) (sizeof(x) - 1) #define TIMEOUT_KEY "grpc-timeout" static void deadline_enc(grpc_chttp2_hpack_compressor* c, grpc_millis deadline, framer_state* st) { char timeout_str[GRPC_HTTP2_TIMEOUT_ENCODE_MIN_BUFSIZE]; grpc_mdelem mdelem; grpc_http2_encode_timeout(deadline - grpc_core::ExecCtx::Get()->Now(), timeout_str); mdelem = grpc_mdelem_from_slices(GRPC_MDSTR_GRPC_TIMEOUT, grpc_slice_from_copied_string(timeout_str)); hpack_enc(c, mdelem, st); GRPC_MDELEM_UNREF(mdelem); } static uint32_t elems_for_bytes(uint32_t bytes) { return (bytes + 31) / 32; } void grpc_chttp2_hpack_compressor_init(grpc_chttp2_hpack_compressor* c) { memset(c, 0, sizeof(*c)); c->max_table_size = GRPC_CHTTP2_HPACKC_INITIAL_TABLE_SIZE; c->cap_table_elems = elems_for_bytes(c->max_table_size); c->max_table_elems = c->cap_table_elems; c->max_usable_size = GRPC_CHTTP2_HPACKC_INITIAL_TABLE_SIZE; c->table_elem_size = static_cast( gpr_malloc(sizeof(*c->table_elem_size) * c->cap_table_elems)); memset(c->table_elem_size, 0, sizeof(*c->table_elem_size) * c->cap_table_elems); for (size_t i = 0; i < GPR_ARRAY_SIZE(c->entries_keys); i++) { c->entries_keys[i] = terminal_slice; } } void grpc_chttp2_hpack_compressor_destroy(grpc_chttp2_hpack_compressor* c) { int i; for (i = 0; i < GRPC_CHTTP2_HPACKC_NUM_VALUES; i++) { if (c->entries_keys[i].refcount != &terminal_slice_refcount) { grpc_slice_unref_internal(c->entries_keys[i]); } GRPC_MDELEM_UNREF(c->entries_elems[i]); } gpr_free(c->table_elem_size); } void grpc_chttp2_hpack_compressor_set_max_usable_size( grpc_chttp2_hpack_compressor* c, uint32_t max_table_size) { c->max_usable_size = max_table_size; grpc_chttp2_hpack_compressor_set_max_table_size( c, GPR_MIN(c->max_table_size, max_table_size)); } static void rebuild_elems(grpc_chttp2_hpack_compressor* c, uint32_t new_cap) { uint16_t* table_elem_size = static_cast(gpr_malloc(sizeof(*table_elem_size) * new_cap)); uint32_t i; memset(table_elem_size, 0, sizeof(*table_elem_size) * new_cap); GPR_ASSERT(c->table_elems <= new_cap); for (i = 0; i < c->table_elems; i++) { uint32_t ofs = c->tail_remote_index + i + 1; table_elem_size[ofs % new_cap] = c->table_elem_size[ofs % c->cap_table_elems]; } c->cap_table_elems = new_cap; gpr_free(c->table_elem_size); c->table_elem_size = table_elem_size; } void grpc_chttp2_hpack_compressor_set_max_table_size( grpc_chttp2_hpack_compressor* c, uint32_t max_table_size) { max_table_size = GPR_MIN(max_table_size, c->max_usable_size); if (max_table_size == c->max_table_size) { return; } while (c->table_size > 0 && c->table_size > max_table_size) { evict_entry(c); } c->max_table_size = max_table_size; c->max_table_elems = elems_for_bytes(max_table_size); if (c->max_table_elems > c->cap_table_elems) { rebuild_elems(c, GPR_MAX(c->max_table_elems, 2 * c->cap_table_elems)); } else if (c->max_table_elems < c->cap_table_elems / 3) { uint32_t new_cap = GPR_MAX(c->max_table_elems, 16); if (new_cap != c->cap_table_elems) { rebuild_elems(c, new_cap); } } c->advertise_table_size_change = 1; if (grpc_http_trace.enabled()) { gpr_log(GPR_INFO, "set max table size from encoder to %d", max_table_size); } } void grpc_chttp2_encode_header(grpc_chttp2_hpack_compressor* c, grpc_mdelem** extra_headers, size_t extra_headers_size, grpc_metadata_batch* metadata, const grpc_encode_header_options* options, grpc_slice_buffer* outbuf) { GPR_ASSERT(options->stream_id != 0); framer_state st; st.seen_regular_header = 0; st.stream_id = options->stream_id; st.output = outbuf; st.is_first_frame = 1; st.stats = options->stats; st.max_frame_size = options->max_frame_size; st.use_true_binary_metadata = options->use_true_binary_metadata; /* Encode a metadata batch; store the returned values, representing a metadata element that needs to be unreffed back into the metadata slot. THIS MAY NOT BE THE SAME ELEMENT (if a decoder table slot got updated). After this loop, we'll do a batch unref of elements. */ begin_frame(&st); if (c->advertise_table_size_change != 0) { emit_advertise_table_size_change(c, &st); } for (size_t i = 0; i < extra_headers_size; ++i) { grpc_mdelem md = *extra_headers[i]; uint8_t static_index = grpc_chttp2_get_static_hpack_table_index(md); if (static_index) { emit_indexed(c, static_index, &st); } else { hpack_enc(c, md, &st); } } grpc_metadata_batch_assert_ok(metadata); for (grpc_linked_mdelem* l = metadata->list.head; l; l = l->next) { uint8_t static_index = grpc_chttp2_get_static_hpack_table_index(l->md); if (static_index) { emit_indexed(c, static_index, &st); } else { hpack_enc(c, l->md, &st); } } grpc_millis deadline = metadata->deadline; if (deadline != GRPC_MILLIS_INF_FUTURE) { deadline_enc(c, deadline, &st); } finish_frame(&st, 1, options->is_eof); }