/* * Copyright (C) 2012-2019 NXP Semiconductors * * 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 #include #include #include #include #include #include #include #include #include #include #include #include #include "NfccPowerTracker.h" #include "hal_nxpese.h" #include "hal_nxpnfc.h" #include "spi_spm.h" using namespace android::hardware::nfc::V1_1; using namespace android::hardware::nfc::V1_2; using android::hardware::nfc::V1_1::NfcEvent; /*********************** Global Variables *************************************/ #define PN547C2_CLOCK_SETTING #define CORE_RES_STATUS_BYTE 3 bool bEnableMfcExtns = false; bool bEnableMfcReader = false; bool bDisableLegacyMfcExtns = true; /* Processing of ISO 15693 EOF */ extern uint8_t icode_send_eof; extern uint8_t icode_detected; static uint8_t cmd_icode_eof[] = {0x00, 0x00, 0x00}; /* FW download success flag */ static uint8_t fw_download_success = 0; static uint8_t config_access = false; static uint8_t config_success = true; static ThreadMutex sHalFnLock; /* NCI HAL Control structure */ phNxpNciHal_Control_t nxpncihal_ctrl; /* NXP Poll Profile structure */ phNxpNciProfile_Control_t nxpprofile_ctrl; /* TML Context */ extern phTmlNfc_Context_t* gpphTmlNfc_Context; extern void phTmlNfc_set_fragmentation_enabled( phTmlNfc_i2cfragmentation_t result); /* global variable to get FW version from NCI response*/ uint32_t wFwVerRsp; EseAdaptation* gpEseAdapt = NULL; /* External global variable to get FW version */ extern uint16_t wFwVer; extern uint16_t fw_maj_ver; extern uint16_t rom_version; extern uint8_t gRecFWDwnld; static uint8_t gRecFwRetryCount; // variable to hold recovery FW retry count static uint8_t Rx_data[NCI_MAX_DATA_LEN]; extern int phPalEse_spi_ioctl(phPalEse_ControlCode_t eControlCode, void* pDevHandle, long level); uint32_t timeoutTimerId = 0; bool nfc_debug_enabled = true; static bool sIsForceFwDownloadReqd = false; /* Used to send Callback Transceive data during Mifare Write. * If this flag is enabled, no need to send response to Upper layer */ bool sendRspToUpperLayer = true; phNxpNciHal_Sem_t config_data; phNxpNciClock_t phNxpNciClock = {0, {0}, false}; phNxpNciRfSetting_t phNxpNciRfSet = {false, {0}}; phNxpNciMwEepromArea_t phNxpNciMwEepromArea = {false, {0}}; /**************** local methods used in this file only ************************/ static NFCSTATUS phNxpNciHal_fw_download(void); static void phNxpNciHal_open_complete(NFCSTATUS status); static void phNxpNciHal_MinOpen_complete(NFCSTATUS status); static void phNxpNciHal_write_complete(void* pContext, phTmlNfc_TransactInfo_t* pInfo); static void phNxpNciHal_read_complete(void* pContext, phTmlNfc_TransactInfo_t* pInfo); static void phNxpNciHal_close_complete(NFCSTATUS status); static void phNxpNciHal_core_initialized_complete(NFCSTATUS status); static void phNxpNciHal_power_cycle_complete(NFCSTATUS status); static void phNxpNciHal_kill_client_thread( phNxpNciHal_Control_t* p_nxpncihal_ctrl); static void* phNxpNciHal_client_thread(void* arg); static void phNxpNciHal_get_clk_freq(void); static void phNxpNciHal_set_clock(void); static void phNxpNciHal_hci_network_reset(void); static NFCSTATUS phNxpNciHal_do_se_session_reset(void); static void phNxpNciHal_print_res_status(uint8_t* p_rx_data, uint16_t* p_len); static NFCSTATUS phNxpNciHal_CheckValidFwVersion(void); static void phNxpNciHal_enable_i2c_fragmentation(); static NFCSTATUS phNxpNciHal_get_mw_eeprom(void); static NFCSTATUS phNxpNciHal_set_mw_eeprom(void); static int phNxpNciHal_fw_mw_ver_check(); NFCSTATUS phNxpNciHal_check_clock_config(void); NFCSTATUS phNxpNciHal_china_tianjin_rf_setting(void); static void phNxpNciHal_gpio_restore(phNxpNciHal_GpioInfoState state); static void phNxpNciHal_initialize_debug_enabled_flag(); static void phNxpNciHal_initialize_mifare_flag(); NFCSTATUS phNxpNciHal_nfcc_core_reset_init(); NFCSTATUS phNxpNciHal_getChipInfoInFwDnldMode(void); static NFCSTATUS phNxpNciHalRFConfigCmdRecSequence(); static NFCSTATUS phNxpNciHal_CheckRFCmdRespStatus(); int check_config_parameter(); #ifdef FactoryOTA void phNxpNciHal_isFactoryOTAModeActive(); static NFCSTATUS phNxpNciHal_disableFactoryOTAMode(void); #endif /****************************************************************************** * Function phNxpNciHal_initialize_debug_enabled_flag * * Description This function gets the value for nfc_debug_enabled * * Returns void * ******************************************************************************/ static void phNxpNciHal_initialize_debug_enabled_flag() { unsigned long num = 0; char valueStr[PROPERTY_VALUE_MAX] = {0}; if (GetNxpNumValue(NAME_NFC_DEBUG_ENABLED, &num, sizeof(num))) { nfc_debug_enabled = (num == 0) ? false : true; } int len = property_get("nfc.debug_enabled", valueStr, ""); if (len > 0) { // let Android property override .conf variable unsigned debug_enabled = 0; sscanf(valueStr, "%u", &debug_enabled); nfc_debug_enabled = (debug_enabled == 0) ? false : true; } NXPLOG_NCIHAL_D("nfc_debug_enabled : %d", nfc_debug_enabled); } /****************************************************************************** * Function phNxpNciHal_client_thread * * Description This function is a thread handler which handles all TML and * NCI messages. * * Returns void * ******************************************************************************/ static void* phNxpNciHal_client_thread(void* arg) { phNxpNciHal_Control_t* p_nxpncihal_ctrl = (phNxpNciHal_Control_t*)arg; phLibNfc_Message_t msg; NXPLOG_NCIHAL_D("thread started"); p_nxpncihal_ctrl->thread_running = 1; while (p_nxpncihal_ctrl->thread_running == 1) { /* Fetch next message from the NFC stack message queue */ if (phDal4Nfc_msgrcv(p_nxpncihal_ctrl->gDrvCfg.nClientId, &msg, 0, 0) == -1) { NXPLOG_NCIHAL_E("NFC client received bad message"); continue; } if (p_nxpncihal_ctrl->thread_running == 0) { break; } switch (msg.eMsgType) { case PH_LIBNFC_DEFERREDCALL_MSG: { phLibNfc_DeferredCall_t* deferCall = (phLibNfc_DeferredCall_t*)(msg.pMsgData); REENTRANCE_LOCK(); deferCall->pCallback(deferCall->pParameter); REENTRANCE_UNLOCK(); break; } case NCI_HAL_OPEN_CPLT_MSG: { REENTRANCE_LOCK(); if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /* Send the event */ (*nxpncihal_ctrl.p_nfc_stack_cback)(HAL_NFC_OPEN_CPLT_EVT, HAL_NFC_STATUS_OK); } REENTRANCE_UNLOCK(); break; } case NCI_HAL_CLOSE_CPLT_MSG: { REENTRANCE_LOCK(); if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /* Send the event */ (*nxpncihal_ctrl.p_nfc_stack_cback)(HAL_NFC_CLOSE_CPLT_EVT, HAL_NFC_STATUS_OK); } phNxpNciHal_kill_client_thread(&nxpncihal_ctrl); REENTRANCE_UNLOCK(); break; } case NCI_HAL_POST_INIT_CPLT_MSG: { REENTRANCE_LOCK(); if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /* Send the event */ (*nxpncihal_ctrl.p_nfc_stack_cback)(HAL_NFC_POST_INIT_CPLT_EVT, HAL_NFC_STATUS_OK); } REENTRANCE_UNLOCK(); break; } case NCI_HAL_PRE_DISCOVER_CPLT_MSG: { REENTRANCE_LOCK(); if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /* Send the event */ (*nxpncihal_ctrl.p_nfc_stack_cback)(HAL_NFC_PRE_DISCOVER_CPLT_EVT, HAL_NFC_STATUS_OK); } REENTRANCE_UNLOCK(); break; } case NCI_HAL_HCI_NETWORK_RESET_MSG: { REENTRANCE_LOCK(); if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /* Send the event */ (*nxpncihal_ctrl.p_nfc_stack_cback)( (uint32_t)NfcEvent::HCI_NETWORK_RESET, HAL_NFC_STATUS_OK); } REENTRANCE_UNLOCK(); break; } case NCI_HAL_ERROR_MSG: { REENTRANCE_LOCK(); if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /* Send the event */ (*nxpncihal_ctrl.p_nfc_stack_cback)(HAL_NFC_ERROR_EVT, HAL_NFC_STATUS_FAILED); } REENTRANCE_UNLOCK(); break; } case NCI_HAL_RX_MSG: { REENTRANCE_LOCK(); if (nxpncihal_ctrl.p_nfc_stack_data_cback != NULL) { (*nxpncihal_ctrl.p_nfc_stack_data_cback)(nxpncihal_ctrl.rsp_len, nxpncihal_ctrl.p_rsp_data); } REENTRANCE_UNLOCK(); break; } } } NXPLOG_NCIHAL_D("NxpNciHal thread stopped"); return NULL; } /****************************************************************************** * Function phNxpNciHal_kill_client_thread * * Description This function safely kill the client thread and clean all * resources. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_kill_client_thread( phNxpNciHal_Control_t* p_nxpncihal_ctrl) { NXPLOG_NCIHAL_D("Terminating phNxpNciHal client thread..."); p_nxpncihal_ctrl->p_nfc_stack_cback = NULL; p_nxpncihal_ctrl->p_nfc_stack_data_cback = NULL; p_nxpncihal_ctrl->thread_running = 0; return; } /****************************************************************************** * Function phNxpNciHal_fw_download * * Description This function download the PN54X secure firmware to IC. If * firmware version in Android filesystem and firmware in the * IC is same then firmware download will return with success * without downloading the firmware. * * Returns NFCSTATUS_SUCCESS if firmware download successful * NFCSTATUS_FAILED in case of failure * NFCSTATUS_REJECTED if FW version is invalid or if hardware * criteria is not matching * ******************************************************************************/ static NFCSTATUS phNxpNciHal_fw_download(void) { if (NFCSTATUS_SUCCESS != phNxpNciHal_CheckValidFwVersion()) { return NFCSTATUS_REJECTED; } nfc_nci_IoctlInOutData_t data; memset(&data, 0x00, sizeof(nfc_nci_IoctlInOutData_t)); data.inp.level = 0x03; // ioctl call arg value to get eSE power GPIO value = 0x03 int ese_gpio_value = phNxpNciHal_ioctl(HAL_NFC_GET_SPM_STATUS, &data); NXPLOG_NCIHAL_D("eSE Power GPIO value = %d", ese_gpio_value); if (ese_gpio_value != 0) { NXPLOG_NCIHAL_E("FW download denied while SPI in use, Continue NFC init"); return NFCSTATUS_REJECTED; } nxpncihal_ctrl.phNxpNciGpioInfo.state = GPIO_UNKNOWN; phNxpNciHal_gpio_restore(GPIO_STORE); int fw_retry_count = 0; NFCSTATUS status = NFCSTATUS_REJECTED; NXPLOG_NCIHAL_D("Starting FW update"); do { fw_download_success = 0; phNxpNciHal_get_clk_freq(); status = phTmlNfc_IoCtl(phTmlNfc_e_EnableDownloadMode); if (NFCSTATUS_SUCCESS != status) { fw_retry_count++; NXPLOG_NCIHAL_D("Retrying: FW download"); continue; } if (sIsForceFwDownloadReqd) { status = phNxpNciHal_getChipInfoInFwDnldMode(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Unknown chip type, FW can't be upgraded"); return status; } } /* Set the obtained device handle to download module */ phDnldNfc_SetHwDevHandle(); NXPLOG_NCIHAL_D("Calling Seq handler for FW Download \n"); status = phNxpNciHal_fw_download_seq(nxpprofile_ctrl.bClkSrcVal, nxpprofile_ctrl.bClkFreqVal); if (status != NFCSTATUS_SUCCESS) { phTmlNfc_ReadAbort(); phDnldNfc_ReSetHwDevHandle(); fw_retry_count++; NXPLOG_NCIHAL_D("Retrying: FW download"); android_errorWriteLog(0x534e4554, "192614125"); } } while ((fw_retry_count < 3) && (status != NFCSTATUS_SUCCESS)); if (status != NFCSTATUS_SUCCESS) { if (NFCSTATUS_SUCCESS != phNxpNciHal_fw_mw_ver_check()) { NXPLOG_NCIHAL_D("Chip Version Middleware Version mismatch!!!!"); phOsalNfc_Timer_Cleanup(); phTmlNfc_Shutdown_CleanUp(); status = NFCSTATUS_FAILED; } else { NXPLOG_NCIHAL_E("FW download failed, Continue NFCC init"); } } else { status = NFCSTATUS_SUCCESS; fw_download_success = 1; } /*Keep Read Pending on I2C*/ NFCSTATUS readRestoreStatus = NFCSTATUS_FAILED; readRestoreStatus = phTmlNfc_Read( nxpncihal_ctrl.p_cmd_data, NCI_MAX_DATA_LEN, (pphTmlNfc_TransactCompletionCb_t)&phNxpNciHal_read_complete, NULL); if (readRestoreStatus != NFCSTATUS_PENDING) { NXPLOG_NCIHAL_E("TML Read status error status = %x", readRestoreStatus); readRestoreStatus = phTmlNfc_Shutdown_CleanUp(); if (readRestoreStatus != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("TML Shutdown failed. Status = %x", readRestoreStatus); } } phDnldNfc_ReSetHwDevHandle(); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_nfcc_core_reset_init(); if (status == NFCSTATUS_SUCCESS) { phNxpNciHal_gpio_restore(GPIO_RESTORE); } else { NXPLOG_NCIHAL_D("Failed to restore GPIO values!!!\n"); } } return status; } /****************************************************************************** * Function phNxpNciHal_CheckValidFwVersion * * Description This function checks the valid FW for Mobile device. * If the FW doesn't belong the Mobile device it further * checks nxp config file to override. * * Returns NFCSTATUS_SUCCESS if valid fw version found * NFCSTATUS_NOT_ALLOWED in case of FW not valid for mobile * device * ******************************************************************************/ static NFCSTATUS phNxpNciHal_CheckValidFwVersion(void) { NFCSTATUS status = NFCSTATUS_NOT_ALLOWED; const unsigned char sfw_infra_major_no = 0x02; unsigned char ufw_current_major_no = 0x00; unsigned long num = 0; int isfound = 0; unsigned char fw_major_no = ((wFwVerRsp >> 8) & 0x000000FF); /* extract the firmware's major no */ ufw_current_major_no = ((0x00FF) & (wFwVer >> 8U)); if (ufw_current_major_no >= fw_major_no) { status = NFCSTATUS_SUCCESS; } else if (ufw_current_major_no == sfw_infra_major_no) { if (rom_version == FW_MOBILE_ROM_VERSION_PN553 && nxpncihal_ctrl.nci_info.nci_version == NCI_VERSION_2_0) { NXPLOG_NCIHAL_D(" PN81A allow Fw download with major number = 0x%x", ufw_current_major_no); status = NFCSTATUS_SUCCESS; } else { /* Check the nxp config file if still want to go for download */ /* By default NAME_NXP_FW_PROTECION_OVERRIDE will not be defined in config file. If user really want to override the Infra firmware over mobile firmware, please put "NXP_FW_PROTECION_OVERRIDE=0x01" in libnfc-nxp.conf file. Please note once Infra firmware downloaded to Mobile device, The device can never be updated to Mobile firmware*/ isfound = GetNxpNumValue(NAME_NXP_FW_PROTECION_OVERRIDE, &num, sizeof(num)); if (isfound > 0) { if (num == 0x01) { NXPLOG_NCIHAL_D("Override Infra FW over Mobile"); status = NFCSTATUS_SUCCESS; } else { NXPLOG_NCIHAL_D( "Firmware download not allowed (NXP_FW_PROTECION_OVERRIDE " "invalid value)"); } } else { NXPLOG_NCIHAL_D( "Firmware download not allowed (NXP_FW_PROTECION_OVERRIDE not " "defined)"); } } } else if (gRecFWDwnld == TRUE) { status = NFCSTATUS_SUCCESS; } else if (wFwVerRsp == 0) { NXPLOG_NCIHAL_E( "FW Version not received by NCI command >>> Force Firmware download"); status = NFCSTATUS_SUCCESS; } else { NXPLOG_NCIHAL_E("Wrong FW Version >>> Firmware download not allowed"); } return status; } static void phNxpNciHal_get_clk_freq(void) { unsigned long num = 0; int isfound = 0; nxpprofile_ctrl.bClkSrcVal = 0; nxpprofile_ctrl.bClkFreqVal = 0; nxpprofile_ctrl.bTimeout = 0; isfound = GetNxpNumValue(NAME_NXP_SYS_CLK_SRC_SEL, &num, sizeof(num)); if (isfound > 0) { nxpprofile_ctrl.bClkSrcVal = num; } num = 0; isfound = 0; isfound = GetNxpNumValue(NAME_NXP_SYS_CLK_FREQ_SEL, &num, sizeof(num)); if (isfound > 0) { nxpprofile_ctrl.bClkFreqVal = num; } num = 0; isfound = 0; isfound = GetNxpNumValue(NAME_NXP_SYS_CLOCK_TO_CFG, &num, sizeof(num)); if (isfound > 0) { nxpprofile_ctrl.bTimeout = num; } NXPLOG_FWDNLD_D("gphNxpNciHal_fw_IoctlCtx.bClkSrcVal = 0x%x", nxpprofile_ctrl.bClkSrcVal); NXPLOG_FWDNLD_D("gphNxpNciHal_fw_IoctlCtx.bClkFreqVal = 0x%x", nxpprofile_ctrl.bClkFreqVal); NXPLOG_FWDNLD_D("gphNxpNciHal_fw_IoctlCtx.bClkFreqVal = 0x%x", nxpprofile_ctrl.bTimeout); if ((nxpprofile_ctrl.bClkSrcVal < CLK_SRC_XTAL) || (nxpprofile_ctrl.bClkSrcVal > CLK_SRC_PLL)) { NXPLOG_FWDNLD_E( "Clock source value is wrong in config file, setting it as default"); nxpprofile_ctrl.bClkSrcVal = NXP_SYS_CLK_SRC_SEL; } if (nxpprofile_ctrl.bClkFreqVal == CLK_SRC_PLL && (nxpprofile_ctrl.bClkFreqVal < CLK_FREQ_13MHZ || nxpprofile_ctrl.bClkFreqVal > CLK_FREQ_52MHZ)) { NXPLOG_FWDNLD_E( "Clock frequency value is wrong in config file, setting it as default"); nxpprofile_ctrl.bClkFreqVal = NXP_SYS_CLK_FREQ_SEL; } if ((nxpprofile_ctrl.bTimeout < CLK_TO_CFG_DEF) || (nxpprofile_ctrl.bTimeout > CLK_TO_CFG_MAX)) { NXPLOG_FWDNLD_E( "Clock timeout value is wrong in config file, setting it as default"); nxpprofile_ctrl.bTimeout = CLK_TO_CFG_DEF; } } /****************************************************************************** * Function phNxpNciHal_MinOpen * * Description This function initializes the least required resources to * communicate to NFCC.This is mainly used to communicate to * NFCC when NFC service is not available. * * * Returns This function return NFCSTATUS_SUCCESS (0) in case of * success. In case of failure returns other failure value. * ******************************************************************************/ int phNxpNciHal_MinOpen() { phOsalNfc_Config_t tOsalConfig; phTmlNfc_Config_t tTmlConfig; char* nfc_dev_node = NULL; const uint16_t max_len = 260; NFCSTATUS wConfigStatus = NFCSTATUS_SUCCESS; NFCSTATUS status = NFCSTATUS_SUCCESS; NXPLOG_NCIHAL_D("phNxpNci_MinOpen(): enter"); /*NCI_INIT_CMD*/ static uint8_t cmd_init_nci[] = {0x20, 0x01, 0x00}; /*NCI_RESET_CMD*/ static uint8_t cmd_reset_nci[] = {0x20, 0x00, 0x01, 0x00}; /*NCI2_0_INIT_CMD*/ static uint8_t cmd_init_nci2_0[] = {0x20, 0x01, 0x02, 0x00, 0x00}; AutoThreadMutex a(sHalFnLock); if (nxpncihal_ctrl.halStatus == HAL_STATUS_MIN_OPEN) { NXPLOG_NCIHAL_D("phNxpNciHal_MinOpen(): already open"); return NFCSTATUS_SUCCESS; } /* reset config cache */ resetNxpConfig(); int init_retry_cnt = 0; int8_t ret_val = 0x00; phNxpNciHal_initialize_debug_enabled_flag(); /* initialize trace level */ phNxpLog_InitializeLogLevel(); /* initialize Mifare flags*/ phNxpNciHal_initialize_mifare_flag(); /*Create the timer for extns write response*/ timeoutTimerId = phOsalNfc_Timer_Create(); if (phNxpNciHal_init_monitor() == NULL) { NXPLOG_NCIHAL_E("Init monitor failed"); return NFCSTATUS_FAILED; } CONCURRENCY_LOCK(); memset(&nxpncihal_ctrl, 0x00, sizeof(nxpncihal_ctrl)); memset(&tOsalConfig, 0x00, sizeof(tOsalConfig)); memset(&tTmlConfig, 0x00, sizeof(tTmlConfig)); memset(&nxpprofile_ctrl, 0, sizeof(phNxpNciProfile_Control_t)); /*Init binary semaphore for Spi Nfc synchronization*/ if (0 != sem_init(&nxpncihal_ctrl.syncSpiNfc, 0, 1)) { NXPLOG_NCIHAL_E("sem_init() FAiled, errno = 0x%02X", errno); goto clean_and_return; } /* By default HAL status is HAL_STATUS_OPEN */ nxpncihal_ctrl.halStatus = HAL_STATUS_OPEN; gpEseAdapt = &EseAdaptation::GetInstance(); gpEseAdapt->Initialize(); /*nci version NCI_VERSION_UNKNOWN version by default*/ nxpncihal_ctrl.nci_info.nci_version = NCI_VERSION_UNKNOWN; /* Read the nfc device node name */ nfc_dev_node = (char*)malloc(max_len * sizeof(char)); if (nfc_dev_node == NULL) { NXPLOG_NCIHAL_D("malloc of nfc_dev_node failed "); goto clean_and_return; } else if (!GetNxpStrValue(NAME_NXP_NFC_DEV_NODE, nfc_dev_node, max_len)) { NXPLOG_NCIHAL_D( "Invalid nfc device node name keeping the default device node " "/dev/pn54x"); strlcpy(nfc_dev_node, "/dev/pn54x", (max_len * sizeof(char))); } /* Configure hardware link */ nxpncihal_ctrl.gDrvCfg.nClientId = phDal4Nfc_msgget(0, 0600); nxpncihal_ctrl.gDrvCfg.nLinkType = ENUM_LINK_TYPE_I2C; /* For PN54X */ tTmlConfig.pDevName = (int8_t*)nfc_dev_node; tOsalConfig.dwCallbackThreadId = (uintptr_t)nxpncihal_ctrl.gDrvCfg.nClientId; tOsalConfig.pLogFile = NULL; tTmlConfig.dwGetMsgThreadId = (uintptr_t)nxpncihal_ctrl.gDrvCfg.nClientId; /* Initialize TML layer */ wConfigStatus = phTmlNfc_Init(&tTmlConfig); if (wConfigStatus != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("phTmlNfc_Init Failed"); goto clean_and_return; } else { if (nfc_dev_node != NULL) { free(nfc_dev_node); nfc_dev_node = NULL; } } /* Create the client thread */ ret_val = pthread_create(&nxpncihal_ctrl.client_thread, NULL, phNxpNciHal_client_thread, &nxpncihal_ctrl); if (ret_val != 0) { NXPLOG_NCIHAL_E("pthread_create failed"); wConfigStatus = phTmlNfc_Shutdown_CleanUp(); goto clean_and_return; } CONCURRENCY_UNLOCK(); /* call read pending */ status = phTmlNfc_Read( nxpncihal_ctrl.p_cmd_data, NCI_MAX_DATA_LEN, (pphTmlNfc_TransactCompletionCb_t)&phNxpNciHal_read_complete, NULL); if (status != NFCSTATUS_PENDING) { NXPLOG_NCIHAL_E("TML Read status error status = %x", status); wConfigStatus = phTmlNfc_Shutdown_CleanUp(); wConfigStatus = NFCSTATUS_FAILED; goto clean_and_return; } phNxpNciHal_ext_init(); init_retry: status = phNxpNciHal_send_ext_cmd(sizeof(cmd_reset_nci), cmd_reset_nci); if (status == NFCSTATUS_SUCCESS) { sIsForceFwDownloadReqd = false; } else if (sIsForceFwDownloadReqd) { /* MinOpen can be called from either NFC on or any NFC IOCTL calls from * SPI HAL or system/nfc while Minopen is not done/success, which can * trigger Force FW update during every Minopen. To avoid multiple Force * Force FW upadted return if Force FW update is already done */ NXPLOG_NCIHAL_E("%s: Failed after Force FW updated. Exit", __func__); return NFCSTATUS_FAILED; } sIsForceFwDownloadReqd = (status != NFCSTATUS_SUCCESS) && (nxpncihal_ctrl.retry_cnt >= MAX_RETRY_COUNT); if (sIsForceFwDownloadReqd) { NXPLOG_NCIHAL_E("Force FW Download, NFCC not coming out from Standby"); wConfigStatus = NFCSTATUS_FAILED; goto force_download; } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_RESET: Failed"); if (init_retry_cnt < 3) { init_retry_cnt++; (void)phNxpNciHal_power_cycle(); goto init_retry; } else init_retry_cnt = 0; wConfigStatus = phTmlNfc_Shutdown_CleanUp(); wConfigStatus = NFCSTATUS_FAILED; goto clean_and_return; } if (nxpncihal_ctrl.nci_info.nci_version == NCI_VERSION_2_0) { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci2_0), cmd_init_nci2_0); } else { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci), cmd_init_nci); /*If chipType is pn557 or PN81A(PN553_TC) and if the chip is in 1.0 mode, Force it to 2.0 mode. To confirm the PN553_TC/PN81A chip, FW version check is also added */ bool pn81A_pn553_chip = (nfcFL.chipType == pn553) && ((wFwVerRsp >> 8 & 0xFFFF) == 0x1102); if ((status == NFCSTATUS_SUCCESS) && ((nfcFL.chipType == pn557) || pn81A_pn553_chip)) { NXPLOG_NCIHAL_D("Chip is in NCI1.0 mode reset the chip to 2.0 mode"); status = phNxpNciHal_send_ext_cmd(sizeof(cmd_reset_nci), cmd_reset_nci); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci2_0), cmd_init_nci2_0); if (status == NFCSTATUS_SUCCESS) { goto init_retry; } } } } if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_INIT : Failed"); if (init_retry_cnt < 3) { init_retry_cnt++; (void)phNxpNciHal_power_cycle(); goto init_retry; } else init_retry_cnt = 0; wConfigStatus = phTmlNfc_Shutdown_CleanUp(); wConfigStatus = NFCSTATUS_FAILED; goto clean_and_return; } phNxpNciHal_enable_i2c_fragmentation(); /*Get FW version from device*/ status = phDnldNfc_InitImgInfo(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Image information extraction Failed!!"); } NXPLOG_NCIHAL_D("FW version for FW file = 0x%x", wFwVer); NXPLOG_NCIHAL_D("FW version from device = 0x%x", wFwVerRsp); if ((wFwVerRsp & 0x0000FFFF) == wFwVer) { NXPLOG_NCIHAL_D("FW update not required"); phDnldNfc_ReSetHwDevHandle(); } else { force_download: status = phNxpNciHal_fw_download(); if (NFCSTATUS_FAILED == status) { wConfigStatus = NFCSTATUS_FAILED; NXPLOG_NCIHAL_D("FW download Failed"); goto clean_and_return; } else if (NFCSTATUS_REJECTED == status) { wConfigStatus = NFCSTATUS_SUCCESS; NXPLOG_NCIHAL_D("FW download Rejected. Continuiing Nfc Init"); } else { wConfigStatus = NFCSTATUS_SUCCESS; NXPLOG_NCIHAL_D("FW download Success"); } } NfccPowerTracker::getInstance().Initialize(); /* Call open complete */ phNxpNciHal_MinOpen_complete(wConfigStatus); NXPLOG_NCIHAL_D("phNxpNciHal_MinOpen(): exit"); return wConfigStatus; clean_and_return: CONCURRENCY_UNLOCK(); if (nfc_dev_node != NULL) { free(nfc_dev_node); nfc_dev_node = NULL; } /* Report error status */ phNxpNciHal_cleanup_monitor(); nxpncihal_ctrl.halStatus = HAL_STATUS_CLOSE; return NFCSTATUS_FAILED; } /****************************************************************************** * Function phNxpNciHal_open * * Description This function is called by libnfc-nci during the * initialization of the NFCC. It opens the physical connection * with NFCC (PN54X) and creates required client thread for * operation. * After open is complete, status is informed to libnfc-nci * through callback function. * * Returns This function return NFCSTATUS_SUCCESS (0) in case of * success. In case of failure returns other failure value. * ******************************************************************************/ int phNxpNciHal_open(nfc_stack_callback_t* p_cback, nfc_stack_data_callback_t* p_data_cback) { NFCSTATUS wConfigStatus = NFCSTATUS_SUCCESS; NFCSTATUS status = NFCSTATUS_SUCCESS; if (nxpncihal_ctrl.halStatus == HAL_STATUS_OPEN) { NXPLOG_NCIHAL_D("phNxpNciHal_open already open"); return NFCSTATUS_SUCCESS; } else if (nxpncihal_ctrl.halStatus == HAL_STATUS_CLOSE) { status = phNxpNciHal_MinOpen(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("phNxpNciHal_MinOpen failed"); goto clean_and_return; } } /*else its already in MIN_OPEN state. continue with rest of functionality*/ nxpncihal_ctrl.p_nfc_stack_cback = p_cback; nxpncihal_ctrl.p_nfc_stack_data_cback = p_data_cback; /* Call open complete */ phNxpNciHal_open_complete(wConfigStatus); return wConfigStatus; clean_and_return: CONCURRENCY_UNLOCK(); /* Report error status */ if (p_cback != NULL) { (*p_cback)(HAL_NFC_OPEN_CPLT_EVT, HAL_NFC_STATUS_FAILED); } nxpncihal_ctrl.p_nfc_stack_cback = NULL; nxpncihal_ctrl.p_nfc_stack_data_cback = NULL; phNxpNciHal_cleanup_monitor(); nxpncihal_ctrl.halStatus = HAL_STATUS_CLOSE; return NFCSTATUS_FAILED; } /****************************************************************************** * Function phNxpNciHal_fw_mw_check * * Description This function inform the status of phNxpNciHal_fw_mw_check * function to libnfc-nci. * * Returns int. * ******************************************************************************/ int phNxpNciHal_fw_mw_ver_check() { NFCSTATUS status = NFCSTATUS_FAILED; if (((nfcFL.chipType == pn557) || (nfcFL.chipType == pn81T)) && (rom_version == FW_MOBILE_ROM_VERSION_PN557) && (fw_maj_ver == 0x01)) { status = NFCSTATUS_SUCCESS; } else if (((nfcFL.chipType == pn553) || (nfcFL.chipType == pn80T)) && (rom_version == FW_MOBILE_ROM_VERSION_PN553) && (fw_maj_ver == 0x01 || fw_maj_ver == 0x02)) { status = NFCSTATUS_SUCCESS; } else if (((nfcFL.chipType == pn551) || (nfcFL.chipType == pn67T)) && (rom_version == FW_MOBILE_ROM_VERSION_PN551) && (fw_maj_ver == 0x05)) { status = NFCSTATUS_SUCCESS; } return status; } /****************************************************************************** * Function phNxpNciHal_MinOpen_complete * * Description This function updates the status of *phNxpNciHal_MinOpen_complete to halstatus. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_MinOpen_complete(NFCSTATUS status) { if (status == NFCSTATUS_SUCCESS) { nxpncihal_ctrl.halStatus = HAL_STATUS_MIN_OPEN; } return; } /****************************************************************************** * Function phNxpNciHal_open_complete * * Description This function inform the status of phNxpNciHal_open * function to libnfc-nci. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_open_complete(NFCSTATUS status) { static phLibNfc_Message_t msg; if (status == NFCSTATUS_SUCCESS) { msg.eMsgType = NCI_HAL_OPEN_CPLT_MSG; nxpncihal_ctrl.hal_open_status = true; nxpncihal_ctrl.halStatus = HAL_STATUS_OPEN; } else { msg.eMsgType = NCI_HAL_ERROR_MSG; } msg.pMsgData = NULL; msg.Size = 0; phTmlNfc_DeferredCall(gpphTmlNfc_Context->dwCallbackThreadId, (phLibNfc_Message_t*)&msg); return; } /****************************************************************************** * Function phNxpNciHal_write * * Description This function write the data to NFCC through physical * interface (e.g. I2C) using the PN54X driver interface. * Before sending the data to NFCC, phNxpNciHal_write_ext * is called to check if there is any extension processing * is required for the NCI packet being sent out. * * Returns It returns number of bytes successfully written to NFCC. * ******************************************************************************/ int phNxpNciHal_write(uint16_t data_len, const uint8_t* p_data) { if (bDisableLegacyMfcExtns && bEnableMfcExtns && p_data[0] == 0x00) { return NxpMfcReaderInstance.Write(data_len, p_data); } return phNxpNciHal_write_internal(data_len, p_data); } /****************************************************************************** * Function phNxpNciHal_write_internal * * Description This function write the data to NFCC through physical * interface (e.g. I2C) using the PN54X driver interface. * Before sending the data to NFCC, phNxpNciHal_write_ext * is called to check if there is any extension processing * is required for the NCI packet being sent out. * * Returns It returns number of bytes successfully written to NFCC. * ******************************************************************************/ int phNxpNciHal_write_internal(uint16_t data_len, const uint8_t* p_data) { NFCSTATUS status = NFCSTATUS_FAILED; static phLibNfc_Message_t msg; if (nxpncihal_ctrl.halStatus != HAL_STATUS_OPEN) { return NFCSTATUS_FAILED; } if (data_len > NCI_MAX_DATA_LEN) { NXPLOG_NCIHAL_E("cmd_len exceeds limit NCI_MAX_DATA_LEN"); android_errorWriteLog(0x534e4554, "121267042"); goto clean_and_return; } /* Create local copy of cmd_data */ memcpy(nxpncihal_ctrl.p_cmd_data, p_data, data_len); nxpncihal_ctrl.cmd_len = data_len; #ifdef P2P_PRIO_LOGIC_HAL_IMP /* Specific logic to block RF disable when P2P priority logic is busy */ if (data_len < NORMAL_MODE_HEADER_LEN) { /* Avoid OOB Read */ android_errorWriteLog(0x534e4554, "128530069"); } else if (p_data[0] == 0x21 && p_data[1] == 0x06 && p_data[2] == 0x01 && EnableP2P_PrioLogic == true) { NXPLOG_NCIHAL_D("P2P priority logic busy: Disable it."); phNxpNciHal_clean_P2P_Prio(); } #endif /* Check for NXP ext before sending write */ status = phNxpNciHal_write_ext(&nxpncihal_ctrl.cmd_len, nxpncihal_ctrl.p_cmd_data, &nxpncihal_ctrl.rsp_len, nxpncihal_ctrl.p_rsp_data); if (status != NFCSTATUS_SUCCESS) { /* Do not send packet to PN54X, send response directly */ msg.eMsgType = NCI_HAL_RX_MSG; msg.pMsgData = NULL; msg.Size = 0; phTmlNfc_DeferredCall(gpphTmlNfc_Context->dwCallbackThreadId, (phLibNfc_Message_t*)&msg); goto clean_and_return; } CONCURRENCY_LOCK(); data_len = phNxpNciHal_write_unlocked(nxpncihal_ctrl.cmd_len, nxpncihal_ctrl.p_cmd_data); CONCURRENCY_UNLOCK(); if (icode_send_eof == 1) { usleep(10000); icode_send_eof = 2; status = phNxpNciHal_send_ext_cmd(3, cmd_icode_eof); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("ICODE end of frame command failed"); } } clean_and_return: /* No data written */ return data_len; } /****************************************************************************** * Function phNxpNciHal_write_unlocked * * Description This is the actual function which is being called by * phNxpNciHal_write. This function writes the data to NFCC. * It waits till write callback provide the result of write * process. * * Returns It returns number of bytes successfully written to NFCC. * ******************************************************************************/ int phNxpNciHal_write_unlocked(uint16_t data_len, const uint8_t* p_data) { NFCSTATUS status = NFCSTATUS_INVALID_PARAMETER; phNxpNciHal_Sem_t cb_data; nxpncihal_ctrl.retry_cnt = 0; static uint8_t reset_ntf[] = {0x60, 0x00, 0x06, 0xA0, 0x00, 0xC7, 0xD4, 0x00, 0x00}; /* Create the local semaphore */ if (phNxpNciHal_init_cb_data(&cb_data, NULL) != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_D("phNxpNciHal_write_unlocked Create cb data failed"); data_len = 0; goto clean_and_return; } /* Create local copy of cmd_data */ memcpy(nxpncihal_ctrl.p_cmd_data, p_data, data_len); nxpncihal_ctrl.cmd_len = data_len; /* check for write synchronyztion */ if (phNxpNciHal_check_ncicmd_write_window(nxpncihal_ctrl.cmd_len, nxpncihal_ctrl.p_cmd_data) != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_D("phNxpNciHal_write_unlocked Create cb data failed"); data_len = 0; goto clean_and_return; } NfccPowerTracker::getInstance().ProcessCmd( (uint8_t*)nxpncihal_ctrl.p_cmd_data, (uint16_t)nxpncihal_ctrl.cmd_len); retry: data_len = nxpncihal_ctrl.cmd_len; status = phTmlNfc_Write( (uint8_t*)nxpncihal_ctrl.p_cmd_data, (uint16_t)nxpncihal_ctrl.cmd_len, (pphTmlNfc_TransactCompletionCb_t)&phNxpNciHal_write_complete, (void*)&cb_data); if (status != NFCSTATUS_PENDING) { NXPLOG_NCIHAL_E("write_unlocked status error"); data_len = 0; goto clean_and_return; } /* Wait for callback response */ if (SEM_WAIT(cb_data)) { NXPLOG_NCIHAL_E("write_unlocked semaphore error"); data_len = 0; goto clean_and_return; } if (cb_data.status != NFCSTATUS_SUCCESS) { data_len = 0; if (nxpncihal_ctrl.retry_cnt++ < MAX_RETRY_COUNT) { NXPLOG_NCIHAL_D( "write_unlocked failed - PN54X Maybe in Standby Mode - Retry"); /* 10ms delay to give NFCC wake up delay */ usleep(1000 * 10); goto retry; } else { NXPLOG_NCIHAL_E( "write_unlocked failed - PN54X Maybe in Standby Mode (max count = " "0x%x)", nxpncihal_ctrl.retry_cnt); sem_post(&(nxpncihal_ctrl.syncSpiNfc)); status = phTmlNfc_IoCtl(phTmlNfc_e_ResetDevice); if (NFCSTATUS_SUCCESS == status) { NXPLOG_NCIHAL_D("PN54X Reset - SUCCESS\n"); } else { NXPLOG_NCIHAL_D("PN54X Reset - FAILED\n"); } if (nxpncihal_ctrl.p_nfc_stack_data_cback != NULL && nxpncihal_ctrl.p_rx_data != NULL && nxpncihal_ctrl.hal_open_status == true) { NXPLOG_NCIHAL_D( "Send the Core Reset NTF to upper layer, which will trigger the " "recovery\n"); // Send the Core Reset NTF to upper layer, which will trigger the // recovery. nxpncihal_ctrl.rx_data_len = sizeof(reset_ntf); memcpy(nxpncihal_ctrl.p_rx_data, reset_ntf, sizeof(reset_ntf)); (*nxpncihal_ctrl.p_nfc_stack_data_cback)(nxpncihal_ctrl.rx_data_len, nxpncihal_ctrl.p_rx_data); } } } clean_and_return: phNxpNciHal_cleanup_cb_data(&cb_data); return data_len; } /****************************************************************************** * Function phNxpNciHal_write_complete * * Description This function handles write callback. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_write_complete(void* pContext, phTmlNfc_TransactInfo_t* pInfo) { phNxpNciHal_Sem_t* p_cb_data = (phNxpNciHal_Sem_t*)pContext; if (pInfo->wStatus == NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_D("write successful status = 0x%x", pInfo->wStatus); } else { NXPLOG_NCIHAL_D("write error status = 0x%x", pInfo->wStatus); } p_cb_data->status = pInfo->wStatus; SEM_POST(p_cb_data); return; } /****************************************************************************** * Function phNxpNciHal_read_complete * * Description This function is called whenever there is an NCI packet * received from NFCC. It could be RSP or NTF packet. This * function provide the received NCI packet to libnfc-nci * using data callback of libnfc-nci. * There is a pending read called from each * phNxpNciHal_read_complete so each a packet received from * NFCC can be provide to libnfc-nci. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_read_complete(void* pContext, phTmlNfc_TransactInfo_t* pInfo) { NFCSTATUS status = NFCSTATUS_FAILED; int sem_val; UNUSED(pContext); if (nxpncihal_ctrl.read_retry_cnt == 1) { nxpncihal_ctrl.read_retry_cnt = 0; } if (pInfo->wStatus == NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_D("read successful status = 0x%x", pInfo->wStatus); sem_getvalue(&(nxpncihal_ctrl.syncSpiNfc), &sem_val); if (((pInfo->pBuff[0] & NCI_MT_MASK) == NCI_MT_RSP) && sem_val == 0) { sem_post(&(nxpncihal_ctrl.syncSpiNfc)); } /*Check the Omapi command response and store in dedicated buffer to solve * sync issue*/ if (pInfo->pBuff[0] == 0x4F && pInfo->pBuff[1] == 0x01 && pInfo->pBuff[2] == 0x01) { nxpncihal_ctrl.p_rx_ese_data = pInfo->pBuff; nxpncihal_ctrl.rx_ese_data_len = pInfo->wLength; SEM_POST(&(nxpncihal_ctrl.ext_cb_data)); } else { nxpncihal_ctrl.p_rx_data = pInfo->pBuff; nxpncihal_ctrl.rx_data_len = pInfo->wLength; status = phNxpNciHal_process_ext_rsp(nxpncihal_ctrl.p_rx_data, &nxpncihal_ctrl.rx_data_len); } phNxpNciHal_print_res_status(pInfo->pBuff, &pInfo->wLength); if ((nxpncihal_ctrl.p_rx_data[0x00] & NCI_MT_MASK) == NCI_MT_NTF) { NfccPowerTracker::getInstance().ProcessNtf(nxpncihal_ctrl.p_rx_data, nxpncihal_ctrl.rx_data_len); } /* Check if response should go to hal module only */ if (nxpncihal_ctrl.hal_ext_enabled == TRUE && (nxpncihal_ctrl.p_rx_data[0x00] & NCI_MT_MASK) == NCI_MT_RSP) { if (status == NFCSTATUS_FAILED) { NXPLOG_NCIHAL_D("enter into NFCC init recovery"); nxpncihal_ctrl.ext_cb_data.status = status; } /* Unlock semaphore only for responses*/ if ((nxpncihal_ctrl.p_rx_data[0x00] & NCI_MT_MASK) == NCI_MT_RSP || ((icode_detected == true) && (icode_send_eof == 3))) { /* Unlock semaphore */ SEM_POST(&(nxpncihal_ctrl.ext_cb_data)); } } // Notification Checking else if ((nxpncihal_ctrl.hal_ext_enabled == TRUE) && ((nxpncihal_ctrl.p_rx_data[0x00] & NCI_MT_MASK) == NCI_MT_NTF) && (nxpncihal_ctrl.nci_info.wait_for_ntf == TRUE)) { /* Unlock semaphore waiting for only ntf*/ SEM_POST(&(nxpncihal_ctrl.ext_cb_data)); nxpncihal_ctrl.nci_info.wait_for_ntf = FALSE; } else if (bDisableLegacyMfcExtns && !sendRspToUpperLayer && (nxpncihal_ctrl.p_rx_data[0x00] == 0x00)) { sendRspToUpperLayer = true; NFCSTATUS mfcRspStatus = NxpMfcReaderInstance.CheckMfcResponse( nxpncihal_ctrl.p_rx_data, nxpncihal_ctrl.rx_data_len); NXPLOG_NCIHAL_D("Mfc Response Status = 0x%x", mfcRspStatus); SEM_POST(&(nxpncihal_ctrl.ext_cb_data)); } /* Read successful send the event to higher layer */ else if ((nxpncihal_ctrl.p_nfc_stack_data_cback != NULL) && (status == NFCSTATUS_SUCCESS)) { (*nxpncihal_ctrl.p_nfc_stack_data_cback)(nxpncihal_ctrl.rx_data_len, nxpncihal_ctrl.p_rx_data); // workaround for sync issue between SPI and NFC if ((nfcFL.chipType == pn557) && nxpncihal_ctrl.p_rx_data[0] == 0x62 && nxpncihal_ctrl.p_rx_data[1] == 0x00 && nxpncihal_ctrl.p_rx_data[3] == 0xC0 && nxpncihal_ctrl.p_rx_data[4] == 0x00) { uint8_t nfcee_notifiations[3][9] = { {0x61, 0x0A, 0x06, 0x01, 0x00, 0x03, 0xC0, 0x80, 0x04}, {0x61, 0x0A, 0x06, 0x01, 0x00, 0x03, 0xC0, 0x81, 0x04}, {0x61, 0x0A, 0x06, 0x01, 0x00, 0x03, 0xC0, 0x82, 0x03}, }; for (int i = 0; i < 3; i++) { (*nxpncihal_ctrl.p_nfc_stack_data_cback)( sizeof(nfcee_notifiations[i]), nfcee_notifiations[i]); } } } } else { NXPLOG_NCIHAL_E("read error status = 0x%x", pInfo->wStatus); } if (nxpncihal_ctrl.halStatus == HAL_STATUS_CLOSE && nxpncihal_ctrl.nci_info.wait_for_ntf == FALSE) { NXPLOG_NCIHAL_D("Ignoring read, HAL close triggered"); return; } /* Read again because read must be pending always.*/ status = phTmlNfc_Read( Rx_data, NCI_MAX_DATA_LEN, (pphTmlNfc_TransactCompletionCb_t)&phNxpNciHal_read_complete, NULL); if (status != NFCSTATUS_PENDING) { NXPLOG_NCIHAL_E("read status error status = %x", status); /* TODO: Not sure how to handle this ? */ } return; } /****************************************************************************** * Function phNxpNciHal_core_initialized * * Description This function is called by libnfc-nci after successful open * of NFCC. All proprietary setting for PN54X are done here. * After completion of proprietary settings notification is * provided to libnfc-nci through callback function. * * Returns Always returns NFCSTATUS_SUCCESS (0). * ******************************************************************************/ int phNxpNciHal_core_initialized(uint16_t core_init_rsp_params_len, uint8_t* p_core_init_rsp_params) { NFCSTATUS status = NFCSTATUS_SUCCESS; static uint8_t p2p_listen_mode_routing_cmd[] = {0x21, 0x01, 0x07, 0x00, 0x01, 0x01, 0x03, 0x00, 0x01, 0x05}; uint8_t swp_full_pwr_mode_on_cmd[] = {0x20, 0x02, 0x05, 0x01, 0xA0, 0xF1, 0x01, 0x01}; static uint8_t cmd_ven_pulld_enable_nci[] = {0x20, 0x02, 0x05, 0x01, 0xA0, 0x07, 0x01, 0x03}; static uint8_t android_l_aid_matching_mode_on_cmd[] = { 0x20, 0x02, 0x05, 0x01, 0xA0, 0x91, 0x01, 0x01}; static uint8_t swp_switch_timeout_cmd[] = {0x20, 0x02, 0x06, 0x01, 0xA0, 0xF3, 0x02, 0x00, 0x00}; config_success = true; uint8_t* buffer = NULL; long bufflen = 260; long retlen = 0; int isfound; #if (NFC_NXP_HFO_SETTINGS == TRUE) /* Temp fix to re-apply the proper clock setting */ int temp_fix = 1; #endif unsigned long num = 0; // initialize dummy FW recovery variables gRecFwRetryCount = 0; gRecFWDwnld = 0; // recovery --start /*NCI_INIT_CMD*/ static uint8_t cmd_init_nci[] = {0x20, 0x01, 0x00}; /*NCI_RESET_CMD*/ static uint8_t cmd_reset_nci[] = {0x20, 0x00, 0x01, 0x00}; // keep configuration static uint8_t cmd_init_nci2_0[] = {0x20, 0x01, 0x02, 0x00, 0x00}; /* reset config cache */ static uint8_t retry_core_init_cnt; if (nxpncihal_ctrl.halStatus != HAL_STATUS_OPEN) { return NFCSTATUS_FAILED; } if (core_init_rsp_params_len >= 1 && (*p_core_init_rsp_params > 0) && (*p_core_init_rsp_params < 4)) // initializing for recovery. { retry_core_init: config_access = false; if (buffer != NULL) { free(buffer); buffer = NULL; } if (retry_core_init_cnt > 3) { return NFCSTATUS_FAILED; } status = phTmlNfc_IoCtl(phTmlNfc_e_ResetDevice); if (NFCSTATUS_SUCCESS == status) { NXPLOG_NCIHAL_D("PN54X Reset - SUCCESS\n"); } else { NXPLOG_NCIHAL_D("PN54X Reset - FAILED\n"); } status = phNxpNciHal_send_ext_cmd(sizeof(cmd_reset_nci), cmd_reset_nci); if ((status != NFCSTATUS_SUCCESS) && (nxpncihal_ctrl.retry_cnt >= MAX_RETRY_COUNT)) { NXPLOG_NCIHAL_E("Force FW Download, NFCC not coming out from Standby"); retry_core_init_cnt++; goto retry_core_init; } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_RESET: Failed"); retry_core_init_cnt++; goto retry_core_init; } if (*p_core_init_rsp_params == 2) { NXPLOG_NCIHAL_E(" Last command is CORE_RESET!!"); goto invoke_callback; } if (nxpncihal_ctrl.nci_info.nci_version == NCI_VERSION_2_0) { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci2_0), cmd_init_nci2_0); } else { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci), cmd_init_nci); } if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_INIT : Failed"); retry_core_init_cnt++; goto retry_core_init; } if (*p_core_init_rsp_params == 3) { NXPLOG_NCIHAL_E(" Last command is CORE_INIT!!"); goto invoke_callback; } } // recovery --end buffer = (uint8_t*)malloc(bufflen * sizeof(uint8_t)); if (NULL == buffer) { return NFCSTATUS_FAILED; } config_access = true; retlen = 0; isfound = GetNxpByteArrayValue(NAME_NXP_ACT_PROP_EXTN, (char*)buffer, bufflen, &retlen); if (retlen > 0) { /* NXP ACT Proprietary Ext */ status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NXP ACT Proprietary Ext failed"); retry_core_init_cnt++; goto retry_core_init; } } status = phNxpNciHal_send_ext_cmd(sizeof(cmd_ven_pulld_enable_nci), cmd_ven_pulld_enable_nci); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("cmd_ven_pulld_enable_nci: Failed"); retry_core_init_cnt++; goto retry_core_init; } if (fw_download_success == 1) { phNxpNciHal_hci_network_reset(); } // Check if firmware download success status = phNxpNciHal_get_mw_eeprom(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NXP GET MW EEPROM AREA Proprietary Ext failed"); retry_core_init_cnt++; goto retry_core_init; } // status = phNxpNciHal_check_clock_config(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("phNxpNciHal_check_clock_config failed"); retry_core_init_cnt++; goto retry_core_init; } #ifdef PN547C2_CLOCK_SETTING if (isNxpConfigModified() || (fw_download_success == 1) || (phNxpNciClock.issetConfig) #if (NFC_NXP_HFO_SETTINGS == TRUE) || temp_fix == 1 #endif ) { // phNxpNciHal_get_clk_freq(); phNxpNciHal_set_clock(); phNxpNciClock.issetConfig = false; #if (NFC_NXP_HFO_SETTINGS == TRUE) if (temp_fix == 1) { NXPLOG_NCIHAL_D( "Applying Default Clock setting and DPLL register at power on"); /* # A0, 0D, 06, 06, 83, 55, 2A, 04, 00 RF_CLIF_CFG_TARGET CLIF_DPLL_GEAR_REG # A0, 0D, 06, 06, 82, 33, 14, 17, 00 RF_CLIF_CFG_TARGET CLIF_DPLL_INIT_REG # A0, 0D, 06, 06, 84, AA, 85, 00, 80 RF_CLIF_CFG_TARGET CLIF_DPLL_INIT_FREQ_REG # A0, 0D, 06, 06, 81, 63, 00, 00, 00 RF_CLIF_CFG_TARGET CLIF_DPLL_CONTROL_REG */ static uint8_t cmd_dpll_set_reg_nci[] = { 0x20, 0x02, 0x25, 0x04, 0xA0, 0x0D, 0x06, 0x06, 0x83, 0x55, 0x2A, 0x04, 0x00, 0xA0, 0x0D, 0x06, 0x06, 0x82, 0x33, 0x14, 0x17, 0x00, 0xA0, 0x0D, 0x06, 0x06, 0x84, 0xAA, 0x85, 0x00, 0x80, 0xA0, 0x0D, 0x06, 0x06, 0x81, 0x63, 0x00, 0x00, 0x00}; status = phNxpNciHal_send_ext_cmd(sizeof(cmd_dpll_set_reg_nci), cmd_dpll_set_reg_nci); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NXP DPLL REG ACT Proprietary Ext failed"); retry_core_init_cnt++; goto retry_core_init; } /* reset the NFCC after applying the clock setting and DPLL setting */ // phTmlNfc_IoCtl(phTmlNfc_e_ResetDevice); temp_fix = 0; goto retry_core_init; } #endif } #endif retlen = 0; config_access = true; isfound = GetNxpByteArrayValue(NAME_NXP_NFC_PROFILE_EXTN, (char*)buffer, bufflen, &retlen); if (retlen > 0) { /* NXP ACT Proprietary Ext */ status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NXP ACT Proprietary Ext failed"); retry_core_init_cnt++; goto retry_core_init; } } if (isNxpConfigModified() || (fw_download_success == 1)) { retlen = 0; fw_download_success = 0; NXPLOG_NCIHAL_D("Performing TVDD Settings"); isfound = GetNxpNumValue(NAME_NXP_EXT_TVDD_CFG, &num, sizeof(num)); if (isfound > 0) { if (num == 1) { isfound = GetNxpByteArrayValue(NAME_NXP_EXT_TVDD_CFG_1, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("EXT TVDD CFG 1 Settings failed"); retry_core_init_cnt++; goto retry_core_init; } } } else if (num == 2) { isfound = GetNxpByteArrayValue(NAME_NXP_EXT_TVDD_CFG_2, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("EXT TVDD CFG 2 Settings failed"); retry_core_init_cnt++; goto retry_core_init; } } } else if (num == 3) { isfound = GetNxpByteArrayValue(NAME_NXP_EXT_TVDD_CFG_3, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("EXT TVDD CFG 3 Settings failed"); retry_core_init_cnt++; goto retry_core_init; } } } else { NXPLOG_NCIHAL_E("Wrong Configuration Value %ld", num); } } retlen = 0; config_access = false; NXPLOG_NCIHAL_D("Performing RF Settings BLK 1"); isfound = GetNxpByteArrayValue(NAME_NXP_RF_CONF_BLK_1, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_CheckRFCmdRespStatus(); /*STATUS INVALID PARAM 0x09*/ if (status == 0x09) { phNxpNciHalRFConfigCmdRecSequence(); retry_core_init_cnt++; goto retry_core_init; } } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("RF Settings BLK 1 failed"); retry_core_init_cnt++; goto retry_core_init; } } retlen = 0; NXPLOG_NCIHAL_D("Performing RF Settings BLK 2"); isfound = GetNxpByteArrayValue(NAME_NXP_RF_CONF_BLK_2, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_CheckRFCmdRespStatus(); /*STATUS INVALID PARAM 0x09*/ if (status == 0x09) { phNxpNciHalRFConfigCmdRecSequence(); retry_core_init_cnt++; goto retry_core_init; } } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("RF Settings BLK 2 failed"); retry_core_init_cnt++; goto retry_core_init; } } retlen = 0; NXPLOG_NCIHAL_D("Performing RF Settings BLK 3"); isfound = GetNxpByteArrayValue(NAME_NXP_RF_CONF_BLK_3, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_CheckRFCmdRespStatus(); /*STATUS INVALID PARAM 0x09*/ if (status == 0x09) { phNxpNciHalRFConfigCmdRecSequence(); retry_core_init_cnt++; goto retry_core_init; } } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("RF Settings BLK 3 failed"); retry_core_init_cnt++; goto retry_core_init; } } retlen = 0; NXPLOG_NCIHAL_D("Performing RF Settings BLK 4"); isfound = GetNxpByteArrayValue(NAME_NXP_RF_CONF_BLK_4, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_CheckRFCmdRespStatus(); /*STATUS INVALID PARAM 0x09*/ if (status == 0x09) { phNxpNciHalRFConfigCmdRecSequence(); retry_core_init_cnt++; goto retry_core_init; } } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("RF Settings BLK 4 failed"); retry_core_init_cnt++; goto retry_core_init; } } retlen = 0; NXPLOG_NCIHAL_D("Performing RF Settings BLK 5"); isfound = GetNxpByteArrayValue(NAME_NXP_RF_CONF_BLK_5, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_CheckRFCmdRespStatus(); /*STATUS INVALID PARAM 0x09*/ if (status == 0x09) { phNxpNciHalRFConfigCmdRecSequence(); retry_core_init_cnt++; goto retry_core_init; } } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("RF Settings BLK 5 failed"); retry_core_init_cnt++; goto retry_core_init; } } retlen = 0; NXPLOG_NCIHAL_D("Performing RF Settings BLK 6"); isfound = GetNxpByteArrayValue(NAME_NXP_RF_CONF_BLK_6, (char*)buffer, bufflen, &retlen); if (retlen > 0) { status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_CheckRFCmdRespStatus(); /*STATUS INVALID PARAM 0x09*/ if (status == 0x09) { phNxpNciHalRFConfigCmdRecSequence(); retry_core_init_cnt++; goto retry_core_init; } } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("RF Settings BLK 6 failed"); retry_core_init_cnt++; goto retry_core_init; } } retlen = 0; config_access = true; NXPLOG_NCIHAL_D("Performing NAME_NXP_CORE_CONF_EXTN Settings"); isfound = GetNxpByteArrayValue(NAME_NXP_CORE_CONF_EXTN, (char*)buffer, bufflen, &retlen); if (retlen > 0) { /* NXP ACT Proprietary Ext */ status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NXP Core configuration failed"); retry_core_init_cnt++; goto retry_core_init; } } retlen = 0; config_access = false; isfound = GetNxpByteArrayValue(NAME_NXP_CORE_RF_FIELD, (char*)buffer, bufflen, &retlen); if (retlen > 0) { /* NXP ACT Proprietary Ext */ status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status == NFCSTATUS_SUCCESS) { status = phNxpNciHal_CheckRFCmdRespStatus(); /*STATUS INVALID PARAM 0x09*/ if (status == 0x09) { phNxpNciHalRFConfigCmdRecSequence(); retry_core_init_cnt++; goto retry_core_init; } } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Setting NXP_CORE_RF_FIELD status failed"); retry_core_init_cnt++; goto retry_core_init; } } config_access = true; retlen = 0; /* NXP SWP switch timeout Setting*/ if (GetNxpNumValue(NAME_NXP_SWP_SWITCH_TIMEOUT, (void*)&retlen, sizeof(retlen))) { // Check the permissible range [0 - 60] if (0 <= retlen && retlen <= 60) { if (0 < retlen) { unsigned int timeout = (uint32_t)retlen * 1000; unsigned int timeoutHx = 0x0000; char tmpbuffer[10] = {0}; snprintf((char*)tmpbuffer, 10, "%04x", timeout); sscanf((char*)tmpbuffer, "%x", &timeoutHx); swp_switch_timeout_cmd[7] = (timeoutHx & 0xFF); swp_switch_timeout_cmd[8] = ((timeoutHx & 0xFF00) >> 8); } status = phNxpNciHal_send_ext_cmd(sizeof(swp_switch_timeout_cmd), swp_switch_timeout_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("SWP switch timeout Setting Failed"); retry_core_init_cnt++; goto retry_core_init; } } else { NXPLOG_NCIHAL_E("SWP switch timeout Setting Failed - out of range!"); } } status = phNxpNciHal_china_tianjin_rf_setting(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("phNxpNciHal_china_tianjin_rf_setting failed"); retry_core_init_cnt++; goto retry_core_init; } // Update eeprom value status = phNxpNciHal_set_mw_eeprom(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NXP Update MW EEPROM Proprietary Ext failed"); } } retlen = 0; isfound = GetNxpByteArrayValue(NAME_NXP_CORE_CONF, (char*)buffer, bufflen, &retlen); if (retlen > 0) { /* NXP ACT Proprietary Ext */ status = phNxpNciHal_send_ext_cmd(retlen, buffer); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Core Set Config failed"); retry_core_init_cnt++; goto retry_core_init; } } config_access = false; // if recovery mode and length of last command is 0 then only reset the P2P // listen mode routing. if (core_init_rsp_params_len >= 36 && (*p_core_init_rsp_params > 0) && (*p_core_init_rsp_params < 4) && p_core_init_rsp_params[35] == 0) { /* P2P listen mode routing */ status = phNxpNciHal_send_ext_cmd(sizeof(p2p_listen_mode_routing_cmd), p2p_listen_mode_routing_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("P2P listen mode routing failed"); retry_core_init_cnt++; goto retry_core_init; } } retlen = 0; /* SWP FULL PWR MODE SETTING ON */ if (GetNxpNumValue(NAME_NXP_SWP_FULL_PWR_ON, (void*)&retlen, sizeof(retlen))) { if (1 == retlen) { status = phNxpNciHal_send_ext_cmd(sizeof(swp_full_pwr_mode_on_cmd), swp_full_pwr_mode_on_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("SWP FULL PWR MODE SETTING ON CMD FAILED"); retry_core_init_cnt++; goto retry_core_init; } } else { swp_full_pwr_mode_on_cmd[7] = 0x00; status = phNxpNciHal_send_ext_cmd(sizeof(swp_full_pwr_mode_on_cmd), swp_full_pwr_mode_on_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("SWP FULL PWR MODE SETTING OFF CMD FAILED"); retry_core_init_cnt++; goto retry_core_init; } } } /* Android L AID Matching Platform Setting*/ if ((nfcFL.chipType != pn557) && GetNxpNumValue(NAME_AID_MATCHING_PLATFORM, (void*)&retlen, sizeof(retlen))) { if (1 == retlen) { status = phNxpNciHal_send_ext_cmd(sizeof(android_l_aid_matching_mode_on_cmd), android_l_aid_matching_mode_on_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Android L AID Matching Platform Setting Failed"); retry_core_init_cnt++; goto retry_core_init; } } else if (2 == retlen) { android_l_aid_matching_mode_on_cmd[7] = 0x00; status = phNxpNciHal_send_ext_cmd(sizeof(android_l_aid_matching_mode_on_cmd), android_l_aid_matching_mode_on_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Android L AID Matching Platform Setting Failed"); retry_core_init_cnt++; goto retry_core_init; } } } if (core_init_rsp_params_len >= 1 && (*p_core_init_rsp_params > 0) && (*p_core_init_rsp_params < 4)) { static phLibNfc_Message_t msg; uint16_t tmp_len = 0; uint8_t uicc_set_mode[] = {0x22, 0x01, 0x02, 0x02, 0x01}; uint8_t set_screen_state[] = {0x2F, 0x15, 01, 00}; // SCREEN ON uint8_t nfcc_core_conn_create[] = {0x20, 0x04, 0x06, 0x03, 0x01, 0x01, 0x02, 0x01, 0x01}; uint8_t nfcc_mode_set_on[] = {0x22, 0x01, 0x02, 0x01, 0x01}; NXPLOG_NCIHAL_W( "Sending DH and NFCC core connection command as raw packet!!"); status = phNxpNciHal_send_ext_cmd(sizeof(nfcc_core_conn_create), nfcc_core_conn_create); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E( "Sending DH and NFCC core connection command as raw packet!! Failed"); retry_core_init_cnt++; goto retry_core_init; } NXPLOG_NCIHAL_W("Sending DH and NFCC mode set as raw packet!!"); status = phNxpNciHal_send_ext_cmd(sizeof(nfcc_mode_set_on), nfcc_mode_set_on); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Sending DH and NFCC mode set as raw packet!! Failed"); retry_core_init_cnt++; goto retry_core_init; } NXPLOG_NCIHAL_W("Sending UICC Select Command as raw packet!!"); status = phNxpNciHal_send_ext_cmd(sizeof(uicc_set_mode), uicc_set_mode); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Sending UICC Select Command as raw packet!! Failed"); retry_core_init_cnt++; goto retry_core_init; } if (core_init_rsp_params_len >= 4 && *(p_core_init_rsp_params + 1) == 1) // RF state is Discovery!! { NXPLOG_NCIHAL_W("Sending Set Screen ON State Command as raw packet!!"); status = phNxpNciHal_send_ext_cmd(sizeof(set_screen_state), set_screen_state); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E( "Sending Set Screen ON State Command as raw packet!! Failed"); retry_core_init_cnt++; goto retry_core_init; } if (p_core_init_rsp_params[2] > (core_init_rsp_params_len - 3)) { return NFCSTATUS_FAILED; } NXPLOG_NCIHAL_W("Sending discovery as raw packet!!"); status = phNxpNciHal_send_ext_cmd(p_core_init_rsp_params[2], (uint8_t*)&p_core_init_rsp_params[3]); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Sending discovery as raw packet Failed"); retry_core_init_cnt++; goto retry_core_init; } } else { NXPLOG_NCIHAL_W("Sending Set Screen OFF State Command as raw packet!!"); set_screen_state[3] = 0x01; // Screen OFF status = phNxpNciHal_send_ext_cmd(sizeof(set_screen_state), set_screen_state); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E( "Sending Set Screen OFF State Command as raw packet!! Failed"); retry_core_init_cnt++; goto retry_core_init; } } NXPLOG_NCIHAL_W("Sending last command for Recovery "); if (core_init_rsp_params_len >= 40 && p_core_init_rsp_params[35] > 0) { // if length of last command is 0 // then it doesn't need to send last // command. if (!(((p_core_init_rsp_params[36] == 0x21) && (p_core_init_rsp_params[37] == 0x03)) && (*(p_core_init_rsp_params + 1) == 1)) && !((p_core_init_rsp_params[36] == 0x21) && (p_core_init_rsp_params[37] == 0x06) && (p_core_init_rsp_params[39] == 0x00) && (*(p_core_init_rsp_params + 1) == 0x00))) // if last command is discovery and RF status is also discovery state, // then it doesn't need to execute or similarly // if the last command is deactivate to idle and RF status is also idle , // no need to execute the command . { tmp_len = p_core_init_rsp_params[35]; /* Check for NXP ext before sending write */ status = phNxpNciHal_write_ext( &tmp_len, (uint8_t*)&p_core_init_rsp_params[36], &nxpncihal_ctrl.rsp_len, nxpncihal_ctrl.p_rsp_data); if (status != NFCSTATUS_SUCCESS) { if (buffer) { free(buffer); buffer = NULL; } /* Do not send packet to PN54X, send response directly */ msg.eMsgType = NCI_HAL_RX_MSG; msg.pMsgData = NULL; msg.Size = 0; phTmlNfc_DeferredCall(gpphTmlNfc_Context->dwCallbackThreadId, (phLibNfc_Message_t*)&msg); return NFCSTATUS_SUCCESS; } p_core_init_rsp_params[35] = (uint8_t)tmp_len; if (p_core_init_rsp_params[35] > (core_init_rsp_params_len - 36)) { return NFCSTATUS_FAILED; } status = phNxpNciHal_send_ext_cmd( p_core_init_rsp_params[35], (uint8_t*)&p_core_init_rsp_params[36]); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Sending last command for Recovery Failed"); retry_core_init_cnt++; goto retry_core_init; } } } } retry_core_init_cnt = 0; if (buffer) { free(buffer); buffer = NULL; } // initialize dummy FW recovery variables gRecFWDwnld = 0; gRecFwRetryCount = 0; if (core_init_rsp_params_len >= 1 && !((*p_core_init_rsp_params > 0) && (*p_core_init_rsp_params < 4))) phNxpNciHal_core_initialized_complete(status); else { invoke_callback: config_access = false; if (nxpncihal_ctrl.p_nfc_stack_data_cback != NULL) { if (core_init_rsp_params_len) *p_core_init_rsp_params = 0; NXPLOG_NCIHAL_W("Invoking data callback!!"); (*nxpncihal_ctrl.p_nfc_stack_data_cback)(nxpncihal_ctrl.rx_data_len, nxpncihal_ctrl.p_rx_data); } } if (config_success == false) return NFCSTATUS_FAILED; #ifdef PN547C2_CLOCK_SETTING if (isNxpConfigModified()) { updateNxpConfigTimestamp(); } #endif return NFCSTATUS_SUCCESS; } #ifdef FactoryOTA void phNxpNciHal_isFactoryOTAModeActive() { uint8_t check_factoryOTA[] = {0x20, 0x03, 0x05, 0x02, 0xA0, 0x08, 0xA0, 0x88}; NFCSTATUS status = NFCSTATUS_FAILED; NXPLOG_NCIHAL_D("check FactoryOTA mode status"); status = phNxpNciHal_send_ext_cmd(sizeof(check_factoryOTA), check_factoryOTA); if (status == NFCSTATUS_SUCCESS) { if (nxpncihal_ctrl.p_rx_data[9] == 0x1 && nxpncihal_ctrl.p_rx_data[13] == 0x1) { NXPLOG_NCIHAL_D("FactoryOTA mode is active"); } else { NXPLOG_NCIHAL_D("FactoryOTA mode is disabled"); } } else { NXPLOG_NCIHAL_E("Fail to get FactoryOTA mode status"); } return; } NFCSTATUS phNxpNciHal_disableFactoryOTAMode() { // NFCC GPIO output control uint8_t nfcc_system_gpio[] = {0x20, 0x02, 0x06, 0x01, 0xA0, 0x08, 0x02, 0x00, 0x00}; // NFCC automatically sets GPIO once a specific RF pattern is detected uint8_t nfcc_gpio_pattern[] = {0x20, 0x02, 0x08, 0x01, 0xA0, 0x88, 0x04, 0x00, 0x96, 0x96, 0x03}; NFCSTATUS status = NFCSTATUS_SUCCESS; NXPLOG_NCIHAL_D("Disable FactoryOTA mode"); status = phNxpNciHal_send_ext_cmd(sizeof(nfcc_system_gpio), nfcc_system_gpio); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Can't disable A008 for FactoryOTA mode"); } status = phNxpNciHal_send_ext_cmd(sizeof(nfcc_gpio_pattern), nfcc_gpio_pattern); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Can't disable A088 for FactoryOTA mode"); } return status; } #endif /****************************************************************************** * Function phNxpNciHal_CheckRFCmdRespStatus * * Description This function is called to check the resp status of * RF update commands. * * Returns NFCSTATUS_SUCCESS if successful, * NFCSTATUS_INVALID_PARAMETER if parameter is inavlid * NFCSTATUS_FAILED if failed response * ******************************************************************************/ NFCSTATUS phNxpNciHal_CheckRFCmdRespStatus() { NFCSTATUS status = NFCSTATUS_SUCCESS; static uint16_t INVALID_PARAM = 0x09; if ((nxpncihal_ctrl.rx_data_len > 0) && (nxpncihal_ctrl.p_rx_data[2] > 0)) { if (nxpncihal_ctrl.p_rx_data[3] == 0x09) { status = INVALID_PARAM; } else if (nxpncihal_ctrl.p_rx_data[3] != NFCSTATUS_SUCCESS) { status = NFCSTATUS_FAILED; } } return status; } /****************************************************************************** * Function phNxpNciHalRFConfigCmdRecSequence * * Description This function is called to handle dummy FW recovery sequence * Whenever RF settings are failed to apply with invalid param * response, recovery mechanism includes dummy firmware *download * followed by firmware download and then config settings. The *dummy * firmware changes the major number of the firmware inside *NFCC. * Then actual firmware dowenload will be successful. This can *be * retried maximum three times. * * Returns Always returns NFCSTATUS_SUCCESS * ******************************************************************************/ NFCSTATUS phNxpNciHalRFConfigCmdRecSequence() { NFCSTATUS status = NFCSTATUS_SUCCESS; uint16_t recFWState = 1; gRecFWDwnld = true; gRecFwRetryCount++; if (gRecFwRetryCount > 0x03) { NXPLOG_NCIHAL_D("Max retry count for RF config FW recovery exceeded "); gRecFWDwnld = false; return NFCSTATUS_FAILED; } do { status = phTmlNfc_IoCtl(phTmlNfc_e_ResetDevice); phDnldNfc_InitImgInfo(); if (NFCSTATUS_SUCCESS == phNxpNciHal_CheckValidFwVersion()) { fw_download_success = 0; status = phNxpNciHal_fw_download(); if (status == NFCSTATUS_SUCCESS) { fw_download_success = 1; } status = phTmlNfc_Read( nxpncihal_ctrl.p_cmd_data, NCI_MAX_DATA_LEN, (pphTmlNfc_TransactCompletionCb_t)&phNxpNciHal_read_complete, NULL); if (status != NFCSTATUS_PENDING) { NXPLOG_NCIHAL_E("TML Read status error status = %x", status); phOsalNfc_Timer_Cleanup(); phTmlNfc_Shutdown(); status = NFCSTATUS_FAILED; } break; } gRecFWDwnld = false; } while (recFWState--); gRecFWDwnld = false; return status; } /****************************************************************************** * Function phNxpNciHal_core_initialized_complete * * Description This function is called when phNxpNciHal_core_initialized * complete all proprietary command exchanges. This function * informs libnfc-nci about completion of core initialize * and result of that through callback. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_core_initialized_complete(NFCSTATUS status) { static phLibNfc_Message_t msg; if (status == NFCSTATUS_SUCCESS) { msg.eMsgType = NCI_HAL_POST_INIT_CPLT_MSG; } else { msg.eMsgType = NCI_HAL_ERROR_MSG; } msg.pMsgData = NULL; msg.Size = 0; phTmlNfc_DeferredCall(gpphTmlNfc_Context->dwCallbackThreadId, (phLibNfc_Message_t*)&msg); return; } /****************************************************************************** * Function phNxpNciHal_pre_discover * * Description This function is called by libnfc-nci to perform any * proprietary exchange before RF discovery. * * Returns It always returns NFCSTATUS_SUCCESS (0). * ******************************************************************************/ int phNxpNciHal_pre_discover(void) { /* Nothing to do here for initial version */ return NFCSTATUS_SUCCESS; } /****************************************************************************** * Function phNxpNciHal_close * * Description This function close the NFCC interface and free all * resources.This is called by libnfc-nci on NFC service stop. * * Returns Always return NFCSTATUS_SUCCESS (0). * ******************************************************************************/ int phNxpNciHal_close(bool bShutdown) { NFCSTATUS status; /*NCI_RESET_CMD*/ static uint8_t cmd_reset_nci[] = {0x20, 0x00, 0x01, 0x00}; static uint8_t cmd_ven_disable_nci[] = {0x20, 0x02, 0x05, 0x01, 0xA0, 0x07, 0x01, 0x02}; AutoThreadMutex a(sHalFnLock); if (nxpncihal_ctrl.halStatus == HAL_STATUS_CLOSE) { NXPLOG_NCIHAL_D("phNxpNciHal_close is already closed, ignoring close"); return NFCSTATUS_FAILED; } CONCURRENCY_LOCK(); int sem_val; sem_getvalue(&(nxpncihal_ctrl.syncSpiNfc), &sem_val); if (sem_val == 0) { sem_post(&(nxpncihal_ctrl.syncSpiNfc)); } if (!bShutdown) { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_ven_disable_nci), cmd_ven_disable_nci); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("CMD_VEN_DISABLE_NCI: Failed"); } } #ifdef FactoryOTA char valueStr[PROPERTY_VALUE_MAX] = {0}; bool factoryOTA_terminate = false; int len = property_get("persist.factoryota.reboot", valueStr, "normal"); if (len > 0) { factoryOTA_terminate = (len == 9 && (memcmp(valueStr, "terminate", len) == 0)) ? true : false; } NXPLOG_NCIHAL_D("factoryOTA_terminate: %d", factoryOTA_terminate); if (factoryOTA_terminate) { phNxpNciHal_disableFactoryOTAMode(); phNxpNciHal_isFactoryOTAModeActive(); } #endif nxpncihal_ctrl.halStatus = HAL_STATUS_CLOSE; status = phNxpNciHal_send_ext_cmd(sizeof(cmd_reset_nci), cmd_reset_nci); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_RESET: Failed"); } sem_destroy(&nxpncihal_ctrl.syncSpiNfc); if (NULL != gpphTmlNfc_Context->pDevHandle) { phNxpNciHal_close_complete(NFCSTATUS_SUCCESS); /* Abort any pending read and write */ status = phTmlNfc_ReadAbort(); status = phTmlNfc_WriteAbort(); phOsalNfc_Timer_Cleanup(); status = phTmlNfc_Shutdown(); if (0 != pthread_join(nxpncihal_ctrl.client_thread, (void**)NULL)) { NXPLOG_TML_E("Fail to kill client thread!"); } phTmlNfc_CleanUp(); phDal4Nfc_msgrelease(nxpncihal_ctrl.gDrvCfg.nClientId); memset(&nxpncihal_ctrl, 0x00, sizeof(nxpncihal_ctrl)); NXPLOG_NCIHAL_D("phNxpNciHal_close - phOsalNfc_DeInit completed"); } NfccPowerTracker::getInstance().Pause(); CONCURRENCY_UNLOCK(); phNxpNciHal_cleanup_monitor(); /* Return success always */ return NFCSTATUS_SUCCESS; } /****************************************************************************** * Function phNxpNciHal_close_complete * * Description This function inform libnfc-nci about result of * phNxpNciHal_close. * * Returns void. * ******************************************************************************/ void phNxpNciHal_close_complete(NFCSTATUS status) { static phLibNfc_Message_t msg; if (status == NFCSTATUS_SUCCESS) { msg.eMsgType = NCI_HAL_CLOSE_CPLT_MSG; } else { msg.eMsgType = NCI_HAL_ERROR_MSG; } msg.pMsgData = NULL; msg.Size = 0; phTmlNfc_DeferredCall(gpphTmlNfc_Context->dwCallbackThreadId, &msg); return; } /****************************************************************************** * Function phNxpNciHal_configDiscShutdown * * Description Enable the CE and VEN config during shutdown. * * Returns Always return NFCSTATUS_SUCCESS (0). * ******************************************************************************/ int phNxpNciHal_configDiscShutdown(void) { NFCSTATUS status; NfccPowerTracker::getInstance().Reset(); status = phNxpNciHal_close(true); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_HAL_CLOSE: Failed"); } /* Return success always */ return NFCSTATUS_SUCCESS; } /****************************************************************************** * Function phNxpNciHal_getVendorConfig * * Description This function can be used by HAL to inform * to update vendor configuration parametres * * Returns void. * ******************************************************************************/ void phNxpNciHal_getVendorConfig( android::hardware::nfc::V1_1::NfcConfig& config) { unsigned long num = 0; std::array buffer; buffer.fill(0); long retlen = 0; memset(&config, 0x00, sizeof(android::hardware::nfc::V1_1::NfcConfig)); config.nfaPollBailOutMode = true; if (GetNxpNumValue(NAME_ISO_DEP_MAX_TRANSCEIVE, &num, sizeof(num))) { config.maxIsoDepTransceiveLength = (uint32_t)num; } if (GetNxpNumValue(NAME_DEFAULT_OFFHOST_ROUTE, &num, sizeof(num))) { config.defaultOffHostRoute = (uint8_t)num; } if (GetNxpNumValue(NAME_DEFAULT_NFCF_ROUTE, &num, sizeof(num))) { config.defaultOffHostRouteFelica = (uint8_t)num; } if (GetNxpNumValue(NAME_DEFAULT_SYS_CODE_ROUTE, &num, sizeof(num))) { config.defaultSystemCodeRoute = (uint8_t)num; } if (GetNxpNumValue(NAME_DEFAULT_SYS_CODE_PWR_STATE, &num, sizeof(num))) { config.defaultSystemCodePowerState = (uint8_t)num; } if (GetNxpNumValue(NAME_DEFAULT_ROUTE, &num, sizeof(num))) { config.defaultRoute = (uint8_t)num; } if (GetNxpByteArrayValue(NAME_DEVICE_HOST_WHITE_LIST, (char*)buffer.data(), buffer.size(), &retlen)) { config.hostWhitelist.resize(retlen); for (long i = 0; i < retlen; i++) config.hostWhitelist[i] = buffer[i]; } if (GetNxpNumValue(NAME_OFF_HOST_ESE_PIPE_ID, &num, sizeof(num))) { config.offHostESEPipeId = (uint8_t)num; } if (GetNxpNumValue(NAME_OFF_HOST_SIM_PIPE_ID, &num, sizeof(num))) { config.offHostSIMPipeId = (uint8_t)num; } if ((GetNxpByteArrayValue(NAME_NFA_PROPRIETARY_CFG, (char*)buffer.data(), buffer.size(), &retlen)) && (retlen == 9)) { config.nfaProprietaryCfg.protocol18092Active = (uint8_t)buffer[0]; config.nfaProprietaryCfg.protocolBPrime = (uint8_t)buffer[1]; config.nfaProprietaryCfg.protocolDual = (uint8_t)buffer[2]; config.nfaProprietaryCfg.protocol15693 = (uint8_t)buffer[3]; config.nfaProprietaryCfg.protocolKovio = (uint8_t)buffer[4]; config.nfaProprietaryCfg.protocolMifare = (uint8_t)buffer[5]; config.nfaProprietaryCfg.discoveryPollKovio = (uint8_t)buffer[6]; config.nfaProprietaryCfg.discoveryPollBPrime = (uint8_t)buffer[7]; config.nfaProprietaryCfg.discoveryListenBPrime = (uint8_t)buffer[8]; } else { memset(&config.nfaProprietaryCfg, 0xFF, sizeof(ProtocolDiscoveryConfig)); } if ((GetNxpNumValue(NAME_PRESENCE_CHECK_ALGORITHM, &num, sizeof(num))) && (num <= 2)) { config.presenceCheckAlgorithm = (PresenceCheckAlgorithm)num; } } /****************************************************************************** * Function phNxpNciHal_getVendorConfig_1_2 * * Description This function can be used by HAL to inform * to update vendor configuration parametres * * Returns void. * ******************************************************************************/ void phNxpNciHal_getVendorConfig_1_2( android::hardware::nfc::V1_2::NfcConfig& config) { unsigned long num = 0; std::array buffer; buffer.fill(0); long retlen = 0; memset(&config, 0x00, sizeof(android::hardware::nfc::V1_2::NfcConfig)); phNxpNciHal_getVendorConfig(config.v1_1); if (GetNxpByteArrayValue(NAME_OFFHOST_ROUTE_UICC, (char*)buffer.data(), buffer.size(), &retlen)) { config.offHostRouteUicc.resize(retlen); for (int i = 0; i < retlen; i++) config.offHostRouteUicc[i] = buffer[i]; } if (GetNxpByteArrayValue(NAME_OFFHOST_ROUTE_ESE, (char*)buffer.data(), buffer.size(), &retlen)) { config.offHostRouteEse.resize(retlen); for (int i = 0; i < retlen; i++) config.offHostRouteEse[i] = buffer[i]; } if (GetNxpNumValue(NAME_DEFAULT_ISODEP_ROUTE, &num, sizeof(num))) { config.defaultIsoDepRoute = num; } } /****************************************************************************** * Function phNxpNciHal_notify_i2c_fragmentation * * Description This function can be used by HAL to inform * libnfc-nci that i2c fragmentation is enabled/disabled * * Returns void. * ******************************************************************************/ void phNxpNciHal_notify_i2c_fragmentation(void) { if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /*inform libnfc-nci that i2c fragmentation is enabled/disabled */ (*nxpncihal_ctrl.p_nfc_stack_cback)(HAL_NFC_ENABLE_I2C_FRAGMENTATION_EVT, HAL_NFC_STATUS_OK); } } /****************************************************************************** * Function phNxpNciHal_control_granted * * Description Called by libnfc-nci when NFCC control is granted to HAL. * * Returns Always returns NFCSTATUS_SUCCESS (0). * ******************************************************************************/ int phNxpNciHal_control_granted(void) { /* Take the concurrency lock so no other calls from upper layer * will be allowed */ CONCURRENCY_LOCK(); if (NULL != nxpncihal_ctrl.p_control_granted_cback) { (*nxpncihal_ctrl.p_control_granted_cback)(); } /* At the end concurrency unlock so calls from upper layer will * be allowed */ CONCURRENCY_UNLOCK(); return NFCSTATUS_SUCCESS; } /****************************************************************************** * Function phNxpNciHal_request_control * * Description This function can be used by HAL to request control of * NFCC to libnfc-nci. When control is provided to HAL it is * notified through phNxpNciHal_control_granted. * * Returns void. * ******************************************************************************/ void phNxpNciHal_request_control(void) { if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /* Request Control of NCI Controller from NCI NFC Stack */ (*nxpncihal_ctrl.p_nfc_stack_cback)(HAL_NFC_REQUEST_CONTROL_EVT, HAL_NFC_STATUS_OK); } return; } /****************************************************************************** * Function phNxpNciHal_release_control * * Description This function can be used by HAL to release the control of * NFCC back to libnfc-nci. * * Returns void. * ******************************************************************************/ void phNxpNciHal_release_control(void) { if (nxpncihal_ctrl.p_nfc_stack_cback != NULL) { /* Release Control of NCI Controller to NCI NFC Stack */ (*nxpncihal_ctrl.p_nfc_stack_cback)(HAL_NFC_RELEASE_CONTROL_EVT, HAL_NFC_STATUS_OK); } return; } /****************************************************************************** * Function phNxpNciHal_power_cycle * * Description This function is called by libnfc-nci when power cycling is * performed. When processing is complete it is notified to * libnfc-nci through phNxpNciHal_power_cycle_complete. * * Returns Always return NFCSTATUS_SUCCESS (0). * ******************************************************************************/ int phNxpNciHal_power_cycle(void) { NXPLOG_NCIHAL_D("Power Cycle"); NFCSTATUS status = NFCSTATUS_FAILED; if (nxpncihal_ctrl.halStatus != HAL_STATUS_OPEN) { NXPLOG_NCIHAL_D("Power Cycle failed due to hal status not open"); return NFCSTATUS_FAILED; } status = phTmlNfc_IoCtl(phTmlNfc_e_ResetDevice); if (NFCSTATUS_SUCCESS == status) { NXPLOG_NCIHAL_D("PN54X Reset - SUCCESS\n"); } else { NXPLOG_NCIHAL_D("PN54X Reset - FAILED\n"); } phNxpNciHal_power_cycle_complete(NFCSTATUS_SUCCESS); return NFCSTATUS_SUCCESS; } /****************************************************************************** * Function phNxpNciHal_power_cycle_complete * * Description This function is called to provide the status of * phNxpNciHal_power_cycle to libnfc-nci through callback. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_power_cycle_complete(NFCSTATUS status) { static phLibNfc_Message_t msg; if (status == NFCSTATUS_SUCCESS) { msg.eMsgType = NCI_HAL_OPEN_CPLT_MSG; } else { msg.eMsgType = NCI_HAL_ERROR_MSG; } msg.pMsgData = NULL; msg.Size = 0; phTmlNfc_DeferredCall(gpphTmlNfc_Context->dwCallbackThreadId, &msg); return; } /****************************************************************************** * Function phNxpNciHal_check_ncicmd_write_window * * Description This function is called to check the write synchroniztion * status if write already aquired then wait for corresponding read to complete. * * Returns return 0 on success and -1 on fail. * ******************************************************************************/ int phNxpNciHal_check_ncicmd_write_window(uint16_t cmd_len, uint8_t* p_cmd) { NFCSTATUS status = NFCSTATUS_FAILED; int sem_timedout = 2, s; struct timespec ts; if (cmd_len < 1) { android_errorWriteLog(0x534e4554, "153880357"); return NFCSTATUS_FAILED; } if ((p_cmd[0] & 0xF0) == 0x20) { clock_gettime(CLOCK_REALTIME, &ts); ts.tv_sec += sem_timedout; while ((s = sem_timedwait(&nxpncihal_ctrl.syncSpiNfc, &ts)) == -1 && errno == EINTR) continue; /* Restart if interrupted by handler */ if (s != -1) { status = NFCSTATUS_SUCCESS; } } else { /* cmd window check not required for writing data packet */ status = NFCSTATUS_SUCCESS; } return status; } /****************************************************************************** * Function phNxpNciHal_ioctl * * Description This function is called by jni when wired mode is * performed.First Pn54x driver will give the access * permission whether wired mode is allowed or not * arg (0): * Returns return 0 on success and -1 on fail, On success * update the acutual state of operation in arg pointer * ******************************************************************************/ int phNxpNciHal_ioctl(long arg, void* p_data) { NXPLOG_NCIHAL_D("%s : enter - arg = %ld", __func__, arg); nfc_nci_IoctlInOutData_t* pInpOutData = (nfc_nci_IoctlInOutData_t*)p_data; int ret = -1; long level; level = pInpOutData->inp.level; if (nxpncihal_ctrl.halStatus == HAL_STATUS_CLOSE) { NFCSTATUS status = NFCSTATUS_FAILED; status = phNxpNciHal_MinOpen(); if (status != NFCSTATUS_SUCCESS) { pInpOutData->out.data.nciRsp.p_rsp[3] = 1; return -1; } } switch (arg) { case HAL_NFC_IOCTL_SPI_DWP_SYNC: { ret = phNxpNciHal_send_ese_hal_cmd(pInpOutData->inp.data.nciCmd.cmd_len, pInpOutData->inp.data.nciCmd.p_cmd); pInpOutData->out.data.nciRsp.rsp_len = nxpncihal_ctrl.rx_ese_data_len; if ((nxpncihal_ctrl.rx_ese_data_len > 0) && (nxpncihal_ctrl.rx_ese_data_len <= MAX_IOCTL_TRANSCEIVE_RESP_LEN) && (nxpncihal_ctrl.p_rx_ese_data != NULL)) { memcpy(pInpOutData->out.data.nciRsp.p_rsp, nxpncihal_ctrl.p_rx_ese_data, nxpncihal_ctrl.rx_ese_data_len); } if (pInpOutData->out.data.nciRsp.p_rsp[0] == 0x4F && pInpOutData->out.data.nciRsp.p_rsp[1] == 0x01 && pInpOutData->out.data.nciRsp.p_rsp[2] == 0x01 && pInpOutData->out.data.nciRsp.p_rsp[3] == 0x00 && pInpOutData->inp.data.nciCmd.p_cmd[3] == 0x01) { NXPLOG_NCIHAL_D("OMAPI COMMAND for Open SUCCESS : 0x%x", pInpOutData->out.data.nciRsp.p_rsp[3]); ret = pInpOutData->out.data.nciRsp.p_rsp[3]; } else if (pInpOutData->out.data.nciRsp.p_rsp[0] == 0x4F && pInpOutData->out.data.nciRsp.p_rsp[1] == 0x01 && pInpOutData->out.data.nciRsp.p_rsp[2] == 0x01 && pInpOutData->out.data.nciRsp.p_rsp[3] == 0x00 && pInpOutData->inp.data.nciCmd.p_cmd[3] == 0x00) { NXPLOG_NCIHAL_D("OMAPI COMMAND for Close SUCCESS : 0x%x", pInpOutData->out.data.nciRsp.p_rsp[3]); ret = pInpOutData->out.data.nciRsp.p_rsp[3]; } else { NXPLOG_NCIHAL_D("OMAPI COMMAND FAILURE : 0x%x", pInpOutData->out.data.nciRsp.p_rsp[3]); ret = pInpOutData->out.data.nciRsp.p_rsp[3] = 3; // magic number for omapi failure } } break; case HAL_NFC_SET_SPM_PWR: ret = phPalEse_spi_ioctl(phPalEse_e_ChipRst, gpphTmlNfc_Context->pDevHandle, level); if ((nxpncihal_ctrl.halStatus == HAL_STATUS_MIN_OPEN) && (level == 0x01)) { NXPLOG_NCIHAL_D(" HAL close after SPI close , while NFC is Off"); phNxpNciHal_close(false); } break; case HAL_NFC_SET_POWER_SCHEME: ret = phPalEse_spi_ioctl(phPalEse_e_SetPowerScheme, gpphTmlNfc_Context->pDevHandle, level); break; case HAL_NFC_GET_SPM_STATUS: ret = phPalEse_spi_ioctl(phPalEse_e_GetSPMStatus, gpphTmlNfc_Context->pDevHandle, level); break; case HAL_NFC_GET_ESE_ACCESS: ret = phPalEse_spi_ioctl(phPalEse_e_GetEseAccess, gpphTmlNfc_Context->pDevHandle, level); break; case HAL_NFC_SET_DWNLD_STATUS: ret = phPalEse_spi_ioctl(phPalEse_e_SetJcopDwnldState, gpphTmlNfc_Context->pDevHandle, level); break; case HAL_NFC_INHIBIT_PWR_CNTRL: ret = phPalEse_spi_ioctl(phPalEse_e_DisablePwrCntrl, gpphTmlNfc_Context->pDevHandle, level); break; case HAL_NFC_IOCTL_RF_STATUS_UPDATE: NXPLOG_NCIHAL_D("HAL_NFC_IOCTL_RF_STATUS_UPDATE Enter value is %d: \n", pInpOutData->inp.data.nciCmd.p_cmd[0]); if (gpEseAdapt != NULL) ret = gpEseAdapt->HalIoctl(HAL_NFC_IOCTL_RF_STATUS_UPDATE, pInpOutData); break; default: NXPLOG_NCIHAL_E("%s : Wrong arg = %ld", __func__, arg); break; } NXPLOG_NCIHAL_D("%s : exit - ret = %d", __func__, ret); return ret; } /****************************************************************************** * Function phNxpNciHal_get_mw_eeprom * * Description This function is called to retreive data in mw eeprom area * * Returns NFCSTATUS. * ******************************************************************************/ static NFCSTATUS phNxpNciHal_get_mw_eeprom(void) { NFCSTATUS status = NFCSTATUS_SUCCESS; uint8_t retry_cnt = 0; static uint8_t get_mw_eeprom_cmd[] = {0x20, 0x03, 0x03, 0x01, 0xA0, 0x0F}; retry_send_ext: if (retry_cnt > 3) { return NFCSTATUS_FAILED; } phNxpNciMwEepromArea.isGetEepromArea = true; status = phNxpNciHal_send_ext_cmd(sizeof(get_mw_eeprom_cmd), get_mw_eeprom_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_D("unable to get the mw eeprom data"); phNxpNciMwEepromArea.isGetEepromArea = false; retry_cnt++; goto retry_send_ext; } phNxpNciMwEepromArea.isGetEepromArea = false; if (phNxpNciMwEepromArea.p_rx_data[12]) { fw_download_success = 1; } return status; } /****************************************************************************** * Function phNxpNciHal_set_mw_eeprom * * Description This function is called to update data in mw eeprom area * * Returns void. * ******************************************************************************/ static NFCSTATUS phNxpNciHal_set_mw_eeprom(void) { NFCSTATUS status = NFCSTATUS_SUCCESS; uint8_t retry_cnt = 0; uint8_t set_mw_eeprom_cmd[39] = {0}; uint8_t cmd_header[] = {0x20, 0x02, 0x24, 0x01, 0xA0, 0x0F, 0x20}; memcpy(set_mw_eeprom_cmd, cmd_header, sizeof(cmd_header)); phNxpNciMwEepromArea.p_rx_data[12] = 0; memcpy(set_mw_eeprom_cmd + sizeof(cmd_header), phNxpNciMwEepromArea.p_rx_data, sizeof(phNxpNciMwEepromArea.p_rx_data)); retry_send_ext: if (retry_cnt > 3) { return NFCSTATUS_FAILED; } status = phNxpNciHal_send_ext_cmd(sizeof(set_mw_eeprom_cmd), set_mw_eeprom_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_D("unable to update the mw eeprom data"); retry_cnt++; goto retry_send_ext; } return status; } /****************************************************************************** * Function phNxpNciHal_set_clock * * Description This function is called after successfull download * to apply the clock setting provided in config file * * Returns void. * ******************************************************************************/ static void phNxpNciHal_set_clock(void) { NFCSTATUS status = NFCSTATUS_FAILED; int retryCount = 0; retrySetclock: phNxpNciClock.isClockSet = true; if (nxpprofile_ctrl.bClkSrcVal == CLK_SRC_PLL) { static uint8_t set_clock_cmd[] = {0x20, 0x02, 0x09, 0x02, 0xA0, 0x03, 0x01, 0x11, 0xA0, 0x04, 0x01, 0x01}; uint8_t param_clock_src = 0x00; if ((nfcFL.chipType != pn553) && (nfcFL.chipType != pn557)) { uint8_t param_clock_src = CLK_SRC_PLL; param_clock_src = param_clock_src << 3; } if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_13MHZ) { param_clock_src |= 0x00; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_19_2MHZ) { param_clock_src |= 0x01; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_24MHZ) { param_clock_src |= 0x02; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_26MHZ) { param_clock_src |= 0x03; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_38_4MHZ) { param_clock_src |= 0x04; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_52MHZ) { param_clock_src |= 0x05; } else { NXPLOG_NCIHAL_E("Wrong clock freq, send default PLL@19.2MHz"); if ((nfcFL.chipType == pn553) || (nfcFL.chipType == pn557)) { param_clock_src = 0x01; } else { param_clock_src = 0x11; } } set_clock_cmd[7] = param_clock_src; set_clock_cmd[11] = nxpprofile_ctrl.bTimeout; status = phNxpNciHal_send_ext_cmd(sizeof(set_clock_cmd), set_clock_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("PLL colck setting failed !!"); } } else if (nxpprofile_ctrl.bClkSrcVal == CLK_SRC_XTAL) { static uint8_t set_clock_cmd[] = {0x20, 0x02, 0x05, 0x01, 0xA0, 0x03, 0x01, 0x08}; status = phNxpNciHal_send_ext_cmd(sizeof(set_clock_cmd), set_clock_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("XTAL colck setting failed !!"); } } else { NXPLOG_NCIHAL_E("Wrong clock source. Don't apply any modification") } // Checking for SET CONFG SUCCESS, re-send the command if not. phNxpNciClock.isClockSet = false; if (phNxpNciClock.p_rx_data[3] != NFCSTATUS_SUCCESS) { if (retryCount++ < 3) { NXPLOG_NCIHAL_D("Set-clk failed retry again "); goto retrySetclock; } else { NXPLOG_NCIHAL_E("Set clk failed - max count = 0x%x exceeded ", retryCount); // NXPLOG_NCIHAL_E("Set Config is failed for Clock Due to // elctrical disturbances, aborting the NFC process"); // abort (); } } } /****************************************************************************** * Function phNxpNciHal_check_clock_config * * Description This function is called after successfull download * to check if clock settings in config file and chip * is same * * Returns void. * ******************************************************************************/ NFCSTATUS phNxpNciHal_check_clock_config(void) { NFCSTATUS status = NFCSTATUS_SUCCESS; uint8_t param_clock_src; static uint8_t get_clock_cmd[] = {0x20, 0x03, 0x07, 0x03, 0xA0, 0x02, 0xA0, 0x03, 0xA0, 0x04}; phNxpNciClock.isClockSet = true; phNxpNciHal_get_clk_freq(); status = phNxpNciHal_send_ext_cmd(sizeof(get_clock_cmd), get_clock_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("unable to retrieve get_clk_src_sel"); return status; } param_clock_src = check_config_parameter(); if (phNxpNciClock.p_rx_data[12] == param_clock_src && phNxpNciClock.p_rx_data[16] == nxpprofile_ctrl.bTimeout) { phNxpNciClock.issetConfig = false; } else { phNxpNciClock.issetConfig = true; } phNxpNciClock.isClockSet = false; return status; } /****************************************************************************** * Function phNxpNciHal_china_tianjin_rf_setting * * Description This function is called to check RF Setting * * Returns Status. * ******************************************************************************/ NFCSTATUS phNxpNciHal_china_tianjin_rf_setting(void) { NFCSTATUS status = NFCSTATUS_SUCCESS; int isfound = 0; int rf_enable = false; int rf_val = 0; int send_flag; uint8_t retry_cnt = 0; int enable_bit = 0; static uint8_t get_rf_cmd[] = {0x20, 0x03, 0x03, 0x01, 0xA0, 0x85}; retry_send_ext: if (retry_cnt > 3) { return NFCSTATUS_FAILED; } send_flag = true; phNxpNciRfSet.isGetRfSetting = true; status = phNxpNciHal_send_ext_cmd(sizeof(get_rf_cmd), get_rf_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("unable to get the RF setting"); phNxpNciRfSet.isGetRfSetting = false; retry_cnt++; goto retry_send_ext; } phNxpNciRfSet.isGetRfSetting = false; if (phNxpNciRfSet.p_rx_data[3] != 0x00) { NXPLOG_NCIHAL_E("GET_CONFIG_RSP is FAILED for CHINA TIANJIN"); return status; } rf_val = phNxpNciRfSet.p_rx_data[10]; isfound = (GetNxpNumValue(NAME_NXP_CHINA_TIANJIN_RF_ENABLED, (void*)&rf_enable, sizeof(rf_enable))); if (isfound > 0) { enable_bit = rf_val & 0x40; if ((enable_bit != 0x40) && (rf_enable == 1)) { phNxpNciRfSet.p_rx_data[10] |= 0x40; // Enable if it is disabled } else if ((enable_bit == 0x40) && (rf_enable == 0)) { phNxpNciRfSet.p_rx_data[10] &= 0xBF; // Disable if it is Enabled } else { send_flag = false; // No need to change in RF setting } if (send_flag == true) { static uint8_t set_rf_cmd[] = {0x20, 0x02, 0x08, 0x01, 0xA0, 0x85, 0x04, 0x50, 0x08, 0x68, 0x00}; memcpy(&set_rf_cmd[4], &phNxpNciRfSet.p_rx_data[5], 7); status = phNxpNciHal_send_ext_cmd(sizeof(set_rf_cmd), set_rf_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("unable to set the RF setting"); retry_cnt++; goto retry_send_ext; } } } return status; } /****************************************************************************** * Function phNxpNciHal_gpio_restore * * Description This function restores the gpio values into eeprom * * Returns void * ******************************************************************************/ static void phNxpNciHal_gpio_restore(phNxpNciHal_GpioInfoState state) { NFCSTATUS status = NFCSTATUS_SUCCESS; uint8_t get_gpio_values_cmd[] = {0x20, 0x03, 0x03, 0x01, 0xA0, 0x00}; uint8_t set_gpio_values_cmd[] = { 0x20, 0x02, 0x00, 0x01, 0xA0, 0x00, 0x20, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}; if (state == GPIO_STORE) { nxpncihal_ctrl.phNxpNciGpioInfo.state = GPIO_STORE; get_gpio_values_cmd[5] = 0x08; status = phNxpNciHal_send_ext_cmd(sizeof(get_gpio_values_cmd), get_gpio_values_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Failed to get GPIO values!!!\n"); return; } nxpncihal_ctrl.phNxpNciGpioInfo.state = GPIO_STORE_DONE; set_gpio_values_cmd[2] = 0x24; set_gpio_values_cmd[5] = 0x14; set_gpio_values_cmd[7] = nxpncihal_ctrl.phNxpNciGpioInfo.values[0]; set_gpio_values_cmd[8] = nxpncihal_ctrl.phNxpNciGpioInfo.values[1]; status = phNxpNciHal_send_ext_cmd(sizeof(set_gpio_values_cmd), set_gpio_values_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Failed to set GPIO values!!!\n"); return; } } else if (state == GPIO_RESTORE) { nxpncihal_ctrl.phNxpNciGpioInfo.state = GPIO_RESTORE; get_gpio_values_cmd[5] = 0x14; status = phNxpNciHal_send_ext_cmd(sizeof(get_gpio_values_cmd), get_gpio_values_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Failed to get GPIO values!!!\n"); return; } nxpncihal_ctrl.phNxpNciGpioInfo.state = GPIO_RESTORE_DONE; set_gpio_values_cmd[2] = 0x06; set_gpio_values_cmd[5] = 0x08; // update TAG set_gpio_values_cmd[6] = 0x02; // update length set_gpio_values_cmd[7] = nxpncihal_ctrl.phNxpNciGpioInfo.values[0]; set_gpio_values_cmd[8] = nxpncihal_ctrl.phNxpNciGpioInfo.values[1]; status = phNxpNciHal_send_ext_cmd(9, set_gpio_values_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("Failed to set GPIO values!!!\n"); return; } } else { NXPLOG_NCIHAL_E("GPIO Restore Invalid Option!!!\n"); } } /****************************************************************************** * Function phNxpNciHal_nfcc_core_reset_init * * Description Helper function to do nfcc core reset & core init * * Returns Status * ******************************************************************************/ NFCSTATUS phNxpNciHal_nfcc_core_reset_init() { NFCSTATUS status = NFCSTATUS_FAILED; uint8_t retry_cnt = 0; uint8_t cmd_reset_nci[] = {0x20, 0x00, 0x01, 0x01}; retry_core_reset: status = phNxpNciHal_send_ext_cmd(sizeof(cmd_reset_nci), cmd_reset_nci); if ((status != NFCSTATUS_SUCCESS) && (retry_cnt < 3)) { NXPLOG_NCIHAL_D("Retry: NCI_CORE_RESET"); retry_cnt++; goto retry_core_reset; } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_RESET failed!!!\n"); return status; } retry_cnt = 0; uint8_t cmd_init_nci[] = {0x20, 0x01, 0x00}; uint8_t cmd_init_nci2_0[] = {0x20, 0x01, 0x02, 0x00, 0x00}; retry_core_init: if (nxpncihal_ctrl.nci_info.nci_version == NCI_VERSION_2_0) { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci2_0), cmd_init_nci2_0); } else { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci), cmd_init_nci); } if ((status != NFCSTATUS_SUCCESS) && (retry_cnt < 3)) { NXPLOG_NCIHAL_D("Retry: NCI_CORE_INIT\n"); retry_cnt++; goto retry_core_init; } else if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_INIT failed!!!\n"); return status; } return status; } /****************************************************************************** * Function phNxpNciHal_getChipInfoInFwDnldMode * * Description Helper function to get the chip info in download mode * * Returns Status * ******************************************************************************/ NFCSTATUS phNxpNciHal_getChipInfoInFwDnldMode(void) { NFCSTATUS status = NFCSTATUS_FAILED; uint8_t retry_cnt = 0; uint8_t get_chip_info_cmd[] = {0x00, 0x04, 0xF1, 0x00, 0x00, 0x00, 0x6E, 0xEF}; NXPLOG_NCIHAL_D("%s:enter", __func__); retry: status = phNxpNciHal_send_ext_cmd(sizeof(get_chip_info_cmd), get_chip_info_cmd); if (status != NFCSTATUS_SUCCESS) { if (retry_cnt < 3) { NXPLOG_NCIHAL_D("Retry: get chip info"); retry_cnt++; goto retry; } else { NXPLOG_NCIHAL_E("Failed: get chip info"); } } else { phNxpNciHal_configFeatureList(nxpncihal_ctrl.p_rx_data, nxpncihal_ctrl.rx_data_len); } NXPLOG_NCIHAL_D("%s:exit status: 0x%02x", __func__, status); return status; } int check_config_parameter() { uint8_t param_clock_src = CLK_SRC_PLL; if (nxpprofile_ctrl.bClkSrcVal == CLK_SRC_PLL) { if ((nfcFL.chipType != pn553) && (nfcFL.chipType != pn557)) { param_clock_src = param_clock_src << 3; } if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_13MHZ) { param_clock_src |= 0x00; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_19_2MHZ) { param_clock_src |= 0x01; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_24MHZ) { param_clock_src |= 0x02; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_26MHZ) { param_clock_src |= 0x03; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_38_4MHZ) { param_clock_src |= 0x04; } else if (nxpprofile_ctrl.bClkFreqVal == CLK_FREQ_52MHZ) { param_clock_src |= 0x05; } else { NXPLOG_NCIHAL_E("Wrong clock freq, send default PLL@19.2MHz"); param_clock_src = 0x11; } } else if (nxpprofile_ctrl.bClkSrcVal == CLK_SRC_XTAL) { param_clock_src = 0x08; } else { NXPLOG_NCIHAL_E("Wrong clock source. Don't apply any modification") } return param_clock_src; } /****************************************************************************** * Function phNxpNciHal_enable_i2c_fragmentation * * Description This function is called to process the response status * and print the status byte. * * Returns void. * ******************************************************************************/ void phNxpNciHal_enable_i2c_fragmentation() { NFCSTATUS status = NFCSTATUS_FAILED; static uint8_t fragmentation_enable_config_cmd[] = {0x20, 0x02, 0x05, 0x01, 0xA0, 0x05, 0x01, 0x10}; long i2c_status = 0x00; long config_i2c_vlaue = 0xff; /*NCI_RESET_CMD*/ static uint8_t cmd_reset_nci[] = {0x20, 0x00, 0x01, 0x00}; /*NCI_INIT_CMD*/ static uint8_t cmd_init_nci[] = {0x20, 0x01, 0x00}; static uint8_t cmd_init_nci2_0[] = {0x20, 0x01, 0x02, 0x00, 0x00}; static uint8_t get_i2c_fragmentation_cmd[] = {0x20, 0x03, 0x03, 0x01, 0xA0, 0x05}; if (GetNxpNumValue(NAME_NXP_I2C_FRAGMENTATION_ENABLED, (void*)&i2c_status, sizeof(i2c_status)) == true) { NXPLOG_FWDNLD_D("I2C status : %ld", i2c_status); } else { NXPLOG_FWDNLD_E("I2C status read not succeeded. Default value : %ld", i2c_status); } status = phNxpNciHal_send_ext_cmd(sizeof(get_i2c_fragmentation_cmd), get_i2c_fragmentation_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("unable to retrieve get_i2c_fragmentation_cmd"); } else { if (nxpncihal_ctrl.p_rx_data[8] == 0x10) { config_i2c_vlaue = 0x01; phNxpNciHal_notify_i2c_fragmentation(); phTmlNfc_set_fragmentation_enabled(I2C_FRAGMENTATION_ENABLED); } else if (nxpncihal_ctrl.p_rx_data[8] == 0x00) { config_i2c_vlaue = 0x00; } // if the value already matches, nothing to be done if (config_i2c_vlaue != i2c_status) { if (i2c_status == 0x01) { /* NXP I2C fragmenation enabled*/ status = phNxpNciHal_send_ext_cmd(sizeof(fragmentation_enable_config_cmd), fragmentation_enable_config_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NXP fragmentation enable failed"); } } else if (i2c_status == 0x00 || config_i2c_vlaue == 0xff) { fragmentation_enable_config_cmd[7] = 0x00; /* NXP I2C fragmentation disabled*/ status = phNxpNciHal_send_ext_cmd(sizeof(fragmentation_enable_config_cmd), fragmentation_enable_config_cmd); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NXP fragmentation disable failed"); } } status = phNxpNciHal_send_ext_cmd(sizeof(cmd_reset_nci), cmd_reset_nci); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_RESET: Failed"); } if (nxpncihal_ctrl.nci_info.nci_version == NCI_VERSION_2_0) { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci2_0), cmd_init_nci2_0); } else { status = phNxpNciHal_send_ext_cmd(sizeof(cmd_init_nci), cmd_init_nci); } if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("NCI_CORE_INIT : Failed"); } else if (i2c_status == 0x01) { phNxpNciHal_notify_i2c_fragmentation(); phTmlNfc_set_fragmentation_enabled(I2C_FRAGMENTATION_ENABLED); } } } } /****************************************************************************** * Function phNxpNciHal_do_se_session_reset * * Description This function is called to set the session id to default * value. * * Returns NFCSTATUS. * ******************************************************************************/ static NFCSTATUS phNxpNciHal_do_se_session_reset(void) { static uint8_t reset_se_session_identity_set[] = { 0x20, 0x02, 0x17, 0x02, 0xA0, 0xEA, 0x08, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xA0, 0xEB, 0x08, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF}; NFCSTATUS status = phNxpNciHal_send_ext_cmd( sizeof(reset_se_session_identity_set), reset_se_session_identity_set); NXPLOG_NCIHAL_D("%s status = %x ", __func__, status); return status; } /****************************************************************************** * Function phNxpNciHal_do_factory_reset * * Description This function is called during factory reset to clear/reset * nfc sub-system persistant data. * * Returns void. * ******************************************************************************/ void phNxpNciHal_do_factory_reset(void) { NFCSTATUS status = NFCSTATUS_FAILED; if (nxpncihal_ctrl.halStatus == HAL_STATUS_CLOSE) { status = phNxpNciHal_MinOpen(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("%s: NXP Nfc Open failed", __func__); return; } } status = phNxpNciHal_do_se_session_reset(); if (status != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_E("%s failed. status = %x ", __func__, status); } } /****************************************************************************** * Function phNxpNciHal_hci_network_reset * * Description This function resets the session id's of all the se's * in the HCI network and notify to HCI_NETWORK_RESET event to * NFC HAL Client. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_hci_network_reset(void) { static phLibNfc_Message_t msg; msg.pMsgData = NULL; msg.Size = 0; NFCSTATUS status = phNxpNciHal_do_se_session_reset(); if (status != NFCSTATUS_SUCCESS) { msg.eMsgType = NCI_HAL_ERROR_MSG; } else { msg.eMsgType = NCI_HAL_HCI_NETWORK_RESET_MSG; } phTmlNfc_DeferredCall(gpphTmlNfc_Context->dwCallbackThreadId, &msg); } /******************************************************************************* ** ** Function phNxpNciHal_configFeatureList ** ** Description Configures the featureList based on chip type ** HW Version information number will provide chipType. ** HW Version can be obtained from CORE_INIT_RESPONSE(NCI 1.0) ** or CORE_RST_NTF(NCI 2.0) or PROPREITARY RSP (FW download * mode) ** ** Parameters CORE_INIT_RESPONSE/CORE_RST_NTF/PROPREITARY RSP, len ** ** Returns none *******************************************************************************/ void phNxpNciHal_configFeatureList(uint8_t* msg, uint16_t msg_len) { tNFC_chipType chipType = pConfigFL->getChipType(msg, msg_len); CONFIGURE_FEATURELIST(chipType); NXPLOG_NCIHAL_D("%s chipType = %d", __func__, chipType); } /****************************************************************************** * Function phNxpNciHal_print_res_status * * Description This function is called to process the response status * and print the status byte. * * Returns void. * ******************************************************************************/ static void phNxpNciHal_print_res_status(uint8_t* p_rx_data, uint16_t* p_len) { static uint8_t response_buf[][30] = {"STATUS_OK", "STATUS_REJECTED", "STATUS_RF_FRAME_CORRUPTED", "STATUS_FAILED", "STATUS_NOT_INITIALIZED", "STATUS_SYNTAX_ERROR", "STATUS_SEMANTIC_ERROR", "RFU", "RFU", "STATUS_INVALID_PARAM", "STATUS_MESSAGE_SIZE_EXCEEDED", "STATUS_UNDEFINED"}; int status_byte; if (p_rx_data[0] == 0x40 && (p_rx_data[1] == 0x02 || p_rx_data[1] == 0x03)) { if (p_rx_data[2] && p_rx_data[3] <= 10) { status_byte = p_rx_data[CORE_RES_STATUS_BYTE]; NXPLOG_NCIHAL_D("%s: response status =%s", __func__, response_buf[status_byte]); } else { NXPLOG_NCIHAL_D("%s: response status =%s", __func__, response_buf[11]); } if (phNxpNciClock.isClockSet) { int i, len = sizeof(phNxpNciClock.p_rx_data); if (*p_len > len) { android_errorWriteLog(0x534e4554, "169257710"); } else { len = *p_len; } for (i = 0; i < len; i++) { phNxpNciClock.p_rx_data[i] = p_rx_data[i]; } } else if (phNxpNciRfSet.isGetRfSetting) { int i, len = sizeof(phNxpNciRfSet.p_rx_data); if (*p_len > len) { android_errorWriteLog(0x534e4554, "169258733"); } else { len = *p_len; } for (i = 0; i < len; i++) { phNxpNciRfSet.p_rx_data[i] = p_rx_data[i]; // NXPLOG_NCIHAL_D("%s: response status =0x%x",__func__,p_rx_data[i]); } } else if (phNxpNciMwEepromArea.isGetEepromArea) { int i, len = sizeof(phNxpNciMwEepromArea.p_rx_data) + 8; if (*p_len > len) { android_errorWriteLog(0x534e4554, "169258884"); } else { len = *p_len; } for (i = 8; i < len; i++) { phNxpNciMwEepromArea.p_rx_data[i - 8] = p_rx_data[i]; } } else if (nxpncihal_ctrl.phNxpNciGpioInfo.state == GPIO_STORE) { NXPLOG_NCIHAL_D("%s: Storing GPIO Values...", __func__); nxpncihal_ctrl.phNxpNciGpioInfo.values[0] = p_rx_data[9]; nxpncihal_ctrl.phNxpNciGpioInfo.values[1] = p_rx_data[8]; } else if (nxpncihal_ctrl.phNxpNciGpioInfo.state == GPIO_RESTORE) { NXPLOG_NCIHAL_D("%s: Restoring GPIO Values...", __func__); nxpncihal_ctrl.phNxpNciGpioInfo.values[0] = p_rx_data[9]; nxpncihal_ctrl.phNxpNciGpioInfo.values[1] = p_rx_data[8]; } } if (p_rx_data[2] && (config_access == true)) { if (p_rx_data[3] != NFCSTATUS_SUCCESS) { NXPLOG_NCIHAL_W("Invalid Data from config file."); config_success = false; } } } /****************************************************************************** * Function phNxpNciHal_initialize_mifare_flag * * Description This function gets the value for Mfc flags. * * Returns void * ******************************************************************************/ static void phNxpNciHal_initialize_mifare_flag() { unsigned long num = 0; bEnableMfcReader = false; bDisableLegacyMfcExtns = true; // 1: Enable Mifare Classic protocol in RF Discovery. // 0: Remove Mifare Classic protocol in RF Discovery. if (GetNxpNumValue(NAME_MIFARE_READER_ENABLE, &num, sizeof(num))) { bEnableMfcReader = (num == 0) ? false : true; } // 1: Use legacy JNI MFC extns. // 0: Disable legacy JNI MFC extns, use hal MFC Extns instead. if (GetNxpNumValue(NAME_LEGACY_MIFARE_READER, &num, sizeof(num))) { bDisableLegacyMfcExtns = (num == 0) ? true : false; } }