/**************************************************************************//** * @file sc.c * @version V3.00 * @brief M480 Smartcard(SC) driver source file * * @copyright (C) 2016 Nuvoton Technology Corp. All rights reserved. *****************************************************************************/ #include "NuMicro.h" /* Below are variables used locally by SC driver and does not want to parse by doxygen unless HIDDEN_SYMBOLS is defined */ /** @cond HIDDEN_SYMBOLS */ static uint32_t u32CardStateIgnore[SC_INTERFACE_NUM] = {0UL, 0UL, 0UL}; /** @endcond HIDDEN_SYMBOLS */ /** @addtogroup Standard_Driver Standard Driver @{ */ /** @addtogroup SC_Driver SC Driver @{ */ /** @addtogroup SC_EXPORTED_FUNCTIONS SC Exported Functions @{ */ /** * @brief This function indicates specified smartcard slot status * @param[in] sc Base address of smartcard module * @return Card insert status * @retval TRUE Card insert * @retval FALSE Card remove */ uint32_t SC_IsCardInserted(SC_T *sc) { uint32_t ret; /* put conditions into two variable to remove IAR compilation warning */ uint32_t cond1 = ((sc->STATUS & SC_STATUS_CDPINSTS_Msk) >> SC_STATUS_CDPINSTS_Pos); uint32_t cond2 = ((sc->CTL & SC_CTL_CDLV_Msk) >> SC_CTL_CDLV_Pos); if((sc == SC0) && (u32CardStateIgnore[0] == 1UL)) { ret = (uint32_t)TRUE; } else if((sc == SC1) && (u32CardStateIgnore[1] == 1UL)) { ret = (uint32_t)TRUE; } else if((sc == SC2) && (u32CardStateIgnore[2] == 1UL)) { ret = (uint32_t)TRUE; } else if(cond1 != cond2) { ret = (uint32_t)FALSE; } else { ret = (uint32_t)TRUE; } return ret; } /** * @brief This function reset both transmit and receive FIFO of specified smartcard module * @param[in] sc Base address of smartcard module * @return None */ void SC_ClearFIFO(SC_T *sc) { while(sc->ALTCTL & SC_ALTCTL_SYNC_Msk) { ; } sc->ALTCTL |= (SC_ALTCTL_TXRST_Msk | SC_ALTCTL_RXRST_Msk); } /** * @brief This function disable specified smartcard module * @param[in] sc Base address of smartcard module * @return None */ void SC_Close(SC_T *sc) { sc->INTEN = 0UL; while(sc->PINCTL & SC_PINCTL_SYNC_Msk) { ; } sc->PINCTL = 0UL; sc->ALTCTL = 0UL; while(sc->CTL & SC_CTL_SYNC_Msk) { ; } sc->CTL = 0UL; } /** * @brief This function initialized smartcard module * @param[in] sc Base address of smartcard module * @param[in] u32CardDet Card detect polarity, select the CD pin state which indicates card absent. Could be * -\ref SC_PIN_STATE_HIGH * -\ref SC_PIN_STATE_LOW * -\ref SC_PIN_STATE_IGNORE, no card detect pin, always assumes card present * @param[in] u32PWR Power on polarity, select the PWR pin state which could set smartcard VCC to high level. Could be * -\ref SC_PIN_STATE_HIGH * -\ref SC_PIN_STATE_LOW * @return None */ void SC_Open(SC_T *sc, uint32_t u32CardDet, uint32_t u32PWR) { uint32_t u32Reg = 0UL, u32Intf; if(sc == SC0) { u32Intf = 0UL; } else if(sc == SC1) { u32Intf = 1UL; } else { u32Intf = 2UL; } if(u32CardDet != SC_PIN_STATE_IGNORE) { u32Reg = u32CardDet ? 0UL: SC_CTL_CDLV_Msk; u32CardStateIgnore[u32Intf] = 0UL; } else { u32CardStateIgnore[u32Intf] = 1UL; } sc->PINCTL = u32PWR ? 0UL : SC_PINCTL_PWRINV_Msk; while(sc->CTL & SC_CTL_SYNC_Msk) { ; } sc->CTL = SC_CTL_SCEN_Msk | SC_CTL_TMRSEL_Msk | u32Reg; } /** * @brief This function reset specified smartcard module to its default state for activate smartcard * @param[in] sc Base address of smartcard module * @return None */ void SC_ResetReader(SC_T *sc) { uint32_t u32Intf; if(sc == SC0) { u32Intf = 0UL; } else if(sc == SC1) { u32Intf = 1UL; } else { u32Intf = 2UL; } /* Reset FIFO, enable auto de-activation while card removal */ sc->ALTCTL |= (SC_ALTCTL_TXRST_Msk | SC_ALTCTL_RXRST_Msk | SC_ALTCTL_ADACEN_Msk); /* Set Rx trigger level to 1 character, longest card detect debounce period, disable error retry (EMV ATR does not use error retry) */ while(sc->CTL & SC_CTL_SYNC_Msk) { ; } sc->CTL &= ~(SC_CTL_RXTRGLV_Msk | SC_CTL_CDDBSEL_Msk | SC_CTL_TXRTY_Msk | SC_CTL_TXRTYEN_Msk | SC_CTL_RXRTY_Msk | SC_CTL_RXRTYEN_Msk); while(sc->CTL & SC_CTL_SYNC_Msk) { ; } /* Enable auto convention, and all three smartcard internal timers */ sc->CTL |= SC_CTL_AUTOCEN_Msk | SC_CTL_TMRSEL_Msk; /* Disable Rx timeout */ sc->RXTOUT = 0UL; /* 372 clocks per ETU by default */ sc->ETUCTL= 371UL; /* Enable necessary interrupt for smartcard operation */ if(u32CardStateIgnore[u32Intf]) /* Do not enable card detect interrupt if card present state ignore */ { sc->INTEN = (SC_INTEN_RDAIEN_Msk | SC_INTEN_TERRIEN_Msk | SC_INTEN_TMR0IEN_Msk | SC_INTEN_TMR1IEN_Msk | SC_INTEN_TMR2IEN_Msk | SC_INTEN_BGTIEN_Msk | SC_INTEN_ACERRIEN_Msk); } else { sc->INTEN = (SC_INTEN_RDAIEN_Msk | SC_INTEN_TERRIEN_Msk | SC_INTEN_TMR0IEN_Msk | SC_INTEN_TMR1IEN_Msk | SC_INTEN_TMR2IEN_Msk | SC_INTEN_BGTIEN_Msk | SC_INTEN_CDIEN_Msk | SC_INTEN_ACERRIEN_Msk); } return; } /** * @brief This function block guard time (BGT) of specified smartcard module * @param[in] sc Base address of smartcard module * @param[in] u32BGT Block guard time using ETU as unit, valid range are between 1 ~ 32 * @return None */ void SC_SetBlockGuardTime(SC_T *sc, uint32_t u32BGT) { sc->CTL = (sc->CTL & ~SC_CTL_BGT_Msk) | ((u32BGT - 1UL) << SC_CTL_BGT_Pos); } /** * @brief This function character guard time (CGT) of specified smartcard module * @param[in] sc Base address of smartcard module * @param[in] u32CGT Character guard time using ETU as unit, valid range are between 11 ~ 267 * @return None */ void SC_SetCharGuardTime(SC_T *sc, uint32_t u32CGT) { u32CGT -= sc->CTL & SC_CTL_NSB_Msk ? 11UL: 12UL; sc->EGT = u32CGT; } /** * @brief This function stop all smartcard timer of specified smartcard module * @param[in] sc Base address of smartcard module * @return None * @note This function stop the timers within smartcard module, \b not timer module */ void SC_StopAllTimer(SC_T *sc) { while(sc->ALTCTL & SC_ALTCTL_SYNC_Msk) { ; } sc->ALTCTL &= ~(SC_ALTCTL_CNTEN0_Msk | SC_ALTCTL_CNTEN1_Msk | SC_ALTCTL_CNTEN2_Msk); } /** * @brief This function configure and start a smartcard timer of specified smartcard module * @param[in] sc Base address of smartcard module * @param[in] u32TimerNum Timer to start. Valid values are 0, 1, 2. * @param[in] u32Mode Timer operating mode, valid values are: * - \ref SC_TMR_MODE_0 * - \ref SC_TMR_MODE_1 * - \ref SC_TMR_MODE_2 * - \ref SC_TMR_MODE_3 * - \ref SC_TMR_MODE_4 * - \ref SC_TMR_MODE_5 * - \ref SC_TMR_MODE_6 * - \ref SC_TMR_MODE_7 * - \ref SC_TMR_MODE_8 * - \ref SC_TMR_MODE_F * @param[in] u32ETUCount Timer timeout duration, ETU based. For timer 0, valid range are between 1~0x1000000ETUs. * For timer 1 and timer 2, valid range are between 1 ~ 0x100 ETUs * @return None * @note This function start the timer within smartcard module, \b not timer module * @note Depend on the timer operating mode, timer may not start counting immediately */ void SC_StartTimer(SC_T *sc, uint32_t u32TimerNum, uint32_t u32Mode, uint32_t u32ETUCount) { uint32_t reg = u32Mode | (SC_TMRCTL0_CNT_Msk & (u32ETUCount - 1UL)); while(sc->ALTCTL & SC_ALTCTL_SYNC_Msk) { ; } if(u32TimerNum == 0UL) { while(sc->TMRCTL0 & SC_TMRCTL0_SYNC_Msk) { ; } sc->TMRCTL0 = reg; sc->ALTCTL |= SC_ALTCTL_CNTEN0_Msk; } else if(u32TimerNum == 1UL) { while(sc->TMRCTL1 & SC_TMRCTL1_SYNC_Msk) { ; } sc->TMRCTL1 = reg; sc->ALTCTL |= SC_ALTCTL_CNTEN1_Msk; } else /* timer 2 */ { while(sc->TMRCTL2 & SC_TMRCTL2_SYNC_Msk) { ; } sc->TMRCTL2 = reg; sc->ALTCTL |= SC_ALTCTL_CNTEN2_Msk; } } /** * @brief This function stop a smartcard timer of specified smartcard module * @param[in] sc Base address of smartcard module * @param[in] u32TimerNum Timer to stop. Valid values are 0, 1, 2. * @return None * @note This function stop the timer within smartcard module, \b not timer module */ void SC_StopTimer(SC_T *sc, uint32_t u32TimerNum) { while(sc->ALTCTL & SC_ALTCTL_SYNC_Msk) { ; } if(u32TimerNum == 0UL) { sc->ALTCTL &= ~SC_ALTCTL_CNTEN0_Msk; } else if(u32TimerNum == 1UL) { sc->ALTCTL &= ~SC_ALTCTL_CNTEN1_Msk; } else /* timer 2 */ { sc->ALTCTL &= ~SC_ALTCTL_CNTEN2_Msk; } } /** * @brief This function gets smartcard clock frequency. * @param[in] sc Base address of smartcard module * @return Smartcard frequency in kHz */ uint32_t SC_GetInterfaceClock(SC_T *sc) { uint32_t u32ClkSrc, u32Num, u32Clk; if(sc == SC0) { u32Num = 0UL; } else if(sc == SC1) { u32Num = 1UL; } else { u32Num = 2UL; } u32ClkSrc = (CLK->CLKSEL3 >> (2UL * u32Num)) & CLK_CLKSEL3_SC0SEL_Msk; /* Get smartcard module clock */ if(u32ClkSrc == 0UL) { u32Clk = __HXT; } else if(u32ClkSrc == 1UL) { u32Clk = CLK_GetPLLClockFreq(); } else if(u32ClkSrc == 2UL) { if(u32Num == 1UL) { u32Clk = CLK_GetPCLK1Freq(); } else { u32Clk = CLK_GetPCLK0Freq(); } } else { u32Clk = __HIRC; } u32Clk /= (((CLK->CLKDIV1 >> (8UL * u32Num)) & CLK_CLKDIV1_SC0DIV_Msk) + 1UL) * 1000UL; return u32Clk; } /*@}*/ /* end of group SC_EXPORTED_FUNCTIONS */ /*@}*/ /* end of group SC_Driver */ /*@}*/ /* end of group Standard_Driver */ /*** (C) COPYRIGHT 2016 Nuvoton Technology Corp. ***/