/*
* Copyright (c) 2017, Arm Limited and affiliates.
* SPDX-License-Identifier: Apache-2.0
*
* 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 "AT_CellularStack.h"
#include "CellularUtil.h"
#include "CellularLog.h"
#include "rtos/ThisThread.h"
#include "AT_CellularDevice.h"
using namespace mbed_cellular_util;
using namespace mbed;
AT_CellularStack::AT_CellularStack(ATHandler &at, int cid, nsapi_ip_stack_t stack_type, AT_CellularDevice &device) :
_socket(NULL), _cid(cid),
_stack_type(stack_type), _ip_ver_sendto(NSAPI_UNSPEC), _at(at), _device(device)
{
memset(_ip, 0, PDP_IPV6_SIZE);
MBED_ASSERT(_device.get_property(AT_CellularDevice::PROPERTY_SOCKET_COUNT) > 0);
_socket = new CellularSocket *[_device.get_property(AT_CellularDevice::PROPERTY_SOCKET_COUNT)]();
}
AT_CellularStack::~AT_CellularStack()
{
for (int i = 0; i < _device.get_property(AT_CellularDevice::PROPERTY_SOCKET_COUNT); i++) {
if (_socket[i]) {
delete _socket[i];
}
}
delete [] _socket;
}
int AT_CellularStack::find_socket_index(nsapi_socket_t handle)
{
if (!_socket) {
return -1;
}
for (int i = 0; i < _device.get_property(AT_CellularDevice::PROPERTY_SOCKET_COUNT); i++) {
if (_socket[i] == handle) {
return i;
}
}
return -1;
}
/** NetworkStack
*/
nsapi_error_t AT_CellularStack::get_ip_address(SocketAddress *address)
{
if (!address) {
return NSAPI_ERROR_PARAMETER;
}
_at.lock();
bool ipv4 = false, ipv6 = false;
_at.cmd_start_stop("+CGPADDR", "=", "%d", _cid);
_at.resp_start("+CGPADDR:");
if (_at.info_resp()) {
_at.skip_param();
if (_at.read_string(_ip, PDP_IPV6_SIZE) != -1) {
convert_ipv6(_ip);
address->set_ip_address(_ip);
ipv4 = (address->get_ip_version() == NSAPI_IPv4);
ipv6 = (address->get_ip_version() == NSAPI_IPv6);
// Try to look for second address ONLY if modem has support for dual stack(can handle both IPv4 and IPv6 simultaneously).
// Otherwise assumption is that second address is not reliable, even if network provides one.
if ((_device.get_property(AT_CellularDevice::PROPERTY_IPV4V6_PDP_TYPE) && (_at.read_string(_ip, PDP_IPV6_SIZE) != -1))) {
convert_ipv6(_ip);
address->set_ip_address(_ip);
ipv6 = (address->get_ip_version() == NSAPI_IPv6);
}
}
}
_at.resp_stop();
_at.unlock();
if (ipv4 && ipv6) {
_stack_type = IPV4V6_STACK;
} else if (ipv4) {
_stack_type = IPV4_STACK;
} else if (ipv6) {
_stack_type = IPV6_STACK;
}
return (ipv4 || ipv6) ? NSAPI_ERROR_OK : NSAPI_ERROR_NO_ADDRESS;
}
void AT_CellularStack::set_cid(int cid)
{
_cid = cid;
}
nsapi_error_t AT_CellularStack::socket_open(nsapi_socket_t *handle, nsapi_protocol_t proto)
{
if (!handle) {
return NSAPI_ERROR_UNSUPPORTED;
}
if (proto == NSAPI_UDP) {
if (!_device.get_property(AT_CellularDevice::PROPERTY_IP_UDP)) {
return NSAPI_ERROR_UNSUPPORTED;
}
} else if (proto == NSAPI_TCP) {
if (!_device.get_property(AT_CellularDevice::PROPERTY_IP_TCP)) {
return NSAPI_ERROR_UNSUPPORTED;
}
} else {
return NSAPI_ERROR_UNSUPPORTED;
}
_socket_mutex.lock();
int index = find_socket_index(0);
if (index == -1) {
tr_warn("No free sockets!");
_socket_mutex.unlock();
return NSAPI_ERROR_NO_SOCKET;
}
tr_info("Socket %d open", index);
// create local socket structure, socket on modem is created when app calls sendto/recvfrom
// Do not assign a socket ID yet. Socket is not created at the Modem yet.
// create_socket_impl(handle) will assign the correct socket ID.
_socket[index] = new CellularSocket;
CellularSocket *psock = _socket[index];
SocketAddress addr(0, get_dynamic_ip_port());
psock->localAddress = addr;
psock->proto = proto;
*handle = psock;
_socket_mutex.unlock();
return NSAPI_ERROR_OK;
}
nsapi_error_t AT_CellularStack::socket_close(nsapi_socket_t handle)
{
int err = NSAPI_ERROR_DEVICE_ERROR;
struct CellularSocket *socket = (struct CellularSocket *)handle;
if (!socket) {
return NSAPI_ERROR_NO_SOCKET;
}
int sock_id = socket->id;
int index = find_socket_index(handle);
if (index == -1) {
tr_error("No socket found to be closed");
return err;
}
err = NSAPI_ERROR_OK;
// Close the socket on the modem if it was created
_at.lock();
if (sock_id > -1) {
err = socket_close_impl(sock_id);
}
if (!err) {
tr_info("Socket %d closed", index);
} else {
tr_info("Socket %d close (id %d, started %d, error %d)", index, sock_id, socket->started, err);
}
_socket_mutex.lock();
_socket[index] = NULL;
delete socket;
_socket_mutex.unlock();
_at.unlock();
return err;
}
nsapi_error_t AT_CellularStack::socket_bind(nsapi_socket_t handle, const SocketAddress &addr)
{
struct CellularSocket *socket = (CellularSocket *)handle;
if (!socket) {
return NSAPI_ERROR_NO_SOCKET;
}
if (addr) {
return NSAPI_ERROR_UNSUPPORTED;
}
_at.lock();
uint16_t port = addr.get_port();
if (port != socket->localAddress.get_port()) {
if (port && (get_socket_index_by_port(port) == -1)) {
socket->localAddress.set_port(port);
} else {
_at.unlock();
return NSAPI_ERROR_PARAMETER;
}
}
if (socket->id == -1) {
create_socket_impl(socket);
}
return _at.unlock_return_error();
}
nsapi_error_t AT_CellularStack::socket_listen(nsapi_socket_t handle, int backlog)
{
return NSAPI_ERROR_UNSUPPORTED;
}
nsapi_error_t AT_CellularStack::socket_connect(nsapi_socket_t handle, const SocketAddress &addr)
{
CellularSocket *socket = (CellularSocket *)handle;
if (!socket) {
return NSAPI_ERROR_NO_SOCKET;
}
socket->remoteAddress = addr;
socket->connected = true;
return NSAPI_ERROR_OK;
}
nsapi_error_t AT_CellularStack::socket_accept(void *server, void **socket, SocketAddress *addr)
{
return NSAPI_ERROR_UNSUPPORTED;
}
nsapi_size_or_error_t AT_CellularStack::socket_send(nsapi_socket_t handle, const void *data, unsigned size)
{
CellularSocket *socket = (CellularSocket *)handle;
if (!socket) {
return NSAPI_ERROR_NO_SOCKET;
}
if (!socket->connected) {
return NSAPI_ERROR_NO_CONNECTION;
}
return socket_sendto(handle, socket->remoteAddress, data, size);
}
nsapi_size_or_error_t AT_CellularStack::socket_sendto(nsapi_socket_t handle, const SocketAddress &addr, const void *data, unsigned size)
{
CellularSocket *socket = (CellularSocket *)handle;
if (!socket) {
return NSAPI_ERROR_NO_SOCKET;
}
if (socket->closed && !socket->pending_bytes) {
tr_info("sendto socket %d closed", socket->id);
return NSAPI_ERROR_NO_CONNECTION;
}
if (size == 0) {
if (socket->proto == NSAPI_UDP) {
return NSAPI_ERROR_UNSUPPORTED;
} else if (socket->proto == NSAPI_TCP) {
return 0;
}
}
nsapi_size_or_error_t ret_val = NSAPI_ERROR_OK;
if (socket->id == -1) {
/* Check that stack type supports sendto address type*/
if (!is_addr_stack_compatible(addr)) {
return NSAPI_ERROR_PARAMETER;
}
_ip_ver_sendto = addr.get_ip_version();
_at.lock();
ret_val = create_socket_impl(socket);
_at.unlock();
if (ret_val != NSAPI_ERROR_OK) {
tr_error("Socket %d create %s error %d", find_socket_index(socket), addr.get_ip_address(), ret_val);
return ret_val;
}
}
/* Check parameters - sendto address is valid and stack type supports sending to that address type*/
if (!is_addr_stack_compatible(addr)) {
return NSAPI_ERROR_PARAMETER;
}
_at.lock();
ret_val = socket_sendto_impl(socket, addr, data, size);
_at.unlock();
if (ret_val >= 0) {
tr_info("Socket %d sent %d bytes to %s port %d", find_socket_index(socket), ret_val, addr.get_ip_address(), addr.get_port());
} else if (ret_val != NSAPI_ERROR_WOULD_BLOCK) {
tr_error("Socket %d sendto %s error %d", find_socket_index(socket), addr.get_ip_address(), ret_val);
}
return ret_val;
}
nsapi_size_or_error_t AT_CellularStack::socket_recv(nsapi_socket_t handle, void *data, unsigned size)
{
return socket_recvfrom(handle, NULL, data, size);
}
nsapi_size_or_error_t AT_CellularStack::socket_recvfrom(nsapi_socket_t handle, SocketAddress *addr, void *buffer, unsigned size)
{
CellularSocket *socket = (CellularSocket *)handle;
if (!socket) {
return NSAPI_ERROR_NO_SOCKET;
}
if (socket->closed) {
tr_info("recvfrom socket %d closed", socket->id);
return 0;
}
nsapi_size_or_error_t ret_val = NSAPI_ERROR_OK;
if (socket->id == -1) {
_at.lock();
ret_val = create_socket_impl(socket);
_at.unlock();
if (ret_val != NSAPI_ERROR_OK) {
tr_error("Socket %d create error %d", find_socket_index(socket), ret_val);
return ret_val;
}
}
_at.lock();
ret_val = socket_recvfrom_impl(socket, addr, buffer, size);
_at.unlock();
if (socket->closed) {
tr_info("recvfrom socket %d closed", socket->id);
return 0;
}
if (ret_val >= 0) {
if (addr) {
tr_info("Socket %d recv %d bytes from %s port %d", find_socket_index(socket), ret_val, addr->get_ip_address(), addr->get_port());
} else {
tr_info("Socket %d recv %d bytes", find_socket_index(socket), ret_val);
}
} else if (ret_val != NSAPI_ERROR_WOULD_BLOCK) {
tr_error("Socket %d recv error %d", find_socket_index(socket), ret_val);
}
return ret_val;
}
void AT_CellularStack::socket_attach(nsapi_socket_t handle, void (*callback)(void *), void *data)
{
CellularSocket *socket = (CellularSocket *)handle;
if (!socket) {
return;
}
socket->_cb = callback;
socket->_data = data;
}
int AT_CellularStack::get_socket_index_by_port(uint16_t port)
{
for (int i = 0; i < _device.get_property(AT_CellularDevice::PROPERTY_SOCKET_COUNT); i++) {
if (_socket[i] != 0) {
if (_socket[i]->localAddress.get_port() == port) {
return i;
}
}
}
return -1;
}
AT_CellularStack::CellularSocket *AT_CellularStack::find_socket(int sock_id)
{
CellularSocket *sock = NULL;
for (int i = 0; i < _device.get_property(AT_CellularDevice::PROPERTY_SOCKET_COUNT); i++) {
if (_socket[i] && _socket[i]->id == sock_id) {
sock = _socket[i];
break;
}
}
if (!sock) {
tr_error("Socket not found %d", sock_id);
}
return sock;
}
bool AT_CellularStack::is_addr_stack_compatible(const SocketAddress &addr)
{
if ((addr.get_ip_version() == NSAPI_UNSPEC) ||
(addr.get_ip_version() == NSAPI_IPv4 && _stack_type == IPV6_STACK) ||
(addr.get_ip_version() == NSAPI_IPv6 && _stack_type == IPV4_STACK)) {
return false;
}
return true;
}
