hoverboard-sideboard-hack-GD/Drivers/GD32F1x0_standard_peripheral/Source/gd32f1x0_fmc.c

/*!
    \file  gd32f1x0_fmc.c
    \brief FMC driver
*/

/*
    Copyright (C) 2017 GigaDevice

    2014-12-26, V1.0.0, platform GD32F1x0(x=3,5)
    2016-01-15, V2.0.0, platform GD32F1x0(x=3,5,7,9)
    2016-04-30, V3.0.0, firmware update for GD32F1x0(x=3,5,7,9)
    2017-06-19, V3.1.0, firmware update for GD32F1x0(x=3,5,7,9)
*/

#include "gd32f1x0_fmc.h"

/* FMC main memory programming functions */

/*!
    \brief      unlock the main FMC operation
                it is better to used in pairs with fmc_lock
    \param[in]  none
    \param[out] none
    \retval     none
*/
void fmc_unlock(void)
{
    if((RESET != (FMC_CTL & FMC_CTL_LK))){
        /* write the FMC key */
        FMC_KEY = UNLOCK_KEY0;
        FMC_KEY = UNLOCK_KEY1;
    }
}

/*!
    \brief      lock the main FMC operation
                it is better to used in pairs with fmc_unlock after an operation
    \param[in]  none
    \param[out] none
    \retval     none
*/
void fmc_lock(void)
{
    /* set the LK bit*/
    FMC_CTL |= FMC_CTL_LK;
}

/*!
    \brief      set the wait state counter value
    \param[in]  wscnt: wait state counter value
      \arg        WS_WSCNT_0: 0 wait state added
      \arg        WS_WSCNT_1: 1 wait state added
      \arg        WS_WSCNT_2: 2 wait state added
    \param[out] none
    \retval     none
*/
void fmc_wscnt_set(uint8_t wscnt)
{
    uint32_t reg;
    
    reg = FMC_WS;
    /* set the wait state counter value */
    reg &= ~FMC_WS_WSCNT;
    FMC_WS = (reg | wscnt);
}

/*!
    \brief      fmc wait state enable
    \param[in]  none
    \param[out] none
    \retval     none
*/
void fmc_wait_state_enable(void)
{
    /* unlock the main flash */
    fmc_unlock();

    /* set the WSEN bit in register FMC_WSEN */
    FMC_WSEN |= FMC_WSEN_WSEN;

    /* lock the main flash after operation */
    fmc_lock();
}

/*!
    \brief      fmc wait state disable
    \param[in]  none
    \param[out] none
    \retval     none
*/
void fmc_wait_state_disable(void)
{
    /* unlock the main flash */
    fmc_unlock();

    /* reset the WSEN bit in register FMC_WSEN */
    FMC_WSEN &= ~FMC_WSEN_WSEN;

    /* lock the main flash after operation */
    fmc_lock();
}

/*!
    \brief      erase page
    \param[in]  page_address: target page start address
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum fmc_page_erase(uint32_t page_address)
{
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
  
    if(FMC_READY == fmc_state){ 
        /* start page erase */
        FMC_CTL |= FMC_CTL_PER;
        FMC_ADDR = page_address;
        FMC_CTL |= FMC_CTL_START;

        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
    
        /* reset the PER bit */
        FMC_CTL &= ~FMC_CTL_PER;
    }
    
    /* return the FMC state  */
    return fmc_state;
}

/*!
    \brief      erase whole chip
    \param[in]  none
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum fmc_mass_erase(void)
{
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
  
    if(FMC_READY == fmc_state){ 
        /* start chip erase */
        FMC_CTL |= FMC_CTL_MER; 
        FMC_CTL |= FMC_CTL_START;
    
        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);

        /* reset the MER bit */
        FMC_CTL &= ~FMC_CTL_MER;
    }
    
    /* return the fmc state  */
    return fmc_state;
}

/*!
    \brief      program a word at the corresponding address
    \param[in]  address: address to program
    \param[in]  data: word to program
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum fmc_word_program(uint32_t address, uint32_t data)
{
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
  
    if(FMC_READY == fmc_state){ 
        /* set the PG bit to start program */
        FMC_CTL |= FMC_CTL_PG; 
  
        REG32(address) = data;

        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
    
        /* reset the PG bit */
        FMC_CTL &= ~FMC_CTL_PG; 
    } 
  
    /* return the FMC state */
    return fmc_state;
}

/*!
    \brief      program a half word at the corresponding address
    \param[in]  address: address to program
    \param[in]  data: word to program
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum fmc_halfword_program(uint32_t address, uint16_t data)
{
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
  
    if(FMC_READY == fmc_state){ 
        /* set the PG bit to start program */
        FMC_CTL |= FMC_CTL_PG; 
  
        REG16(address) = data;

        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
    
        /* reset the PG bit */
        FMC_CTL &= ~FMC_CTL_PG; 
    } 
  
    /* return the FMC state */
    return fmc_state;
}

#ifdef GD32F170_190
/*!
    \brief      program a word at the corresponding address without erasing
    \param[in]  address: address to program
    \param[in]  data: word to program
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum fmc_word_reprogram(uint32_t address, uint32_t data)
{
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
    FMC_WSEN |= FMC_WSEN_BPEN;

    if(FMC_READY == fmc_state){
        /* set the PG bit to start program */
        FMC_CTL |= FMC_CTL_PG;

        REG32(address) = data;

        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
    
        /* reset the PG bit */
        FMC_CTL &= ~FMC_CTL_PG;
    }
  
    /* return the FMC state */
    return fmc_state;
}
#endif /* GD32F170_190 */

/* FMC option bytes programming functions */

/*!
    \brief      unlock the option byte operation
                it is better to used in pairs with ob_lock
    \param[in]  none
    \param[out] none
    \retval     none
*/
void ob_unlock(void)
{
    if(RESET == (FMC_CTL & FMC_CTL_OBWEN)){
        /* write the FMC key */
        FMC_OBKEY = UNLOCK_KEY0;
        FMC_OBKEY = UNLOCK_KEY1;
    }
}

/*!
    \brief      lock the option byte operation
                it is better to used in pairs with ob_unlock after an operation
    \param[in]  none
    \param[out] none
    \retval     none
*/
void ob_lock(void)
{
    /* reset the OBWE bit */
    FMC_CTL &= ~FMC_CTL_OBWEN;
}

/*!
    \brief      reload the option byte and generate a system reset
    \param[in]  none
    \param[out] none
    \retval     none
*/
void ob_reset(void)
{
    /* set the OBRLD bit */
    FMC_CTL |= FMC_CTL_OBRLD;
}

/*!
    \brief      erase the option byte
                programmer must ensure FMC & option byte are both unlocked before calling this function
    \param[in]  none
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum ob_erase(void)
{
    uint16_t fmc_spc;
    uint32_t fmc_plevel = ob_obstat_plevel_get();
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);

    /* get the original option byte security protection code */
    if(OB_OBSTAT_PLEVEL_NO == fmc_plevel){
        fmc_spc = FMC_NSPC;
    }else if(OB_OBSTAT_PLEVEL_LOW == fmc_plevel){
        fmc_spc = FMC_LSPC;
    }else{
        fmc_spc   = FMC_HSPC;
        fmc_state = FMC_OB_HSPC;
    }

    if(FMC_READY == fmc_state){
        /* start erase the option byte */
        FMC_CTL |= FMC_CTL_OBER;
        FMC_CTL |= FMC_CTL_START;

        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
    
        if(FMC_READY == fmc_state){
            /* reset the OBER bit */
            FMC_CTL &= ~FMC_CTL_OBER;
       
            /* set the OBPG bit */
            FMC_CTL |= FMC_CTL_OBPG;

            /* restore the last get option byte security protection code */
            OB_SPC = fmc_spc;

            /* wait for the FMC ready */
            fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
 
            if(FMC_TOERR != fmc_state){
                /* reset the OBPG bit */
                FMC_CTL &= ~FMC_CTL_OBPG;
            }
        }else{
            if(FMC_TOERR != fmc_state){
                /* reset the OBPG bit */
                FMC_CTL &= ~FMC_CTL_OBPG;
            }
        }  
    }
    /* return the FMC state */
    return fmc_state;
}

/*!
    \brief      enable option byte write protection (OB_WP)
    \param[in]  ob_wp: write protection configuration data
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum ob_write_protection_enable(uint32_t ob_wp)
{
    uint16_t ob_wrp0, ob_wrp1;

    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);

    ob_wp   = (uint32_t)(~ob_wp);
    ob_wrp0 = (uint16_t)(ob_wp & OB_LWP);
    ob_wrp1 = (uint16_t)((ob_wp & OB_HWP) >> 8);

    if(FMC_READY == fmc_state){
        /* set the OBPG bit*/
        FMC_CTL |= FMC_CTL_OBPG;

        if(0xFFU != ob_wrp0){
            OB_WP0 = ob_wrp0;
    
            /* wait for the FMC ready */
            fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
        }
        if((FMC_READY == fmc_state) && (0xFFU != ob_wrp1)){
            OB_WP1 = ob_wrp1;
      
            /* wait for the FMC ready */
            fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
        }
        if(FMC_TOERR != fmc_state){
            /* reset the OBPG bit */
            FMC_CTL &= ~FMC_CTL_OBPG;
        }
    } 
    /* return the FMC state */
    return fmc_state;
}

/*!
    \brief      configure security protection
    \param[in]  ob_spc: specify security protection code
      \arg        FMC_NSPC: no security protection
      \arg        FMC_LSPC: low security protection
      \arg        FMC_HSPC: high security protection
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum ob_security_protection_config(uint8_t ob_spc)
{
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);

    /* the OB_SPC byte cannot be reprogrammed if protection level is high */
    if(OB_OBSTAT_PLEVEL_HIGH == ob_obstat_plevel_get()){
        fmc_state = FMC_OB_HSPC;
    }

    if(FMC_READY == fmc_state){
        /* start erase the option byte */
        FMC_CTL |= FMC_CTL_OBER;
        FMC_CTL |= FMC_CTL_START;
    
        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
    
        if(FMC_READY == fmc_state){
        
            /* reset the OBER bit */
            FMC_CTL &= ~FMC_CTL_OBER;
      
            /* enable the option bytes programming */
            FMC_CTL |= FMC_CTL_OBPG;
       
            OB_SPC = ob_spc;

            /* wait for the FMC ready */
            fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT); 
    
            if(FMC_TOERR != fmc_state){
                /* reset the OBPG bit */
                FMC_CTL &= ~FMC_CTL_OBPG;
            }
        }else{
            if(FMC_TOERR != fmc_state){
                /* reset the OBER bit */
                FMC_CTL &= ~FMC_CTL_OBER;
            }
        }
    }
    /* return the FMC state */
    return fmc_state;
}

/*!
    \brief      program the FMC user option byte
    \param[in]  ob_user: user option byte
      \arg        OB_FWDGT_SW: software free watchdog timer
      \arg        OB_FWDGT_HW: hardware free watchdog timer
      \arg        OB_DEEPSLEEP_NRST: generate a reset instead of entering deepsleep mode
      \arg        OB_DEEPSLEEP_RST: no reset when entering deepsleep mode
      \arg        OB_STDBY_NRST: generate a reset instead of entering standby mode
      \arg        OB_STDBY_RST: no reset when entering deepsleep mode
      \arg        OB_BOOT1_SET_1: BOOT1 bit is 1
      \arg        OB_BOOT1_SET_0: BOOT1 bit is 0
      \arg        OB_VDDA_DISABLE: disable VDDA monitor
      \arg        OB_VDDA_ENABLE: enable VDDA monitor
      \arg        OB_SRAM_PARITY_DISABLE: disable sram parity check
      \arg        OB_SRAM_PARITY_ENABLE: enable sram parity check
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum ob_user_write(uint8_t ob_user)
{
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);

    if(FMC_READY == fmc_state){
        /* set the OBPG bit */
        FMC_CTL |= FMC_CTL_OBPG; 

        OB_USER = (uint8_t)(ob_user | OB_USER_MASK);
  
        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);

        if(FMC_TOERR != fmc_state){
            /* reset the OBPG bit */
            FMC_CTL &= ~FMC_CTL_OBPG;
        }
    }
    /* return the FMC state */
    return fmc_state;
}

/*!
    \brief      program the FMC data option byte
    \param[in]  address: OB_DATA_ADDR0 or OB_DATA_ADDR1
      \arg        OB_DATA_ADDR0: option byte data address 0
      \arg        OB_DATA_ADDR1: option byte data address 1
    \param[in]  data: the byte to be programmed
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum ob_data_program(uint32_t address, uint8_t data)
{
    fmc_state_enum fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);

    if(FMC_READY == fmc_state){
        /* set the OBPG bit */
        FMC_CTL |= FMC_CTL_OBPG; 
        REG16(address) = data;
    
        /* wait for the FMC ready */
        fmc_state = fmc_ready_wait(FMC_TIMEOUT_COUNT);
    
        if(FMC_TOERR != fmc_state){
            /* reset the OBPG bit */
            FMC_CTL &= ~FMC_CTL_OBPG;
        }
    }
    /* return the FMC state */
    return fmc_state;
}

/*!
    \brief      get OB_USER in register FMC_OBSTAT
    \param[in]  none
    \param[out] none
    \retval     ob_user
*/
uint8_t ob_user_get(void)
{
    return (uint8_t)(FMC_OBSTAT >> 8);
}

/*!
    \brief      get OB_DATA in register FMC_OBSTAT
    \param[in]  none
    \param[out] none
    \retval     ob_data
*/
uint16_t ob_data_get(void)
{
    return (uint16_t)(FMC_OBSTAT >> 16);
}

/*!
    \brief      get the FMC option byte write protection (OB_WP) in register FMC_WP
    \param[in]  none
    \param[out] none
    \retval     OB_WP
*/
uint16_t ob_write_protection_get(void)
{
    return (uint16_t)(FMC_WP);
}

/*!
    \brief      get the value of FMC option byte security protection level (PLEVEL) in FMC_OBSTAT register
    \param[in]  none
    \param[out] none
    \retval     the value of PLEVEL
*/
uint32_t ob_obstat_plevel_get(void)
{
    return (FMC_OBSTAT & (FMC_OBSTAT_PLVL_BIT0 | FMC_OBSTAT_PLVL_BIT1));
}

/* FMC interrupts and flags management functions */
/*!
    \brief      enable FMC interrupt
    \param[in]  interrupt: the FMC interrupt source
      \arg        FMC_INTEN_END: FMC end of operation interrupt
      \arg        FMC_INTEN_ERR: FMC error interrupt
    \param[out] none
    \retval     none
*/
void fmc_interrupt_enable(uint32_t interrupt)
{
    FMC_CTL |= interrupt;
}

/*!
    \brief      disable FMC interrupt
    \param[in]  interrupt: the FMC interrupt source
      \arg        FMC_INTEN_END: FMC end of operation interrupt
      \arg        FMC_INTEN_ERR: FMC error interrupt
    \param[out] none
    \retval     none
*/
void fmc_interrupt_disable(uint32_t interrupt)
{
    FMC_CTL &= ~(uint32_t)interrupt;
}

/*!
    \brief      get flag set or reset
    \param[in]  flag: check FMC flag
      \arg        FMC_FLAG_BUSY: FMC busy flag
      \arg        FMC_FLAG_PGERR: FMC programming error flag
      \arg        FMC_FLAG_WPERR: FMC write protection error flag
      \arg        FMC_FLAG_END: FMC end of programming flag
    \param[out] none
    \retval     FlagStatus: SET or RESET
*/
FlagStatus fmc_flag_get(uint32_t flag)
{
    FlagStatus status = RESET;

    if(FMC_STAT & flag){
        status = SET;
    }
    /* return the state of corresponding FMC flag */
    return status; 
}

/*!
    \brief      clear the FMC pending flag by writing 1
    \param[in]  flag: clear FMC flag
      \arg        FMC_FLAG_PGERR: FMC programming error flag
      \arg        FMC_FLAG_WPERR: FMC write protection error flag
      \arg        FMC_FLAG_END: fmc end of programming flag
    \param[out] none
    \retval     none
*/
void fmc_flag_clear(uint32_t flag)
{
    /* clear the flags */
    FMC_STAT = flag;
}

/*!
    \brief      get the FMC state
    \param[in]  none
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum fmc_state_get(void)
{
    fmc_state_enum fmc_state = FMC_READY;
  
    if((uint32_t)0x00U != (FMC_STAT & FMC_STAT_BUSY)){
        fmc_state = FMC_BUSY;
    }else{
        if((uint32_t)0x00U != (FMC_STAT & FMC_STAT_WPERR)){
            fmc_state = FMC_WPERR;
        }else{
            if((uint32_t)0x00U != (FMC_STAT & FMC_STAT_PGERR)){
                fmc_state = FMC_PGERR; 
            }
        }
    }
    /* return the FMC state */
    return fmc_state;
}

/*!
    \brief      check whether FMC is ready or not
    \param[in]  timeout: timeout count
    \param[out] none
    \retval     fmc_state
*/
fmc_state_enum fmc_ready_wait(uint32_t timeout)
{
    fmc_state_enum fmc_state = FMC_BUSY;
  
    /* wait for FMC ready */
    do{
        /* get FMC state */
        fmc_state = fmc_state_get();
        timeout--;
    }while((FMC_BUSY == fmc_state) && (0U != timeout));
  
    if(FMC_BUSY == fmc_state){
        fmc_state = FMC_TOERR;
    }
    /* return the FMC state */
    return fmc_state;
}