#include <grpc/grpc.h>
#include <grpc/byte_buffer.h>
#include <grpc/byte_buffer_reader.h>
#include <grpc/grpc_security.h>
#include <grpc/impl/codegen/grpc_types.h>
#include <grpc/impl/codegen/compression_types.h>
#include <grpc/slice.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <grpc_haskell.h>
void grpc_haskell_free(char *debugMsg, void *ptr){
#ifdef GRPC_HASKELL_DEBUG
printf("C wrapper: %s: freeing ptr: %p\n", debugMsg, ptr);
#endif
free(ptr);
}
grpc_event *grpc_completion_queue_next_(grpc_completion_queue *cq,
gpr_timespec *deadline,
void *reserved) {
grpc_event *toReturn = malloc(sizeof(grpc_event));
*toReturn = grpc_completion_queue_next(cq, *deadline, reserved);
return toReturn;
}
grpc_event *grpc_completion_queue_pluck_(grpc_completion_queue *cq, void *tag,
gpr_timespec *deadline,
void *reserved) {
grpc_event *toReturn = malloc(sizeof(grpc_event));
*toReturn = grpc_completion_queue_pluck(cq, tag, *deadline, reserved);
return toReturn;
}
grpc_call *grpc_channel_create_call_(grpc_channel *channel,
grpc_call *parent_call,
uint32_t propagation_mask,
grpc_completion_queue *completion_queue,
const char *method, const char *host,
gpr_timespec *deadline, void *reserved) {
grpc_slice method_slice = grpc_slice_from_copied_string(method);
grpc_slice host_slice = grpc_slice_from_copied_string(host);
return grpc_channel_create_call(channel, parent_call, propagation_mask,
completion_queue, method_slice,
&host_slice, *deadline, reserved);
}
grpc_slice* grpc_slice_malloc_(size_t len){
grpc_slice* retval = malloc(sizeof(grpc_slice));
*retval = grpc_slice_malloc(len);
return retval;
}
size_t grpc_slice_length_(grpc_slice *slice){
return GRPC_SLICE_LENGTH(*slice);
}
uint8_t *grpc_slice_start_(grpc_slice *slice){
return GRPC_SLICE_START_PTR(*slice);
}
grpc_slice* grpc_slice_from_copied_string_(const char* source){
grpc_slice* retval = malloc(sizeof(grpc_slice));
*retval = grpc_slice_from_copied_string(source);
return retval;
}
grpc_slice* grpc_slice_from_copied_buffer_(const char *source, size_t len){
grpc_slice* retval = malloc(sizeof(grpc_slice));
//note: 'grpc_slice_from_copied_string' handles allocating space for 'source'.
*retval = grpc_slice_from_copied_buffer(source, len);
return retval;
}
void grpc_slice_unref_(grpc_slice* slice){
grpc_slice_unref(*slice);
}
void free_slice(grpc_slice *slice){
grpc_slice_unref(*slice);
grpc_haskell_free("free_slice", slice);
}
grpc_byte_buffer **create_receiving_byte_buffer(){
grpc_byte_buffer **retval = malloc(sizeof(grpc_byte_buffer*));
*retval = NULL;
return retval;
}
void destroy_receiving_byte_buffer(grpc_byte_buffer **bb){
grpc_byte_buffer_destroy(*bb);
grpc_haskell_free("destroy_receiving_byte_buffer", bb);
}
grpc_byte_buffer_reader *byte_buffer_reader_create(grpc_byte_buffer *buffer){
grpc_byte_buffer_reader *reader = malloc(sizeof(grpc_byte_buffer_reader));
grpc_byte_buffer_reader_init(reader, buffer);
return reader;
}
void byte_buffer_reader_destroy(grpc_byte_buffer_reader *reader){
grpc_byte_buffer_reader_destroy(reader);
grpc_haskell_free("byte_buffer_reader_destroy", reader);
}
grpc_slice *grpc_byte_buffer_reader_readall_(grpc_byte_buffer_reader *reader){
grpc_slice *retval = malloc(sizeof(grpc_slice));
*retval = grpc_byte_buffer_reader_readall(reader);
return retval;
}
void timespec_destroy(gpr_timespec* t){
grpc_haskell_free("timespec_destroy", t);
}
gpr_timespec* gpr_inf_future_(gpr_clock_type t){
gpr_timespec *retval = malloc(sizeof(gpr_timespec));
*retval = gpr_inf_future(t);
return retval;
}
gpr_timespec* gpr_now_(gpr_clock_type t){
gpr_timespec *retval = malloc(sizeof(gpr_timespec));
*retval = gpr_now(t);
return retval;
}
int32_t gpr_time_to_millis_(gpr_timespec* t){
return gpr_time_to_millis(*t);
}
gpr_timespec* seconds_to_deadline(int64_t seconds){
gpr_timespec *retval = malloc(sizeof(gpr_timespec));
*retval = gpr_time_add(gpr_now(GPR_CLOCK_MONOTONIC),
gpr_time_from_millis(seconds * 1e3, GPR_TIMESPAN));
return retval;
}
gpr_timespec* millis_to_deadline(int64_t millis){
gpr_timespec *retval = malloc(sizeof(gpr_timespec));
*retval = gpr_time_add(gpr_now(GPR_CLOCK_MONOTONIC),
gpr_time_from_micros(millis * 1e3, GPR_TIMESPAN));
return retval;
}
gpr_timespec* infinite_deadline(){
gpr_timespec *retval = malloc(sizeof(gpr_timespec));
*retval = gpr_inf_future(GPR_CLOCK_MONOTONIC);
return retval;
}
gpr_timespec* convert_clock_type(gpr_timespec *t, gpr_clock_type to){
gpr_timespec *retval = malloc(sizeof(gpr_timespec));
*retval = gpr_convert_clock_type(*t, to);
return retval;
}
grpc_metadata_array** metadata_array_create(){
grpc_metadata_array **retval = malloc(sizeof(grpc_metadata_array*));
*retval = malloc(sizeof(grpc_metadata_array));
grpc_metadata_array_init(*retval);
#ifdef GRPC_HASKELL_DEBUG
printf("C wrapper: metadata_array_create debug: %p %p %p\n", retval, *retval,
(*retval)->metadata);
#endif
return retval;
}
void metadata_array_destroy(grpc_metadata_array **arr){
grpc_metadata_array_destroy(*arr);
grpc_haskell_free("metadata_array_destroy1", *arr);
grpc_haskell_free("metadata_array_destroy1", arr);
}
grpc_metadata* metadata_alloc(size_t n){
grpc_metadata *retval = calloc(n,sizeof(grpc_metadata));
return retval;
}
void metadata_free(grpc_metadata* m){
grpc_haskell_free("metadata_free", m);
}
void set_metadata_key_val(char *key, char *val, size_t val_len,
grpc_metadata *arr, size_t i){
grpc_metadata *p = arr + i;
p->key = grpc_slice_from_copied_string(key);
p->value = grpc_slice_from_copied_buffer(val,val_len);
}
grpc_slice* get_metadata_key(grpc_metadata *arr, size_t i){
grpc_metadata *p = arr + i;
return &p->key;
}
grpc_slice* get_metadata_val(grpc_metadata *arr, size_t i){
grpc_metadata *p = arr + i;
return &(p->value);
}
grpc_op* op_array_create(size_t n){
grpc_op* ops = malloc(n*sizeof(grpc_op));
memset(ops, 0, n*sizeof(grpc_op));
return ops;
}
void op_array_destroy(grpc_op* op_array, size_t n){
#ifdef GRPC_HASKELL_DEBUG
printf("C wrapper: entered op_array_destroy\n");
#endif
// This only destroys the array, the values in the array
// are freed in freeOpContext
grpc_haskell_free("op_array_destroy", op_array);
}
void op_send_initial_metadata(grpc_op *op_array, size_t i,
grpc_metadata *arr, size_t n_metadata){
grpc_op *op = op_array + i;
op->op = GRPC_OP_SEND_INITIAL_METADATA;
op->data.send_initial_metadata.count = n_metadata;
op->data.send_initial_metadata.metadata
= malloc(n_metadata*sizeof(grpc_metadata));
memcpy(op->data.send_initial_metadata.metadata, arr,
n_metadata*sizeof(grpc_metadata));
op->flags = 0;
op->reserved = NULL;
}
void op_send_initial_metadata_empty(grpc_op *op_array, size_t i){
grpc_op *op = op_array + i;
op->op = GRPC_OP_SEND_INITIAL_METADATA;
op->data.send_initial_metadata.count = 0;
op->data.send_initial_metadata.metadata = malloc(0*sizeof(grpc_metadata));
op->flags = 0;
op->reserved = NULL;
}
void op_send_message(grpc_op *op_array, size_t i,
grpc_byte_buffer *payload){
grpc_op *op = op_array + i;
op->op = GRPC_OP_SEND_MESSAGE;
op->data.send_message.send_message = grpc_byte_buffer_copy(payload);
op->flags = 0;
op->reserved = NULL;
}
void op_send_close_client(grpc_op *op_array, size_t i){
grpc_op *op = op_array + i;
op->op = GRPC_OP_SEND_CLOSE_FROM_CLIENT;
op->flags = 0;
op->reserved = NULL;
}
void op_recv_initial_metadata(grpc_op *op_array, size_t i,
grpc_metadata_array** arr){
grpc_op *op = op_array + i;
op->op = GRPC_OP_RECV_INITIAL_METADATA;
op->data.recv_initial_metadata.recv_initial_metadata = *arr;
op->flags = 0;
op->reserved = NULL;
}
void op_recv_message(grpc_op *op_array, size_t i,
grpc_byte_buffer **payload_recv){
grpc_op *op = op_array + i;
op->op = GRPC_OP_RECV_MESSAGE;
op->data.recv_message.recv_message = payload_recv;
op->flags = 0;
op->reserved = NULL;
}
void op_recv_status_client(grpc_op *op_array, size_t i,
grpc_metadata_array** arr,
grpc_status_code* status,
grpc_slice* details){
grpc_op *op = op_array + i;
op->op = GRPC_OP_RECV_STATUS_ON_CLIENT;
op->data.recv_status_on_client.trailing_metadata = *arr;
op->data.recv_status_on_client.status = status;
op->data.recv_status_on_client.status_details = details;
op->flags = 0;
op->reserved = NULL;
}
void op_recv_close_server(grpc_op *op_array, size_t i, int *was_cancelled){
grpc_op *op = op_array + i;
op->op = GRPC_OP_RECV_CLOSE_ON_SERVER;
op->data.recv_close_on_server.cancelled = was_cancelled;
op->flags = 0;
op->reserved = NULL;
}
void op_send_status_server(grpc_op *op_array, size_t i,
size_t metadata_count, grpc_metadata* m,
grpc_status_code status, grpc_slice *details){
grpc_op *op = op_array + i;
op->op = GRPC_OP_SEND_STATUS_FROM_SERVER;
op->data.send_status_from_server.trailing_metadata_count = metadata_count;
op->data.send_status_from_server.trailing_metadata
= malloc(sizeof(grpc_metadata)*metadata_count);
memcpy(op->data.send_status_from_server.trailing_metadata, m,
metadata_count*sizeof(grpc_metadata));
op->data.send_status_from_server.status = status;
op->data.send_status_from_server.status_details = details;
op->flags = 0;
op->reserved = NULL;
}
grpc_status_code* create_status_code_ptr(){
grpc_status_code* retval = malloc(sizeof(grpc_status_code));
#ifdef GRPC_HASKELL_DEBUG
printf("C wrapper: create_status_code_ptr debug: %p\n", retval);
#endif
return retval;
}
grpc_status_code deref_status_code_ptr(grpc_status_code* p){
return *p;
}
void destroy_status_code_ptr(grpc_status_code* p){
grpc_haskell_free("destroy_status_code_ptr", p);
}
grpc_call_details* create_call_details(){
grpc_call_details* retval = malloc(sizeof(grpc_call_details));
grpc_call_details_init(retval);
return retval;
}
void destroy_call_details(grpc_call_details* cd){
grpc_call_details_destroy(cd);
grpc_haskell_free("destroy_call_details", cd);
}
void grpc_channel_watch_connectivity_state_(grpc_channel *channel,
grpc_connectivity_state
last_observed_state,
gpr_timespec* deadline,
grpc_completion_queue *cq,
void *tag){
grpc_channel_watch_connectivity_state(channel, last_observed_state, *deadline,
cq, tag);
}
grpc_metadata* metadata_array_get_metadata(grpc_metadata_array* arr){
return arr->metadata;
}
void metadata_array_set_metadata(grpc_metadata_array* arr, grpc_metadata* meta){
arr->metadata = meta;
//NOTE: we assume count == capacity because that's how the 'createMetadata'
//Haskell function works. It isn't safe to call this function if the
//metadata was created in some other way.
size_t n = sizeof(meta);
arr->count = n;
arr->capacity = n;
}
size_t metadata_array_get_count(grpc_metadata_array* arr){
return arr->count;
}
size_t metadata_array_get_capacity(grpc_metadata_array* arr){
return arr->capacity;
}
grpc_call* grpc_channel_create_registered_call_(
grpc_channel *channel, grpc_call *parent_call, uint32_t propagation_mask,
grpc_completion_queue *completion_queue, void *registered_call_handle,
gpr_timespec *deadline, void *reserved){
#ifdef GRPC_HASKELL_DEBUG
printf("calling grpc_channel_create_registered_call with deadline %p\n",
deadline);
#endif
return grpc_channel_create_registered_call(channel, parent_call,
propagation_mask, completion_queue, registered_call_handle,
*deadline, reserved);
}
grpc_slice* call_details_get_method(grpc_call_details* details){
return &details->method;
}
grpc_slice* call_details_get_host(grpc_call_details* details){
return &details->host;
}
gpr_timespec* call_details_get_deadline(grpc_call_details* details){
return &(details->deadline);
}
void* grpc_server_register_method_(
grpc_server* server, const char* method,
const char* host, grpc_server_register_method_payload_handling payload_handling ){
return grpc_server_register_method(server, method, host, payload_handling, 0);
}
grpc_arg* create_arg_array(size_t n){
return malloc(sizeof(grpc_arg)*n);
}
//Converts our enum into real GRPC #defines. c2hs workaround.
char* translate_arg_key(enum supported_arg_key key){
switch (key) {
case compression_algorithm_key:
return GRPC_COMPRESSION_CHANNEL_DEFAULT_ALGORITHM;
case compression_level_key:
return GRPC_COMPRESSION_CHANNEL_DEFAULT_LEVEL;
case user_agent_prefix_key:
return GRPC_ARG_PRIMARY_USER_AGENT_STRING;
case user_agent_suffix_key:
return GRPC_ARG_SECONDARY_USER_AGENT_STRING;
case max_receive_message_length_key:
return GRPC_ARG_MAX_RECEIVE_MESSAGE_LENGTH;
case max_metadata_size_key:
return GRPC_ARG_MAX_METADATA_SIZE;
default:
return "unknown_arg_key";
}
}
void create_string_arg(grpc_arg* args, size_t i,
enum supported_arg_key key, char* value){
grpc_arg* arg = args+i;
arg->type = GRPC_ARG_STRING;
arg->key = translate_arg_key(key);
char* storeValue = malloc(sizeof(char)*strlen(value));
arg->value.string = strcpy(storeValue, value);
}
void create_int_arg(grpc_arg* args, size_t i,
enum supported_arg_key key, int value){
grpc_arg* arg = args+i;
arg->type = GRPC_ARG_INTEGER;
arg->key = translate_arg_key(key);
arg->value.integer = value;
}
//Destroys an arg array of the given length. NOTE: the args in the arg array
//MUST have been created by the create_*_arg functions above!
void destroy_arg_array(grpc_arg* args, size_t n){
for(int i = 0; i < n; i++){
grpc_arg* arg = args+i;
if(arg->type == GRPC_ARG_STRING){
free(arg->value.string);
}
}
free(args);
}
grpc_auth_property_iterator* grpc_auth_context_property_iterator_(
const grpc_auth_context* ctx){
grpc_auth_property_iterator* i = malloc(sizeof(grpc_auth_property_iterator));
*i = grpc_auth_context_property_iterator(ctx);
return i;
}
grpc_server_credentials* ssl_server_credentials_create_internal(
const char* pem_root_certs, const char* pem_key, const char* pem_cert,
grpc_ssl_client_certificate_request_type force_client_auth){
grpc_ssl_pem_key_cert_pair pair = {pem_key, pem_cert};
grpc_server_credentials* creds = grpc_ssl_server_credentials_create_ex(
pem_root_certs, &pair, 1, force_client_auth, NULL);
return creds;
}
grpc_channel_credentials* grpc_ssl_credentials_create_internal(
const char* pem_root_certs, const char* pem_key, const char* pem_cert){
grpc_channel_credentials* creds;
if(pem_key && pem_cert){
grpc_ssl_pem_key_cert_pair pair = {pem_key, pem_cert};
creds = grpc_ssl_credentials_create(pem_root_certs, &pair, NULL, NULL);
}
else{
creds = grpc_ssl_credentials_create(pem_root_certs, NULL, NULL, NULL);
}
return creds;
}
void grpc_server_credentials_set_auth_metadata_processor_(
grpc_server_credentials* creds, grpc_auth_metadata_processor* p){
grpc_server_credentials_set_auth_metadata_processor(creds, *p);
}
grpc_auth_metadata_processor* mk_auth_metadata_processor(
void (*process)(void *state, grpc_auth_context *context,
const grpc_metadata *md, size_t num_md,
grpc_process_auth_metadata_done_cb cb, void *user_data)){
//TODO: figure out when to free this.
grpc_auth_metadata_processor* p = malloc(sizeof(grpc_auth_metadata_processor));
p->process = process;
p->destroy = NULL;
p->state = NULL;
return p;
}
grpc_call_credentials* grpc_metadata_credentials_create_from_plugin_(
grpc_metadata_credentials_plugin* plugin){
return grpc_metadata_credentials_create_from_plugin(*plugin, NULL);
}
//This is a hack to work around GHC being unable to deal with raw struct params.
//This callback is registered as the get_metadata callback for the call, and its
//only job is to cast the void* state pointer to the correct function pointer
//type and call the Haskell function with it.
int metadata_dispatcher(void *state,
grpc_auth_metadata_context context,
grpc_credentials_plugin_metadata_cb cb,
void *user_data,
grpc_metadata creds_md[GRPC_METADATA_CREDENTIALS_PLUGIN_SYNC_MAX],
size_t *num_creds_md,
grpc_status_code *status,
const char ** error_details) {
((haskell_get_metadata*)state)(&context, cb, user_data);
return 0;
}
grpc_metadata_credentials_plugin* mk_metadata_client_plugin(
haskell_get_metadata* f){
//TODO: figure out when to free this.
grpc_metadata_credentials_plugin* p =
malloc(sizeof(grpc_metadata_credentials_plugin));
p->get_metadata = metadata_dispatcher;
p->destroy = NULL;
p->state = f;
p->type = "grpc-haskell custom credentials";
return p;
}