Raphael Kwon
BSD style socket API for W5500.
Dependents: W5500_Porting_WIZnetLib W5500_Porting_WIZnetLib W5500_Porting_WIZnetLib_LPC800
Fork of
Ethernet
by 
Raphael Kwon
wizchip_conf.c
- Committer:
- xeon011
- Date:
- 2014-02-18
- Revision:
- 2:ee0f7508fb5c
- Parent:
- 0:9158fe13dc14
File content as of revision 2:ee0f7508fb5c:
//****************************************************************************/
//!
//! \file wizchip_conf.c
//! \brief WIZCHIP Config Header File.
//! \version 1.0.0
//! \date 2013/10/01
//! \par Revision history
//! <2013/10/01> 1st Release
//! \author MidnightCow
//! \copyright
//!
//! Copyright (c) 2013, WIZnet Co., LTD.
//! All rights reserved.
//!
//! Redistribution and use in source and binary forms, with or without
//! modification, are permitted provided that the following conditions
//! are met:
//!
//! * Redistributions of source code must retain the above copyright
//! notice, this list of conditions and the following disclaimer.
//! * Redistributions in binary form must reproduce the above copyright
//! notice, this list of conditions and the following disclaimer in the
//! documentation and/or other materials provided with the distribution.
//! * Neither the name of the <ORGANIZATION> nor the names of its
//! contributors may be used to endorse or promote products derived
//! from this software without specific prior written permission.
//!
//! THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
//! AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
//! IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
//! ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
//! LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
//! CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
//! SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
//! INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
//! CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
//! ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
//! THE POSSIBILITY OF SUCH DAMAGE.
//
//*****************************************************************************/
#include "wizchip_conf.h"
/**
* @brief Default function to enable interrupt.
* @note This function help not to access wrong address. If you do not describe this function or register any functions,
* null function is called.
*/
void wizchip_cris_enter(void) {};
/**
* @brief Default function to disable interrupt.
* @note This function help not to access wrong address. If you do not describe this function or register any functions,
* null function is called.
*/
void wizchip_cris_exit(void) {};
/**
* @brief Default function to select chip.
* @note This function help not to access wrong address. If you do not describe this function or register any functions,
* null function is called.
*/
void wizchip_cs_select(void) {};
/**
* @brief Default function to deselect chip.
* @note This function help not to access wrong address. If you do not describe this function or register any functions,
* null function is called.
*/
void wizchip_cs_deselect(void) {};
/**
* @brief Default function to read in direct or indirect interface.
* @note This function help not to access wrong address. If you do not describe this function or register any functions,
* null function is called.
*/
uint8_t wizchip_bus_readbyte(uint32_t AddrSel) { return * ((volatile uint8_t *) AddrSel); };
/**
* @brief Default function to write in direct or indirect interface.
* @note This function help not to access wrong address. If you do not describe this function or register any functions,
* null function is called.
*/
void wizchip_bus_writebyte(uint32_t AddrSel, uint8_t wb) { *((volatile uint8_t*)AddrSel) = wb; };
/**
* @brief Default function to read in SPI interface.
* @note This function help not to access wrong address. If you do not describe this function or register any functions,
* null function is called.
*/
uint8_t wizchip_spi_readbyte(void) {return 0;};
/**
* @brief Default function to write in SPI interface.
* @note This function help not to access wrong address. If you do not describe this function or register any functions,
* null function is called.
*/
void wizchip_spi_writebyte(uint8_t wb) {};
/**
* @\ref _WIZCHIP instance
*/
_WIZCHIP WIZCHIP =
{
.id = _WIZCHIP_ID_,
.if_mode = _WIZCHIP_IO_MODE_,
.CRIS._enter = wizchip_cris_enter,
.CRIS._exit = wizchip_cris_exit,
.CS._select = wizchip_cs_select,
.CS._deselect = wizchip_cs_deselect,
.IF.BUS._read_byte = wizchip_bus_readbyte,
.IF.BUS._write_byte = wizchip_bus_writebyte
// .IF.SPI._read_byte = wizchip_spi_readbyte,
// .IF.SPI._write_byte = wizchip_spi_writebyte
};
static uint8_t _DNS_[4]; // DNS server ip address
static dhcp_mode _DHCP_; // DHCP mode
void reg_wizchip_cris_cbfunc(void(*cris_en)(void), void(*cris_ex)(void))
{
if(!cris_en || !cris_ex)
{
WIZCHIP.CRIS._enter = wizchip_cris_enter;
WIZCHIP.CRIS._exit = wizchip_cris_exit;
}
else
{
WIZCHIP.CRIS._enter = cris_en;
WIZCHIP.CRIS._exit = cris_ex;
}
}
void reg_wizchip_cs_cbfunc(void(*cs_sel)(void), void(*cs_desel)(void))
{
if(!cs_sel || !cs_desel)
{
WIZCHIP.CS._select = wizchip_cs_select;
WIZCHIP.CS._deselect = wizchip_cs_deselect;
}
else
{
WIZCHIP.CS._select = cs_sel;
WIZCHIP.CS._deselect = cs_desel;
}
}
void reg_wizchip_bus_cbfunc(uint8_t(*bus_rb)(uint32_t addr), void (*bus_wb)(uint32_t addr, uint8_t wb))
{
while(!(WIZCHIP.if_mode & _WIZCHIP_IO_MODE_BUS_));
if(!bus_rb || !bus_wb)
{
WIZCHIP.IF.BUS._read_byte = wizchip_bus_readbyte;
WIZCHIP.IF.BUS._write_byte = wizchip_bus_writebyte;
}
else
{
WIZCHIP.IF.BUS._read_byte = bus_rb;
WIZCHIP.IF.BUS._write_byte = bus_wb;
}
}
void reg_wizchip_spi_cbfunc(uint8_t (*spi_rb)(void), void (*spi_wb)(uint8_t wb))
{
while(!(WIZCHIP.if_mode & _WIZCHIP_IO_MODE_SPI_));
if(!spi_rb || !spi_wb)
{
WIZCHIP.IF.SPI._read_byte = wizchip_spi_readbyte;
WIZCHIP.IF.SPI._write_byte = wizchip_spi_writebyte;
}
else
{
WIZCHIP.IF.SPI._read_byte = spi_rb;
WIZCHIP.IF.SPI._write_byte = spi_wb;
}
}
int8_t ctlwizchip(ctlwizchip_type cwtype, void* arg)
{
uint8_t tmp = 0;
uint8_t* ptmp[2] = {0,0};
switch(cwtype)
{
case CW_RESET_WIZCHIP:
wizchip_sw_reset();
break;
case CW_INIT_WIZCHIP:
if(arg != 0)
{
ptmp[0] = (uint8_t*)arg;
ptmp[1] = ptmp[0] + _WIZCHIP_SOCK_NUM_;
}
return wizchip_init(ptmp[0], ptmp[1]);
case CW_CLR_INTERRUPT:
wizchip_clrinterrupt(*((intr_kind*)arg));
break;
case CW_GET_INTERRUPT:
*((intr_kind*)arg) = wizchip_getinterrupt();
break;
case CW_SET_INTRMASK:
wizchip_setinterruptmask(*((intr_kind*)arg));
break;
case CW_GET_INTRMASK:
*((intr_kind*)arg) = wizchip_getinterruptmask();
break;
#if _WIZCHIP_ > 5100
case CW_SET_INTRTIME:
setINTLEVEL(*(uint16_t*)arg);
break;
case CW_GET_INTRTIME:
*(uint16_t*)arg = getINTLEVEL();
break;
#endif
case CW_GET_ID:
((uint8_t*)arg)[0] = WIZCHIP.id[0];
((uint8_t*)arg)[1] = WIZCHIP.id[1];
((uint8_t*)arg)[2] = WIZCHIP.id[2];
((uint8_t*)arg)[3] = WIZCHIP.id[3];
((uint8_t*)arg)[4] = WIZCHIP.id[4];
((uint8_t*)arg)[5] = 0;
break;
#if _WIZCHIP_ == 5500
case CW_RESET_PHY:
wizphy_reset();
break;
case CW_SET_PHYCONF:
wizphy_setphyconf((wiz_PhyConf*)arg);
break;
case CW_GET_PHYCONF:
wizphy_getphyconf((wiz_PhyConf*)arg);
break;
case CW_GET_PHYSTATUS:
break;
case CW_SET_PHYPOWMODE:
return wizphy_setphypmode(*(uint8_t*)arg);
#endif
case CW_GET_PHYPOWMODE:
tmp = wizphy_getphypmode();
if((int8_t)tmp == -1) return -1;
*(uint8_t*)arg = tmp;
break;
case CW_GET_PHYLINK:
tmp = wizphy_getphylink();
if((int8_t)tmp == -1) return -1;
*(uint8_t*)arg = tmp;
break;
default:
return -1;
}
return 0;
}
int8_t ctlnetwork(ctlnetwork_type cntype, void* arg)
{
switch(cntype)
{
case CN_SET_NETINFO:
wizchip_setnetinfo((wiz_NetInfo*)arg);
break;
case CN_GET_NETINFO:
wizchip_getnetinfo((wiz_NetInfo*)arg);
break;
case CN_SET_NETMODE:
return wizchip_setnetmode(*(netmode_type*)arg);
case CN_GET_NETMODE:
*(netmode_type*)arg = wizchip_getnetmode();
break;
case CN_SET_TIMEOUT:
wizchip_settimeout((wiz_NetTimeout*)arg);
break;
case CN_GET_TIMEOUT:
wizchip_gettimeout((wiz_NetTimeout*)arg);
break;
default:
return -1;
}
return 0;
}
void wizchip_sw_reset(void)
{
uint8_t gw[4], sn[4], sip[4];
uint8_t mac[6];
getSHAR(mac);
getGAR(gw); getSUBR(sn); getSIPR(sip);
setMR(MR_RST);
getMR(); // for delay
setSHAR(mac);
setGAR(gw);
setSUBR(sn);
setSIPR(sip);
}
int8_t wizchip_init(uint8_t* txsize, uint8_t* rxsize)
{
int8_t i;
int8_t tmp = 0;
wizchip_sw_reset();
if(txsize)
{
tmp = 0;
for(i = 0 ; i < _WIZCHIP_SOCK_NUM_; i++)
tmp += txsize[i];
if(tmp > 16) return -1;
for(i = 0 ; i < _WIZCHIP_SOCK_NUM_; i++)
setSn_TXBUF_SIZE(i, txsize[i]);
}
if(rxsize)
{
tmp = 0;
for(i = 0 ; i < _WIZCHIP_SOCK_NUM_; i++)
tmp += rxsize[i];
if(tmp > 16) return -1;
for(i = 0 ; i < _WIZCHIP_SOCK_NUM_; i++)
setSn_RXBUF_SIZE(i, rxsize[i]);
}
return 0;
}
void wizchip_clrinterrupt(intr_kind intr)
{
uint8_t ir = (uint8_t)intr;
uint8_t sir = (uint8_t)((uint16_t)intr >> 8);
#if _WIZCHIP_ < 5500
ir |= (1<<4); // IK_WOL
#endif
#if _WIZCHIP_ == 5200
ir |= (1 << 6);
#endif
#if _WIZCHIP_ < 5200
sir &= 0x0F;
#endif
#if _WIZCHIP_ == 5100
ir |= sir;
setIR(ir);
#else
setIR(ir);
setSIR(sir);
#endif
}
intr_kind wizchip_getinterrupt(void)
{
uint8_t ir = 0;
uint8_t sir = 0;
uint16_t ret = 0;
#if _WIZCHIP_ == 5100
ir = getIR();
sir = ir 0x0F;
#else
ir = getIR();
sir = getSIR();
#endif
#if _WIZCHIP_ < 5500
ir &= ~(1<<4); // IK_WOL
#endif
#if _WIZCHIP_ == 5200
ir &= ~(1 << 6);
#endif
ret = sir;
ret = (ret << 8) + ir;
return (intr_kind)ret;
}
void wizchip_setinterruptmask(intr_kind intr)
{
uint8_t imr = (uint8_t)intr;
uint8_t simr = (uint8_t)((uint16_t)intr >> 8);
#if _WIZCHIP_ < 5500
imr &= ~(1<<4); // IK_WOL
#endif
#if _WIZCHIP_ == 5200
imr &= ~(1 << 6);
#endif
#if _WIZCHIP_ < 5200
simr &= 0x0F;
#endif
#if _WIZCHIP_ == 5100
imr |= simr;
setIMR(imr);
#else
setIMR(imr);
setSIMR(simr);
#endif
}
intr_kind wizchip_getinterruptmask(void)
{
uint8_t imr = 0;
uint8_t simr = 0;
uint16_t ret = 0;
#if _WIZCHIP_ == 5100
imr = getIMR();
simr = imr 0x0F;
#else
imr = getIMR();
simr = getSIMR();
#endif
#if _WIZCHIP_ < 5500
imr &= ~(1<<4); // IK_WOL
#endif
#if _WIZCHIP_ == 5200
imr &= ~(1 << 6); // IK_DEST_UNREACH
#endif
ret = simr;
ret = (ret << 8) + imr;
return (intr_kind)ret;
}
int8_t wizphy_getphylink(void)
{
int8_t tmp;
#if _WIZCHIP_ == 5200
if(getPHYSTATUS() & PHYSTATUS_LINK)
tmp = PHY_LINK_ON;
else
tmp = PHY_LINK_OFF;
#elif _WIZCHIP_ == 5500
if(getPHYCFGR() & PHYCFGR_LNK_ON)
tmp = PHY_LINK_ON;
else
tmp = PHY_LINK_OFF;
#else
tmp = -1;
#endif
return tmp;
}
#if _WIZCHIP_ > 5100
int8_t wizphy_getphypmode(void)
{
int8_t tmp = 0;
#if _WIZCHIP_ == 5200
if(getPHYSTATUS() & PHYSTATUS_POWERDOWN)
tmp = PHY_POWER_DOWN;
else
tmp = PHY_POWER_NORM;
#elif _WIZCHIP_ == 5500
if(getPHYCFGR() & PHYCFGR_OPMDC_PDOWN)
tmp = PHY_POWER_DOWN;
else
tmp = PHY_POWER_NORM;
#else
tmp = -1;
#endif
return tmp;
}
#endif
#if _WIZCHIP_ == 5500
void wizphy_reset(void)
{
uint8_t tmp = getPHYCFGR();
tmp &= PHYCFGR_RST;
setPHYCFGR(tmp);
tmp = getPHYCFGR();
tmp |= ~PHYCFGR_RST;
setPHYCFGR(tmp);
}
void wizphy_setphyconf(wiz_PhyConf* phyconf)
{
uint8_t tmp = 0;
if(phyconf->by == PHY_CONFBY_SW)
tmp |= PHYCFGR_OPMD;
else
tmp &= ~PHYCFGR_OPMD;
if(phyconf->mode == PHY_MODE_AUTONEGO)
tmp |= PHYCFGR_OPMDC_ALLA;
else
{
if(phyconf->duplex == PHY_DUPLEX_FULL)
{
if(phyconf->speed == PHY_SPEED_100)
tmp |= PHYCFGR_OPMDC_100F;
else
tmp |= PHYCFGR_OPMDC_10F;
}
else
{
if(phyconf->speed == PHY_SPEED_100)
tmp |= PHYCFGR_OPMDC_100H;
else
tmp |= PHYCFGR_OPMDC_10H;
}
}
setPHYCFGR(tmp);
wizphy_reset();
}
void wizphy_getphyconf(wiz_PhyConf* phyconf)
{
uint8_t tmp = 0;
tmp = getPHYCFGR();
phyconf->by = (tmp & PHYCFGR_OPMD) ? PHY_CONFBY_SW : PHY_CONFBY_HW;
switch(tmp & PHYCFGR_OPMDC_ALLA)
{
case PHYCFGR_OPMDC_ALLA:
case PHYCFGR_OPMDC_100FA:
phyconf->mode = PHY_MODE_AUTONEGO;
break;
default:
phyconf->mode = PHY_MODE_MANUAL;
break;
}
switch(tmp & PHYCFGR_OPMDC_ALLA)
{
case PHYCFGR_OPMDC_100FA:
case PHYCFGR_OPMDC_100F:
case PHYCFGR_OPMDC_100H:
phyconf->speed = PHY_SPEED_100;
break;
default:
phyconf->speed = PHY_SPEED_10;
break;
}
switch(tmp & PHYCFGR_OPMDC_ALLA)
{
case PHYCFGR_OPMDC_100FA:
case PHYCFGR_OPMDC_100F:
case PHYCFGR_OPMDC_10F:
phyconf->duplex = PHY_DUPLEX_FULL;
break;
default:
phyconf->duplex = PHY_DUPLEX_HALF;
break;
}
}
void wizphy_getphystat(wiz_PhyConf* phyconf)
{
uint8_t tmp = getPHYCFGR();
phyconf->duplex = (tmp & PHYCFGR_DPX_FULL) ? PHY_DUPLEX_FULL : PHY_DUPLEX_HALF;
phyconf->speed = (tmp & PHYCFGR_SPD_100) ? PHY_SPEED_100 : PHY_SPEED_10;
}
int8_t wizphy_setphypmode(uint8_t pmode)
{
uint8_t tmp = 0;
tmp = getPHYCFGR();
if((tmp & PHYCFGR_OPMD)== 0) return -1;
tmp &= ~PHYCFGR_OPMDC_ALLA;
if( pmode == PHY_POWER_DOWN)
tmp |= PHYCFGR_OPMDC_PDOWN;
else
tmp |= PHYCFGR_OPMDC_ALLA;
setPHYCFGR(tmp);
wizphy_reset();
tmp = getPHYCFGR();
if( pmode == PHY_POWER_DOWN)
{
if(tmp & PHYCFGR_OPMDC_PDOWN) return 0;
}
else
{
if(tmp & PHYCFGR_OPMDC_ALLA) return 0;
}
return -1;
}
#endif
void wizchip_setnetinfo(wiz_NetInfo* pnetinfo)
{
setSHAR(pnetinfo->mac);
setGAR(pnetinfo->gw);
setSUBR(pnetinfo->sn);
setSIPR(pnetinfo->ip);
_DNS_[0] = pnetinfo->dns[0];
_DNS_[1] = pnetinfo->dns[1];
_DNS_[2] = pnetinfo->dns[2];
_DNS_[3] = pnetinfo->dns[3];
_DHCP_ = pnetinfo->dhcp;
}
void wizchip_getnetinfo(wiz_NetInfo* pnetinfo)
{
getSHAR(pnetinfo->mac);
getGAR(pnetinfo->gw);
getSUBR(pnetinfo->sn);
getSIPR(pnetinfo->ip);
pnetinfo->dns[0]= _DNS_[0];
pnetinfo->dns[1]= _DNS_[1];
pnetinfo->dns[2]= _DNS_[2];
pnetinfo->dns[3]= _DNS_[3];
pnetinfo->dhcp = _DHCP_;
}
int8_t wizchip_setnetmode(netmode_type netmode)
{
uint8_t tmp = 0;
#if _WIZCHIP_ != 5500
if(netmode & ~(NM_WAKEONLAN | NM_PPPOE | NM_PINGBLOCK)) return -1;
#else
if(netmode & ~(NM_WAKEONLAN | NM_PPPOE | NM_PINGBLOCK | NM_FORCEARP)) return -1;
#endif
tmp = getMR();
tmp |= (uint8_t)netmode;
setMR(tmp);
return 0;
}
netmode_type wizchip_getnetmode(void)
{
return (netmode_type) getMR();
}
void wizchip_settimeout(wiz_NetTimeout* nettime)
{
setRCR(nettime->retry_cnt);
setRTR(nettime->time_100us);
}
void wizchip_gettimeout(wiz_NetTimeout* nettime)
{
nettime->retry_cnt = getRCR();
nettime->time_100us = getRTR();
}