cc3000 driver with expanded buffers.
Fork of cc3000_hostdriver_mbedsocket by
cc3000_event.cpp
- Committer:
- Kojto
- Date:
- 2013-11-06
- Revision:
- 45:50ab13d8f2dc
- Parent:
- 44:960b73df5981
- Child:
- 54:cae3dfc6df20
File content as of revision 45:50ab13d8f2dc:
/***************************************************************************** * * C++ interface/implementation created by Martin Kojtal (0xc0170). Thanks to * Jim Carver and Frank Vannieuwkerke for their inital cc3000 mbed port and * provided help. * * This version of "host driver" uses CC3000 Host Driver Implementation. Thus * read the following copyright: * * Copyright (C) 2011 Texas Instruments Incorporated - http://www.ti.com/ * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the * distribution. * * Neither the name of Texas Instruments Incorporated nor the names of * its contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * *****************************************************************************/ #include "cc3000.h" #include "cc3000_event.h" #include "cc3000_netapp.h" namespace mbed_cc3000 { #if (CC3000_DEBUG_HCI_RX == 1) const char *HCI_EVENT_STR[] = { "Socket", "Bind", "Send", "Recv", "Accept", "Listen", "Connect", "BSD Select", "Set Socket Options", "Get Socket Options", "Close Socket", "Unknown", "Recv From", "Write", "Send To", "Get Hostname", "mDNS Advertise" }; const char *HCI_NETAPP_STR[] = { "DHCP", "Ping Sent", "Ping Report", "Ping Stop", "IP Config", "ARP Flush", "Unknown", "Set Debug level", "Set Timers" }; // from 0-7 const char *HCI_MISC_STR[] = { "BASE - Error?", "Connecting", "Disconnect", "Scan Param", "Connect Policy", "Add Profile", "Del Profile", "Get Scan Res", "Event Mask", "Status Req", "Config Start", "Config Stop", "Config Set Prefix", "Config Patch", }; #endif cc3000_event::cc3000_event(cc3000_simple_link &simplelink, cc3000_hci &hci, cc3000_spi &spi, cc3000 &cc3000) : socket_active_status(SOCKET_STATUS_INIT_VAL), _simple_link(simplelink), _hci(hci), _spi(spi), _cc3000(cc3000) { } cc3000_event::~cc3000_event() { } /* TODO removed buffer, set it in init */ void cc3000_event::received_handler(uint8_t *buffer) { _simple_link.set_data_received_flag(1); _simple_link.set_received_data(buffer); hci_unsolicited_event_handler(); } void cc3000_event::hci_unsol_handle_patch_request(uint8_t *event_hdr) { uint8_t *params = (uint8_t *)(event_hdr) + HCI_EVENT_HEADER_SIZE; uint32_t length = 0; uint8_t *patch; switch (*params) { case HCI_EVENT_PATCHES_DRV_REQ: { tDriverPatches func_pointer = (tDriverPatches)_simple_link.get_func_pointer(DRIVER_PATCHES); if (func_pointer) { patch = func_pointer(&length); if (patch) { _hci.patch_send(HCI_EVENT_PATCHES_DRV_REQ, _simple_link.get_transmit_buffer(), patch, length); return; } } // Send 0 length Patches response event _hci.patch_send(HCI_EVENT_PATCHES_DRV_REQ, _simple_link.get_transmit_buffer(), 0, 0); break; } case HCI_EVENT_PATCHES_FW_REQ: { tFWPatches func_pointer = (tFWPatches)_simple_link.get_func_pointer(FW_PATCHES); if (func_pointer) { patch = func_pointer(&length); // Build and send a patch if (patch) { _hci.patch_send(HCI_EVENT_PATCHES_FW_REQ, _simple_link.get_transmit_buffer(), patch, length); return; } } // Send 0 length Patches response event _hci.patch_send(HCI_EVENT_PATCHES_FW_REQ, _simple_link.get_transmit_buffer(), 0, 0); break; } case HCI_EVENT_PATCHES_BOOTLOAD_REQ: { tBootLoaderPatches func_pointer = (tBootLoaderPatches)_simple_link.get_func_pointer(BOOTLOADER_PATCHES); if (func_pointer) { patch = func_pointer(&length); if (patch) { _hci.patch_send(HCI_EVENT_PATCHES_BOOTLOAD_REQ, _simple_link.get_transmit_buffer(), patch, length); return; } } // Send 0 length Patches response event _hci.patch_send(HCI_EVENT_PATCHES_BOOTLOAD_REQ, _simple_link.get_transmit_buffer(), 0, 0); break; } } } static void hci_event_debug_print(uint16_t hciEventNo) { #if (CC3000_DEBUG_HCI_RX == 1) if ((hciEventNo > HCI_CMND_SOCKET_BASE) && ( hciEventNo <= HCI_CMND_MDNS_ADVERTISE)) { DBG_HCI("Event Received : 0x%04X - %s", hciEventNo, HCI_EVENT_STR[hciEventNo-HCI_CMND_SOCKET]); } else if ((hciEventNo > HCI_CMND_NETAPP_BASE) && ( hciEventNo <= HCI_NETAPP_SET_TIMERS)) { DBG_HCI("Event Received : 0x%04X - %s", hciEventNo, HCI_NETAPP_STR[hciEventNo-HCI_NETAPP_DHCP]); } else if (hciEventNo < HCI_CMND_WLAN_CONFIGURE_PATCH+1) { DBG_HCI("Event Received : 0x%04X - %s", hciEventNo, HCI_MISC_STR[hciEventNo]); } else { DBG_HCI("Event Received : 0x%04X", hciEventNo); } #endif } uint8_t *cc3000_event::hci_event_handler(void *ret_param, uint8_t *from, uint8_t *fromlen) { uint8_t *received_data, argument_size; uint16_t length; uint8_t *pucReceivedParams; uint16_t received_op_code = 0; uint32_t return_value; uint8_t * RecvParams; uint8_t *RetParams; while (1) { if (_simple_link.get_data_received_flag() != 0) { received_data = _simple_link.get_received_data(); if (*received_data == HCI_TYPE_EVNT) { // Event Received STREAM_TO_UINT16((uint8_t *)received_data, HCI_EVENT_OPCODE_OFFSET,received_op_code); pucReceivedParams = received_data + HCI_EVENT_HEADER_SIZE; RecvParams = pucReceivedParams; RetParams = (uint8_t *)ret_param; // unsolicited event received - finish handling if (hci_unsol_event_handler((uint8_t *)received_data) == 0) { STREAM_TO_UINT8(received_data, HCI_DATA_LENGTH_OFFSET, length); hci_event_debug_print( received_op_code ); switch(received_op_code) { case HCI_CMND_READ_BUFFER_SIZE: { uint16_t temp = _simple_link.get_number_free_buffers(); STREAM_TO_UINT8((uint8_t *)pucReceivedParams, 0, temp); _simple_link.set_number_free_buffers(temp); temp = _simple_link.get_buffer_length(); STREAM_TO_UINT16((uint8_t *)pucReceivedParams, 1, temp); _simple_link.set_buffer_length(temp); } break; case HCI_CMND_WLAN_CONFIGURE_PATCH: case HCI_NETAPP_DHCP: case HCI_NETAPP_PING_SEND: case HCI_NETAPP_PING_STOP: case HCI_NETAPP_ARP_FLUSH: case HCI_NETAPP_SET_DEBUG_LEVEL: case HCI_NETAPP_SET_TIMERS: case HCI_EVNT_NVMEM_READ: case HCI_EVNT_NVMEM_CREATE_ENTRY: case HCI_CMND_NVMEM_WRITE_PATCH: case HCI_NETAPP_PING_REPORT: case HCI_EVNT_MDNS_ADVERTISE: STREAM_TO_UINT8(received_data, HCI_EVENT_STATUS_OFFSET, *(uint8_t *)ret_param); break; case HCI_CMND_SETSOCKOPT: case HCI_CMND_WLAN_CONNECT: case HCI_CMND_WLAN_IOCTL_STATUSGET: case HCI_EVNT_WLAN_IOCTL_ADD_PROFILE: case HCI_CMND_WLAN_IOCTL_DEL_PROFILE: case HCI_CMND_WLAN_IOCTL_SET_CONNECTION_POLICY: case HCI_CMND_WLAN_IOCTL_SET_SCANPARAM: case HCI_CMND_WLAN_IOCTL_SIMPLE_CONFIG_START: case HCI_CMND_WLAN_IOCTL_SIMPLE_CONFIG_STOP: case HCI_CMND_WLAN_IOCTL_SIMPLE_CONFIG_SET_PREFIX: case HCI_CMND_EVENT_MASK: case HCI_EVNT_WLAN_DISCONNECT: case HCI_EVNT_SOCKET: case HCI_EVNT_BIND: case HCI_CMND_LISTEN: case HCI_EVNT_CLOSE_SOCKET: case HCI_EVNT_CONNECT: case HCI_EVNT_NVMEM_WRITE: STREAM_TO_UINT32((uint8_t *)pucReceivedParams,0, *(uint32_t *)ret_param); break; case HCI_EVNT_READ_SP_VERSION: STREAM_TO_UINT8(received_data, HCI_EVENT_STATUS_OFFSET, *(uint8_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 1; STREAM_TO_UINT32((uint8_t *)pucReceivedParams, 0, return_value); UINT32_TO_STREAM((uint8_t *)ret_param, return_value); break; case HCI_EVNT_BSD_GETHOSTBYNAME: STREAM_TO_UINT32((uint8_t *)pucReceivedParams,GET_HOST_BY_NAME_RETVAL_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,GET_HOST_BY_NAME_ADDR_OFFSET,*(uint32_t *)ret_param); break; case HCI_EVNT_ACCEPT: { STREAM_TO_UINT32((uint8_t *)pucReceivedParams,ACCEPT_SD_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,ACCEPT_RETURN_STATUS_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; //This argument returns in network order memcpy((uint8_t *)ret_param, pucReceivedParams + ACCEPT_ADDRESS__OFFSET, sizeof(sockaddr)); break; } case HCI_EVNT_RECV: case HCI_EVNT_RECVFROM: { STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SL_RECEIVE_SD_OFFSET ,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SL_RECEIVE_NUM_BYTES_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SL_RECEIVE__FLAGS__OFFSET,*(uint32_t *)ret_param); if(((tBsdReadReturnParams *)ret_param)->iNumberOfBytes == ERROR_SOCKET_INACTIVE) { set_socket_active_status(((tBsdReadReturnParams *)ret_param)->iSocketDescriptor,SOCKET_STATUS_INACTIVE); } break; } case HCI_EVNT_SEND: case HCI_EVNT_SENDTO: { STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SL_RECEIVE_SD_OFFSET ,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SL_RECEIVE_NUM_BYTES_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; break; } case HCI_EVNT_SELECT: { STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SELECT_STATUS_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SELECT_READFD_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SELECT_WRITEFD_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,SELECT_EXFD_OFFSET,*(uint32_t *)ret_param); break; } case HCI_CMND_GETSOCKOPT: STREAM_TO_UINT8(received_data, HCI_EVENT_STATUS_OFFSET,((tBsdGetSockOptReturnParams *)ret_param)->iStatus); //This argument returns in network order memcpy((uint8_t *)ret_param, pucReceivedParams, 4); break; case HCI_CMND_WLAN_IOCTL_GET_SCAN_RESULTS: STREAM_TO_UINT32((uint8_t *)pucReceivedParams,GET_SCAN_RESULTS_TABlE_COUNT_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT32((uint8_t *)pucReceivedParams,GET_SCAN_RESULTS_SCANRESULT_STATUS_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 4; STREAM_TO_UINT16((uint8_t *)pucReceivedParams,GET_SCAN_RESULTS_ISVALID_TO_SSIDLEN_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 2; STREAM_TO_UINT16((uint8_t *)pucReceivedParams,GET_SCAN_RESULTS_FRAME_TIME_OFFSET,*(uint32_t *)ret_param); ret_param = ((uint8_t *)ret_param) + 2; memcpy((uint8_t *)ret_param, (uint8_t *)(pucReceivedParams + GET_SCAN_RESULTS_FRAME_TIME_OFFSET + 2), GET_SCAN_RESULTS_SSID_MAC_LENGTH); break; case HCI_CMND_SIMPLE_LINK_START: break; case HCI_NETAPP_IPCONFIG: //Read IP address STREAM_TO_STREAM(RecvParams,RetParams,NETAPP_IPCONFIG_IP_LENGTH); RecvParams += 4; //Read subnet STREAM_TO_STREAM(RecvParams,RetParams,NETAPP_IPCONFIG_IP_LENGTH); RecvParams += 4; //Read default GW STREAM_TO_STREAM(RecvParams,RetParams,NETAPP_IPCONFIG_IP_LENGTH); RecvParams += 4; //Read DHCP server STREAM_TO_STREAM(RecvParams,RetParams,NETAPP_IPCONFIG_IP_LENGTH); RecvParams += 4; //Read DNS server STREAM_TO_STREAM(RecvParams,RetParams,NETAPP_IPCONFIG_IP_LENGTH); RecvParams += 4; //Read Mac address STREAM_TO_STREAM(RecvParams,RetParams,NETAPP_IPCONFIG_MAC_LENGTH); RecvParams += 6; //Read SSID STREAM_TO_STREAM(RecvParams,RetParams,NETAPP_IPCONFIG_SSID_LENGTH); break; default : DBG_HCI("UNKNOWN Event Received : 0x%04X ", received_op_code); break; } } if (received_op_code == _simple_link.get_op_code()) { _simple_link.set_op_code(0); } } else { pucReceivedParams = received_data; STREAM_TO_UINT8((uint8_t *)received_data, HCI_PACKET_ARGSIZE_OFFSET, argument_size); STREAM_TO_UINT16((uint8_t *)received_data, HCI_PACKET_LENGTH_OFFSET, length); // Data received: note that the only case where from and from length // are not null is in recv from, so fill the args accordingly if (from) { STREAM_TO_UINT32((uint8_t *)(received_data + HCI_DATA_HEADER_SIZE), BSD_RECV_FROM_FROMLEN_OFFSET, *(uint32_t *)fromlen); memcpy(from, (received_data + HCI_DATA_HEADER_SIZE + BSD_RECV_FROM_FROM_OFFSET) ,*fromlen); } memcpy(ret_param, pucReceivedParams + HCI_DATA_HEADER_SIZE + argument_size, length - argument_size); _simple_link.set_pending_data(0); } _simple_link.set_data_received_flag(0); _spi.wlan_irq_enable(); // Since we are going to TX - we need to handle this event after the ResumeSPi since we need interrupts if ((*received_data == HCI_TYPE_EVNT) && (received_op_code == HCI_EVNT_PATCHES_REQ)) { hci_unsol_handle_patch_request((uint8_t *)received_data); } if ((_simple_link.get_op_code() == 0) && (_simple_link.get_pending_data() == 0)) { return NULL; } } } } int32_t cc3000_event::hci_unsol_event_handler(uint8_t *event_hdr) { uint8_t *data = NULL; int32_t event_type; uint32_t number_of_released_packets; uint32_t number_of_sent_packets; STREAM_TO_UINT16(event_hdr, HCI_EVENT_OPCODE_OFFSET,event_type); if (event_type & HCI_EVNT_UNSOL_BASE) { switch(event_type) { case HCI_EVNT_DATA_UNSOL_FREE_BUFF: { hci_event_unsol_flowcontrol_handler(event_hdr); number_of_released_packets = _simple_link.get_released_packets(); number_of_sent_packets = _simple_link.get_sent_packets(); if (number_of_released_packets == number_of_sent_packets) { if (_simple_link.get_tx_complete_signal()) { //tWlanCB func_pointer = (tWlanCB)_simple_link.get_func_pointer(WLAN_CB); _cc3000.usync_callback(HCI_EVENT_CC3000_CAN_SHUT_DOWN, NULL, 0); } } return 1; } } } if (event_type & HCI_EVNT_WLAN_UNSOL_BASE) { switch(event_type) { case HCI_EVNT_WLAN_KEEPALIVE: case HCI_EVNT_WLAN_UNSOL_CONNECT: case HCI_EVNT_WLAN_UNSOL_DISCONNECT: case HCI_EVNT_WLAN_UNSOL_INIT: case HCI_EVNT_WLAN_ASYNC_SIMPLE_CONFIG_DONE: _cc3000.usync_callback(event_type, 0, 0); break; case HCI_EVNT_WLAN_UNSOL_DHCP: { uint8_t params[NETAPP_IPCONFIG_MAC_OFFSET + 1]; // extra byte is for the status uint8_t *recParams = params; data = (uint8_t *)(event_hdr) + HCI_EVENT_HEADER_SIZE; //Read IP address STREAM_TO_STREAM(data,recParams,NETAPP_IPCONFIG_IP_LENGTH); data += 4; //Read subnet STREAM_TO_STREAM(data,recParams,NETAPP_IPCONFIG_IP_LENGTH); data += 4; //Read default GW STREAM_TO_STREAM(data,recParams,NETAPP_IPCONFIG_IP_LENGTH); data += 4; //Read DHCP server STREAM_TO_STREAM(data,recParams,NETAPP_IPCONFIG_IP_LENGTH); data += 4; //Read DNS server STREAM_TO_STREAM(data,recParams,NETAPP_IPCONFIG_IP_LENGTH); // read the status STREAM_TO_UINT8(event_hdr, HCI_EVENT_STATUS_OFFSET, *recParams); _cc3000.usync_callback(event_type, (uint8_t *)params, sizeof(params)); break; } case HCI_EVNT_WLAN_ASYNC_PING_REPORT: { netapp_pingreport_args_t params; data = (uint8_t *)(event_hdr) + HCI_EVENT_HEADER_SIZE; STREAM_TO_UINT32(data, NETAPP_PING_PACKETS_SENT_OFFSET, params.packets_sent); STREAM_TO_UINT32(data, NETAPP_PING_PACKETS_RCVD_OFFSET, params.packets_received); STREAM_TO_UINT32(data, NETAPP_PING_MIN_RTT_OFFSET, params.min_round_time); STREAM_TO_UINT32(data, NETAPP_PING_MAX_RTT_OFFSET, params.max_round_time); STREAM_TO_UINT32(data, NETAPP_PING_AVG_RTT_OFFSET, params.avg_round_time); _cc3000.usync_callback(event_type, (uint8_t *)¶ms, sizeof(params)); break; } case HCI_EVNT_BSD_TCP_CLOSE_WAIT: { _cc3000.usync_callback(event_type, NULL, 0); break; } //'default' case which means "event not supported" default: return (0); } return(1); } if ((event_type == HCI_EVNT_SEND) || (event_type == HCI_EVNT_SENDTO) || (event_type == HCI_EVNT_WRITE)) { uint8_t *pArg; int32_t status; pArg = M_BSD_RESP_PARAMS_OFFSET(event_hdr); STREAM_TO_UINT32(pArg, BSD_RSP_PARAMS_STATUS_OFFSET,status); if (ERROR_SOCKET_INACTIVE == status) { // The only synchronous event that can come from SL device in form of // command complete is "Command Complete" on data sent, in case SL device // was unable to transmit int32_t transmit_error = _simple_link.get_transmit_error(); STREAM_TO_UINT8(event_hdr, HCI_EVENT_STATUS_OFFSET, transmit_error); _simple_link.set_transmit_error(transmit_error); update_socket_active_status(M_BSD_RESP_PARAMS_OFFSET(event_hdr)); return (1); } else { return (0); } } return(0); } int32_t cc3000_event::hci_unsolicited_event_handler(void) { uint32_t res = 0; uint8_t *received_data; if (_simple_link.get_data_received_flag() != 0) { received_data = (_simple_link.get_received_data()); if (*received_data == HCI_TYPE_EVNT) { // unsolicited event received - finish handling if (hci_unsol_event_handler((uint8_t *)received_data) == 1) { // An unsolicited event was received: // release the buffer and clean the event received _simple_link.set_data_received_flag(0); res = 1; _spi.wlan_irq_enable(); } } } return res; } void cc3000_event::set_socket_active_status(int32_t sd, int32_t status) { if (M_IS_VALID_SD(sd) && M_IS_VALID_STATUS(status)) { socket_active_status &= ~(1 << sd); /* clean socket's mask */ socket_active_status |= (status << sd); /* set new socket's mask */ } } int32_t cc3000_event::hci_event_unsol_flowcontrol_handler(uint8_t *event) { int32_t temp, value; uint16_t i; uint16_t pusNumberOfHandles=0; uint8_t *pReadPayload; STREAM_TO_UINT16((uint8_t *)event,HCI_EVENT_HEADER_SIZE,pusNumberOfHandles); pReadPayload = ((uint8_t *)event + HCI_EVENT_HEADER_SIZE + sizeof(pusNumberOfHandles)); temp = 0; for(i = 0; i < pusNumberOfHandles; i++) { STREAM_TO_UINT16(pReadPayload, FLOW_CONTROL_EVENT_FREE_BUFFS_OFFSET, value); temp += value; pReadPayload += FLOW_CONTROL_EVENT_SIZE; } _simple_link.set_number_free_buffers(_simple_link.get_number_free_buffers() + temp); _simple_link.set_number_of_released_packets(_simple_link.get_released_packets() + temp); return(ESUCCESS); } int32_t cc3000_event::get_socket_active_status(int32_t sd) { if (M_IS_VALID_SD(sd)) { return (socket_active_status & (1 << sd)) ? SOCKET_STATUS_INACTIVE : SOCKET_STATUS_ACTIVE; } else { return SOCKET_STATUS_INACTIVE; } } void cc3000_event::update_socket_active_status(uint8_t *resp_params) { int32_t status, sd; STREAM_TO_UINT32(resp_params, BSD_RSP_PARAMS_SOCKET_OFFSET,sd); STREAM_TO_UINT32(resp_params, BSD_RSP_PARAMS_STATUS_OFFSET,status); if (ERROR_SOCKET_INACTIVE == status) { set_socket_active_status(sd, SOCKET_STATUS_INACTIVE); } } void cc3000_event::simplelink_wait_event(uint16_t op_code, void *ret_param) { // In the blocking implementation the control to caller will be returned only // after the end of current transaction _simple_link.set_op_code(op_code); hci_event_handler(ret_param, 0, 0); } void cc3000_event::simplelink_wait_data(uint8_t *pBuf, uint8_t *from, uint8_t *fromlen) { // In the blocking implementation the control to caller will be returned only // after the end of current transaction, i.e. only after data will be received _simple_link.set_pending_data(1); hci_event_handler(pBuf, from, fromlen); } } // end of cc3000