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/*
*
* 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 <grpc/support/port_platform.h>
#include <grpc/support/alloc.h>
#include <grpc/support/log.h>
#include "src/core/lib/channel/channel_stack.h"
#include <stdlib.h>
#include <string.h>
grpc_core::TraceFlag grpc_trace_channel(false, "channel");
/* Memory layouts.
Channel stack is laid out as: {
grpc_channel_stack stk;
padding to GPR_MAX_ALIGNMENT
grpc_channel_element[stk.count];
per-filter memory, aligned to GPR_MAX_ALIGNMENT
}
Call stack is laid out as: {
grpc_call_stack stk;
padding to GPR_MAX_ALIGNMENT
grpc_call_element[stk.count];
per-filter memory, aligned to GPR_MAX_ALIGNMENT
} */
/* Given a size, round up to the next multiple of sizeof(void*) */
#define ROUND_UP_TO_ALIGNMENT_SIZE(x) \
(((x) + GPR_MAX_ALIGNMENT - 1u) & ~(GPR_MAX_ALIGNMENT - 1u))
size_t grpc_channel_stack_size(const grpc_channel_filter** filters,
size_t filter_count) {
/* always need the header, and size for the channel elements */
size_t size =
ROUND_UP_TO_ALIGNMENT_SIZE(sizeof(grpc_channel_stack)) +
ROUND_UP_TO_ALIGNMENT_SIZE(filter_count * sizeof(grpc_channel_element));
size_t i;
GPR_ASSERT((GPR_MAX_ALIGNMENT & (GPR_MAX_ALIGNMENT - 1)) == 0 &&
"GPR_MAX_ALIGNMENT must be a power of two");
/* add the size for each filter */
for (i = 0; i < filter_count; i++) {
size += ROUND_UP_TO_ALIGNMENT_SIZE(filters[i]->sizeof_channel_data);
}
return size;
}
#define CHANNEL_ELEMS_FROM_STACK(stk) \
((grpc_channel_element*)((char*)(stk) + ROUND_UP_TO_ALIGNMENT_SIZE( \
sizeof(grpc_channel_stack))))
#define CALL_ELEMS_FROM_STACK(stk) \
((grpc_call_element*)((char*)(stk) + \
ROUND_UP_TO_ALIGNMENT_SIZE(sizeof(grpc_call_stack))))
grpc_channel_element* grpc_channel_stack_element(
grpc_channel_stack* channel_stack, size_t index) {
return CHANNEL_ELEMS_FROM_STACK(channel_stack) + index;
}
grpc_channel_element* grpc_channel_stack_last_element(
grpc_channel_stack* channel_stack) {
return grpc_channel_stack_element(channel_stack, channel_stack->count - 1);
}
grpc_call_element* grpc_call_stack_element(grpc_call_stack* call_stack,
size_t index) {
return CALL_ELEMS_FROM_STACK(call_stack) + index;
}
grpc_error* grpc_channel_stack_init(
int initial_refs, grpc_iomgr_cb_func destroy, void* destroy_arg,
const grpc_channel_filter** filters, size_t filter_count,
const grpc_channel_args* channel_args, grpc_transport* optional_transport,
const char* name, grpc_channel_stack* stack) {
size_t call_size =
ROUND_UP_TO_ALIGNMENT_SIZE(sizeof(grpc_call_stack)) +
ROUND_UP_TO_ALIGNMENT_SIZE(filter_count * sizeof(grpc_call_element));
grpc_channel_element* elems;
grpc_channel_element_args args;
char* user_data;
size_t i;
stack->count = filter_count;
GRPC_STREAM_REF_INIT(&stack->refcount, initial_refs, destroy, destroy_arg,
name);
elems = CHANNEL_ELEMS_FROM_STACK(stack);
user_data =
(reinterpret_cast<char*>(elems)) +
ROUND_UP_TO_ALIGNMENT_SIZE(filter_count * sizeof(grpc_channel_element));
/* init per-filter data */
grpc_error* first_error = GRPC_ERROR_NONE;
for (i = 0; i < filter_count; i++) {
args.channel_stack = stack;
args.channel_args = channel_args;
args.optional_transport = optional_transport;
args.is_first = i == 0;
args.is_last = i == (filter_count - 1);
elems[i].filter = filters[i];
elems[i].channel_data = user_data;
grpc_error* error = elems[i].filter->init_channel_elem(&elems[i], &args);
if (error != GRPC_ERROR_NONE) {
if (first_error == GRPC_ERROR_NONE) {
first_error = error;
} else {
GRPC_ERROR_UNREF(error);
}
}
user_data += ROUND_UP_TO_ALIGNMENT_SIZE(filters[i]->sizeof_channel_data);
call_size += ROUND_UP_TO_ALIGNMENT_SIZE(filters[i]->sizeof_call_data);
}
GPR_ASSERT(user_data > (char*)stack);
GPR_ASSERT((uintptr_t)(user_data - (char*)stack) ==
grpc_channel_stack_size(filters, filter_count));
stack->call_stack_size = call_size;
return first_error;
}
void grpc_channel_stack_destroy(grpc_channel_stack* stack) {
grpc_channel_element* channel_elems = CHANNEL_ELEMS_FROM_STACK(stack);
size_t count = stack->count;
size_t i;
/* destroy per-filter data */
for (i = 0; i < count; i++) {
channel_elems[i].filter->destroy_channel_elem(&channel_elems[i]);
}
}
grpc_error* grpc_call_stack_init(grpc_channel_stack* channel_stack,
int initial_refs, grpc_iomgr_cb_func destroy,
void* destroy_arg,
const grpc_call_element_args* elem_args) {
grpc_channel_element* channel_elems = CHANNEL_ELEMS_FROM_STACK(channel_stack);
size_t count = channel_stack->count;
grpc_call_element* call_elems;
char* user_data;
size_t i;
elem_args->call_stack->count = count;
GRPC_STREAM_REF_INIT(&elem_args->call_stack->refcount, initial_refs, destroy,
destroy_arg, "CALL_STACK");
call_elems = CALL_ELEMS_FROM_STACK(elem_args->call_stack);
user_data = (reinterpret_cast<char*>(call_elems)) +
ROUND_UP_TO_ALIGNMENT_SIZE(count * sizeof(grpc_call_element));
/* init per-filter data */
grpc_error* first_error = GRPC_ERROR_NONE;
for (i = 0; i < count; i++) {
call_elems[i].filter = channel_elems[i].filter;
call_elems[i].channel_data = channel_elems[i].channel_data;
call_elems[i].call_data = user_data;
grpc_error* error =
call_elems[i].filter->init_call_elem(&call_elems[i], elem_args);
if (error != GRPC_ERROR_NONE) {
if (first_error == GRPC_ERROR_NONE) {
first_error = error;
} else {
GRPC_ERROR_UNREF(error);
}
}
user_data +=
ROUND_UP_TO_ALIGNMENT_SIZE(call_elems[i].filter->sizeof_call_data);
}
return first_error;
}
void grpc_call_stack_set_pollset_or_pollset_set(grpc_call_stack* call_stack,
grpc_polling_entity* pollent) {
size_t count = call_stack->count;
grpc_call_element* call_elems;
char* user_data;
size_t i;
call_elems = CALL_ELEMS_FROM_STACK(call_stack);
user_data = (reinterpret_cast<char*>(call_elems)) +
ROUND_UP_TO_ALIGNMENT_SIZE(count * sizeof(grpc_call_element));
/* init per-filter data */
for (i = 0; i < count; i++) {
call_elems[i].filter->set_pollset_or_pollset_set(&call_elems[i], pollent);
user_data +=
ROUND_UP_TO_ALIGNMENT_SIZE(call_elems[i].filter->sizeof_call_data);
}
}
void grpc_call_stack_ignore_set_pollset_or_pollset_set(
grpc_call_element* elem, grpc_polling_entity* pollent) {}
void grpc_call_stack_destroy(grpc_call_stack* stack,
const grpc_call_final_info* final_info,
grpc_closure* then_schedule_closure) {
grpc_call_element* elems = CALL_ELEMS_FROM_STACK(stack);
size_t count = stack->count;
size_t i;
/* destroy per-filter data */
for (i = 0; i < count; i++) {
elems[i].filter->destroy_call_elem(
&elems[i], final_info,
i == count - 1 ? then_schedule_closure : nullptr);
}
}
void grpc_call_next_op(grpc_call_element* elem,
grpc_transport_stream_op_batch* op) {
grpc_call_element* next_elem = elem + 1;
GRPC_CALL_LOG_OP(GPR_INFO, next_elem, op);
next_elem->filter->start_transport_stream_op_batch(next_elem, op);
}
void grpc_channel_next_get_info(grpc_channel_element* elem,
const grpc_channel_info* channel_info) {
grpc_channel_element* next_elem = elem + 1;
next_elem->filter->get_channel_info(next_elem, channel_info);
}
void grpc_channel_next_op(grpc_channel_element* elem, grpc_transport_op* op) {
grpc_channel_element* next_elem = elem + 1;
next_elem->filter->start_transport_op(next_elem, op);
}
grpc_channel_stack* grpc_channel_stack_from_top_element(
grpc_channel_element* elem) {
return reinterpret_cast<grpc_channel_stack*>(
reinterpret_cast<char*>(elem) -
ROUND_UP_TO_ALIGNMENT_SIZE(sizeof(grpc_channel_stack)));
}
grpc_call_stack* grpc_call_stack_from_top_element(grpc_call_element* elem) {
return reinterpret_cast<grpc_call_stack*>(
reinterpret_cast<char*>(elem) -
ROUND_UP_TO_ALIGNMENT_SIZE(sizeof(grpc_call_stack)));
}
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