/* * Copyright (C) 2013 Realtek Semiconductor Corp. * All Rights Reserved. * * Unless you and Realtek execute a separate written software license * agreement governing use of this software, this software is licensed * to you under the terms of the GNU General Public License version 2, * available at https://www.gnu.org/licenses/old-licenses/gpl-2.0.txt * * $Revision: 76306 $ * $Date: 2017-03-08 15:13:58 +0800 (閫变笁, 08 涓夋湀 2017) $ * * Purpose : RTL8367C switch high-level API for RTL8367C * Feature : LUT related functions * */ #include #include static void _rtl8367c_fdbStUser2Smi( rtl8367c_luttb *pLutSt, rtk_uint16 *pFdbSmi) { /* L3 lookup */ if(pLutSt->l3lookup) { if(pLutSt->l3vidlookup) { pFdbSmi[0] = (pLutSt->sip & 0x0000FFFF); pFdbSmi[1] = (pLutSt->sip & 0xFFFF0000) >> 16; pFdbSmi[2] = (pLutSt->dip & 0x0000FFFF); pFdbSmi[3] = (pLutSt->dip & 0x0FFF0000) >> 16; pFdbSmi[3] |= (pLutSt->l3lookup & 0x0001) << 12; pFdbSmi[3] |= (pLutSt->l3vidlookup & 0x0001) << 13; pFdbSmi[3] |= ((pLutSt->mbr & 0x0300) >> 8) << 14; pFdbSmi[4] |= (pLutSt->mbr & 0x00FF); pFdbSmi[4] |= (pLutSt->l3_vid & 0x00FF) << 8; pFdbSmi[5] |= ((pLutSt->l3_vid & 0x0F00) >> 8); pFdbSmi[5] |= (pLutSt->nosalearn & 0x0001) << 5; pFdbSmi[5] |= ((pLutSt->mbr & 0x0400) >> 10) << 7; } else { pFdbSmi[0] = (pLutSt->sip & 0x0000FFFF); pFdbSmi[1] = (pLutSt->sip & 0xFFFF0000) >> 16; pFdbSmi[2] = (pLutSt->dip & 0x0000FFFF); pFdbSmi[3] = (pLutSt->dip & 0x0FFF0000) >> 16; pFdbSmi[3] |= (pLutSt->l3lookup & 0x0001) << 12; pFdbSmi[3] |= (pLutSt->l3vidlookup & 0x0001) << 13; pFdbSmi[3] |= ((pLutSt->mbr & 0x0300) >> 8) << 14; pFdbSmi[4] |= (pLutSt->mbr & 0x00FF); pFdbSmi[4] |= (pLutSt->igmpidx & 0x00FF) << 8; pFdbSmi[5] |= (pLutSt->igmp_asic & 0x0001); pFdbSmi[5] |= (pLutSt->lut_pri & 0x0007) << 1; pFdbSmi[5] |= (pLutSt->fwd_en & 0x0001) << 4; pFdbSmi[5] |= (pLutSt->nosalearn & 0x0001) << 5; pFdbSmi[5] |= ((pLutSt->mbr & 0x0400) >> 10) << 7; } } else if(pLutSt->mac.octet[0] & 0x01) /*Multicast L2 Lookup*/ { pFdbSmi[0] |= pLutSt->mac.octet[5]; pFdbSmi[0] |= pLutSt->mac.octet[4] << 8; pFdbSmi[1] |= pLutSt->mac.octet[3]; pFdbSmi[1] |= pLutSt->mac.octet[2] << 8; pFdbSmi[2] |= pLutSt->mac.octet[1]; pFdbSmi[2] |= pLutSt->mac.octet[0] << 8; pFdbSmi[3] |= pLutSt->cvid_fid; pFdbSmi[3] |= (pLutSt->l3lookup & 0x0001) << 12; pFdbSmi[3] |= (pLutSt->ivl_svl & 0x0001) << 13; pFdbSmi[3] |= ((pLutSt->mbr & 0x0300) >> 8) << 14; pFdbSmi[4] |= (pLutSt->mbr & 0x00FF); pFdbSmi[4] |= (pLutSt->igmpidx & 0x00FF) << 8; pFdbSmi[5] |= pLutSt->igmp_asic; pFdbSmi[5] |= (pLutSt->lut_pri & 0x0007) << 1; pFdbSmi[5] |= (pLutSt->fwd_en & 0x0001) << 4; pFdbSmi[5] |= (pLutSt->nosalearn & 0x0001) << 5; pFdbSmi[5] |= ((pLutSt->mbr & 0x0400) >> 10) << 7; } else /*Asic auto-learning*/ { pFdbSmi[0] |= pLutSt->mac.octet[5]; pFdbSmi[0] |= pLutSt->mac.octet[4] << 8; pFdbSmi[1] |= pLutSt->mac.octet[3]; pFdbSmi[1] |= pLutSt->mac.octet[2] << 8; pFdbSmi[2] |= pLutSt->mac.octet[1]; pFdbSmi[2] |= pLutSt->mac.octet[0] << 8; pFdbSmi[3] |= pLutSt->cvid_fid; pFdbSmi[3] |= (pLutSt->l3lookup & 0x0001) << 12; pFdbSmi[3] |= (pLutSt->ivl_svl & 0x0001) << 13; pFdbSmi[3] |= ((pLutSt->spa & 0x0008) >> 3) << 15; pFdbSmi[4] |= pLutSt->efid; pFdbSmi[4] |= (pLutSt->fid & 0x000F) << 3; pFdbSmi[4] |= (pLutSt->sa_en & 0x0001) << 7; pFdbSmi[4] |= (pLutSt->spa & 0x0007) << 8; pFdbSmi[4] |= (pLutSt->age & 0x0007) << 11; pFdbSmi[4] |= (pLutSt->auth & 0x0001) << 14; pFdbSmi[4] |= (pLutSt->sa_block & 0x0001) << 15; pFdbSmi[5] |= pLutSt->da_block; pFdbSmi[5] |= (pLutSt->lut_pri & 0x0007) << 1; pFdbSmi[5] |= (pLutSt->fwd_en & 0x0001) << 4; pFdbSmi[5] |= (pLutSt->nosalearn & 0x0001) << 5; } } static void _rtl8367c_fdbStSmi2User( rtl8367c_luttb *pLutSt, rtk_uint16 *pFdbSmi) { /*L3 lookup*/ if(pFdbSmi[3] & 0x1000) { if(pFdbSmi[3] & 0x2000) { pLutSt->sip = pFdbSmi[0] | (pFdbSmi[1] << 16); pLutSt->dip = pFdbSmi[2] | ((pFdbSmi[3] & 0x0FFF) << 16); pLutSt->mbr = (pFdbSmi[4] & 0x00FF) | (((pFdbSmi[3] & 0xC000) >> 14) << 8) | (((pFdbSmi[5] & 0x0080) >> 7) << 10); pLutSt->l3_vid = ((pFdbSmi[4] & 0xFF00) >> 8) | (pFdbSmi[5] & 0x000F); pLutSt->l3lookup = (pFdbSmi[3] & 0x1000) >> 12; pLutSt->l3vidlookup = (pFdbSmi[3] & 0x2000) >> 13; pLutSt->nosalearn = (pFdbSmi[5] & 0x0020) >> 5; } else { pLutSt->sip = pFdbSmi[0] | (pFdbSmi[1] << 16); pLutSt->dip = pFdbSmi[2] | ((pFdbSmi[3] & 0x0FFF) << 16); pLutSt->lut_pri = (pFdbSmi[5] & 0x000E) >> 1; pLutSt->fwd_en = (pFdbSmi[5] & 0x0010) >> 4; pLutSt->mbr = (pFdbSmi[4] & 0x00FF) | (((pFdbSmi[3] & 0xC000) >> 14) << 8) | (((pFdbSmi[5] & 0x0080) >> 7) << 10); pLutSt->igmpidx = (pFdbSmi[4] & 0xFF00) >> 8; pLutSt->igmp_asic = (pFdbSmi[5] & 0x0001); pLutSt->l3lookup = (pFdbSmi[3] & 0x1000) >> 12; pLutSt->nosalearn = (pFdbSmi[5] & 0x0020) >> 5; } } else if(pFdbSmi[2] & 0x0100) /*Multicast L2 Lookup*/ { pLutSt->mac.octet[0] = (pFdbSmi[2] & 0xFF00) >> 8; pLutSt->mac.octet[1] = (pFdbSmi[2] & 0x00FF); pLutSt->mac.octet[2] = (pFdbSmi[1] & 0xFF00) >> 8; pLutSt->mac.octet[3] = (pFdbSmi[1] & 0x00FF); pLutSt->mac.octet[4] = (pFdbSmi[0] & 0xFF00) >> 8; pLutSt->mac.octet[5] = (pFdbSmi[0] & 0x00FF); pLutSt->cvid_fid = pFdbSmi[3] & 0x0FFF; pLutSt->lut_pri = (pFdbSmi[5] & 0x000E) >> 1; pLutSt->fwd_en = (pFdbSmi[5] & 0x0010) >> 4; pLutSt->mbr = (pFdbSmi[4] & 0x00FF) | (((pFdbSmi[3] & 0xC000) >> 14) << 8) | (((pFdbSmi[5] & 0x0080) >> 7) << 10); pLutSt->igmpidx = (pFdbSmi[4] & 0xFF00) >> 8; pLutSt->igmp_asic = (pFdbSmi[5] & 0x0001); pLutSt->l3lookup = (pFdbSmi[3] & 0x1000) >> 12; pLutSt->ivl_svl = (pFdbSmi[3] & 0x2000) >> 13; pLutSt->nosalearn = (pFdbSmi[5] & 0x0020) >> 5; } else /*Asic auto-learning*/ { pLutSt->mac.octet[0] = (pFdbSmi[2] & 0xFF00) >> 8; pLutSt->mac.octet[1] = (pFdbSmi[2] & 0x00FF); pLutSt->mac.octet[2] = (pFdbSmi[1] & 0xFF00) >> 8; pLutSt->mac.octet[3] = (pFdbSmi[1] & 0x00FF); pLutSt->mac.octet[4] = (pFdbSmi[0] & 0xFF00) >> 8; pLutSt->mac.octet[5] = (pFdbSmi[0] & 0x00FF); pLutSt->cvid_fid = pFdbSmi[3] & 0x0FFF; pLutSt->lut_pri = (pFdbSmi[5] & 0x000E) >> 1; pLutSt->fwd_en = (pFdbSmi[5] & 0x0010) >> 4; pLutSt->sa_en = (pFdbSmi[4] & 0x0080) >> 7; pLutSt->auth = (pFdbSmi[4] & 0x4000) >> 14; pLutSt->spa = ((pFdbSmi[4] & 0x0700) >> 8) | (((pFdbSmi[3] & 0x8000) >> 15) << 3); pLutSt->age = (pFdbSmi[4] & 0x3800) >> 11; pLutSt->fid = (pFdbSmi[4] & 0x0078) >> 3; pLutSt->efid = (pFdbSmi[4] & 0x0007); pLutSt->sa_block = (pFdbSmi[4] & 0x8000) >> 15; pLutSt->da_block = (pFdbSmi[5] & 0x0001); pLutSt->l3lookup = (pFdbSmi[3] & 0x1000) >> 12; pLutSt->ivl_svl = (pFdbSmi[3] & 0x2000) >> 13; pLutSt->nosalearn = (pFdbSmi[3] & 0x0020) >> 5; } } /* Function Name: * rtl8367c_setAsicLutIpMulticastLookup * Description: * Set LUT IP multicast lookup function * Input: * enabled - 1: enabled, 0: disabled * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_setAsicLutIpMulticastLookup(rtk_uint32 enabled) { return rtl8367c_setAsicRegBit(RTL8367C_REG_LUT_CFG, RTL8367C_LUT_IPMC_HASH_OFFSET, enabled); } /* Function Name: * rtl8367c_getAsicLutIpMulticastLookup * Description: * Get LUT IP multicast lookup function * Input: * pEnabled - 1: enabled, 0: disabled * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutIpMulticastLookup(rtk_uint32* pEnabled) { return rtl8367c_getAsicRegBit(RTL8367C_REG_LUT_CFG, RTL8367C_LUT_IPMC_HASH_OFFSET, pEnabled); } /* Function Name: * rtl8367c_setAsicLutIpMulticastLookup * Description: * Set LUT IP multicast + VID lookup function * Input: * enabled - 1: enabled, 0: disabled * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_setAsicLutIpMulticastVidLookup(rtk_uint32 enabled) { return rtl8367c_setAsicRegBit(RTL8367C_REG_LUT_CFG2, RTL8367C_LUT_IPMC_VID_HASH_OFFSET, enabled); } /* Function Name: * rtl8367c_getAsicLutIpMulticastVidLookup * Description: * Get LUT IP multicast lookup function * Input: * pEnabled - 1: enabled, 0: disabled * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutIpMulticastVidLookup(rtk_uint32* pEnabled) { return rtl8367c_getAsicRegBit(RTL8367C_REG_LUT_CFG2, RTL8367C_LUT_IPMC_VID_HASH_OFFSET, pEnabled); } /* Function Name: * rtl8367c_setAsicLutIpLookupMethod * Description: * Set LUT IP lookup hash with DIP or {DIP,SIP} pair * Input: * type - 1: When DIP can be found in IPMC_GROUP_TABLE, use DIP+SIP Hash, otherwise, use DIP+(SIP=0.0.0.0) Hash. * 0: When DIP can be found in IPMC_GROUP_TABLE, use DIP+(SIP=0.0.0.0) Hash, otherwise use DIP+SIP Hash. * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_setAsicLutIpLookupMethod(rtk_uint32 type) { return rtl8367c_setAsicRegBit(RTL8367C_REG_LUT_CFG, RTL8367C_LUT_IPMC_LOOKUP_OP_OFFSET, type); } /* Function Name: * rtl8367c_getAsicLutIpLookupMethod * Description: * Get LUT IP lookup hash with DIP or {DIP,SIP} pair * Input: * pType - 1: When DIP can be found in IPMC_GROUP_TABLE, use DIP+SIP Hash, otherwise, use DIP+(SIP=0.0.0.0) Hash. * 0: When DIP can be found in IPMC_GROUP_TABLE, use DIP+(SIP=0.0.0.0) Hash, otherwise use DIP+SIP Hash. * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutIpLookupMethod(rtk_uint32* pType) { return rtl8367c_getAsicRegBit(RTL8367C_REG_LUT_CFG, RTL8367C_LUT_IPMC_LOOKUP_OP_OFFSET, pType); } /* Function Name: * rtl8367c_setAsicLutAgeTimerSpeed * Description: * Set LUT ageing out speed * Input: * timer - Ageing out timer 0:Has been aged out * speed - Ageing out speed 0-fastest 3-slowest * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_OUT_OF_RANGE - input parameter out of range * Note: * None */ ret_t rtl8367c_setAsicLutAgeTimerSpeed(rtk_uint32 timer, rtk_uint32 speed) { if(timer>RTL8367C_LUT_AGETIMERMAX) return RT_ERR_OUT_OF_RANGE; if(speed >RTL8367C_LUT_AGESPEEDMAX) return RT_ERR_OUT_OF_RANGE; return rtl8367c_setAsicRegBits(RTL8367C_REG_LUT_CFG, RTL8367C_AGE_TIMER_MASK | RTL8367C_AGE_SPEED_MASK, (timer << RTL8367C_AGE_TIMER_OFFSET) | (speed << RTL8367C_AGE_SPEED_OFFSET)); } /* Function Name: * rtl8367c_getAsicLutAgeTimerSpeed * Description: * Get LUT ageing out speed * Input: * pTimer - Ageing out timer 0:Has been aged out * pSpeed - Ageing out speed 0-fastest 3-slowest * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_OUT_OF_RANGE - input parameter out of range * Note: * None */ ret_t rtl8367c_getAsicLutAgeTimerSpeed(rtk_uint32* pTimer, rtk_uint32* pSpeed) { rtk_uint32 regData; ret_t retVal; retVal = rtl8367c_getAsicReg(RTL8367C_REG_LUT_CFG, ®Data); if(retVal != RT_ERR_OK) return retVal; *pTimer = (regData & RTL8367C_AGE_TIMER_MASK) >> RTL8367C_AGE_TIMER_OFFSET; *pSpeed = (regData & RTL8367C_AGE_SPEED_MASK) >> RTL8367C_AGE_SPEED_OFFSET; return RT_ERR_OK; } /* Function Name: * rtl8367c_setAsicLutCamTbUsage * Description: * Configure LUT CAM table usage * Input: * enabled - L2 CAM table usage 1: enabled, 0: disabled * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_setAsicLutCamTbUsage(rtk_uint32 enabled) { ret_t retVal; retVal = rtl8367c_setAsicRegBit(RTL8367C_REG_LUT_CFG, RTL8367C_BCAM_DISABLE_OFFSET, enabled ? 0 : 1); return retVal; } /* Function Name: * rtl8367c_getAsicLutCamTbUsage * Description: * Get LUT CAM table usage * Input: * pEnabled - L2 CAM table usage 1: enabled, 0: disabled * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutCamTbUsage(rtk_uint32* pEnabled) { ret_t retVal; rtk_uint32 regData; if ((retVal = rtl8367c_getAsicRegBit(RTL8367C_REG_LUT_CFG, RTL8367C_BCAM_DISABLE_OFFSET, ®Data)) != RT_ERR_OK) return retVal; *pEnabled = regData ? 0 : 1; return RT_ERR_OK; } /* Function Name: * rtl8367c_setAsicLutLearnLimitNo * Description: * Set per-Port auto learning limit number * Input: * port - Physical port number (0~7) * number - ASIC auto learning entries limit number * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_ID - Invalid port number * RT_ERR_LIMITED_L2ENTRY_NUM - Invalid auto learning limit number * Note: * None */ /*修改: RTL8367C_PORTIDMAX, RTL8367C_LUT_LEARNLIMITMAX, RTL8367C_LUT_PORT_LEARN_LIMITNO_REG*/ ret_t rtl8367c_setAsicLutLearnLimitNo(rtk_uint32 port, rtk_uint32 number) { if(port > RTL8367C_PORTIDMAX) return RT_ERR_PORT_ID; if(number > RTL8367C_LUT_LEARNLIMITMAX) return RT_ERR_LIMITED_L2ENTRY_NUM; if(port < 8) return rtl8367c_setAsicReg(RTL8367C_LUT_PORT_LEARN_LIMITNO_REG(port), number); else return rtl8367c_setAsicReg(RTL8367C_REG_LUT_PORT8_LEARN_LIMITNO+port-8, number); } /* Function Name: * rtl8367c_getAsicLutLearnLimitNo * Description: * Get per-Port auto learning limit number * Input: * port - Physical port number (0~7) * pNumber - ASIC auto learning entries limit number * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_ID - Invalid port number * Note: * None */ /*修改: RTL8367C_PORTIDMAX, RTL8367C_LUT_PORT_LEARN_LIMITNO_REG*/ ret_t rtl8367c_getAsicLutLearnLimitNo(rtk_uint32 port, rtk_uint32* pNumber) { if(port > RTL8367C_PORTIDMAX) return RT_ERR_PORT_ID; if(port < 8) return rtl8367c_getAsicReg(RTL8367C_LUT_PORT_LEARN_LIMITNO_REG(port), pNumber); else return rtl8367c_getAsicReg(RTL8367C_REG_LUT_PORT8_LEARN_LIMITNO+port-8, pNumber); } /* Function Name: * rtl8367c_setAsicSystemLutLearnLimitNo * Description: * Set system auto learning limit number * Input: * number - ASIC auto learning entries limit number * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_ID - Invalid port number * RT_ERR_LIMITED_L2ENTRY_NUM - Invalid auto learning limit number * Note: * None */ /*修改: RTL8367C_LUT_LEARNLIMITMAX*/ ret_t rtl8367c_setAsicSystemLutLearnLimitNo(rtk_uint32 number) { if(number > RTL8367C_LUT_LEARNLIMITMAX) return RT_ERR_LIMITED_L2ENTRY_NUM; return rtl8367c_setAsicReg(RTL8367C_REG_LUT_SYS_LEARN_LIMITNO, number); } /* Function Name: * rtl8367c_getAsicSystemLutLearnLimitNo * Description: * Get system auto learning limit number * Input: * port - Physical port number (0~7) * pNumber - ASIC auto learning entries limit number * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_ID - Invalid port number * Note: * None */ ret_t rtl8367c_getAsicSystemLutLearnLimitNo(rtk_uint32 *pNumber) { if(NULL == pNumber) return RT_ERR_NULL_POINTER; return rtl8367c_getAsicReg(RTL8367C_REG_LUT_SYS_LEARN_LIMITNO, pNumber); } /* Function Name: * rtl8367c_setAsicLutLearnOverAct * Description: * Set auto learn over limit number action * Input: * action - Learn over action 0:normal, 1:drop 2:trap * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_NOT_ALLOWED - Invalid learn over action * Note: * None */ ret_t rtl8367c_setAsicLutLearnOverAct(rtk_uint32 action) { if(action >= LRNOVERACT_END) return RT_ERR_NOT_ALLOWED; return rtl8367c_setAsicRegBits(RTL8367C_REG_PORT_SECURITY_CTRL, RTL8367C_LUT_LEARN_OVER_ACT_MASK, action); } /* Function Name: * rtl8367c_getAsicLutLearnOverAct * Description: * Get auto learn over limit number action * Input: * pAction - Learn over action 0:normal, 1:drop 2:trap * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutLearnOverAct(rtk_uint32* pAction) { return rtl8367c_getAsicRegBits(RTL8367C_REG_PORT_SECURITY_CTRL, RTL8367C_LUT_LEARN_OVER_ACT_MASK, pAction); } /* Function Name: * rtl8367c_setAsicSystemLutLearnOverAct * Description: * Set system auto learn over limit number action * Input: * action - Learn over action 0:normal, 1:drop, 2:trap * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_NOT_ALLOWED - Invalid learn over action * Note: * None */ ret_t rtl8367c_setAsicSystemLutLearnOverAct(rtk_uint32 action) { if(action >= LRNOVERACT_END) return RT_ERR_NOT_ALLOWED; return rtl8367c_setAsicRegBits(RTL8367C_REG_LUT_LRN_SYS_LMT_CTRL, RTL8367C_LUT_SYSTEM_LEARN_OVER_ACT_MASK, action); } /* Function Name: * rtl8367c_getAsicSystemLutLearnOverAct * Description: * Get system auto learn over limit number action * Input: * pAction - Learn over action 0:normal, 1:drop 2:trap * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicSystemLutLearnOverAct(rtk_uint32 *pAction) { if(NULL == pAction) return RT_ERR_NULL_POINTER; return rtl8367c_getAsicRegBits(RTL8367C_REG_LUT_LRN_SYS_LMT_CTRL, RTL8367C_LUT_SYSTEM_LEARN_OVER_ACT_MASK, pAction); } /* Function Name: * rtl8367c_setAsicSystemLutLearnPortMask * Description: * Set system auto learn limit port mask * Input: * portmask - port mask of system learning limit * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_MASK - Error port mask * Note: * None */ /*修改: RTL8367C_LUT_SYSTEM_LEARN_PMASK_MASK*/ ret_t rtl8367c_setAsicSystemLutLearnPortMask(rtk_uint32 portmask) { ret_t retVal; if(portmask > RTL8367C_PORTMASK) return RT_ERR_PORT_MASK; retVal = rtl8367c_setAsicRegBits(RTL8367C_REG_LUT_LRN_SYS_LMT_CTRL, RTL8367C_LUT_SYSTEM_LEARN_PMASK_MASK, portmask & 0xff); if(retVal != RT_ERR_OK) return retVal; retVal = rtl8367c_setAsicRegBits(RTL8367C_REG_LUT_LRN_SYS_LMT_CTRL, RTL8367C_LUT_SYSTEM_LEARN_PMASK1_MASK, (portmask>>8) & 0x7); if(retVal != RT_ERR_OK) return retVal; return RT_ERR_OK; } /* Function Name: * rtl8367c_getAsicSystemLutLearnPortMask * Description: * Get system auto learn limit port mask * Input: * None * Output: * pPortmask - port mask of system learning limit * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_NULL_POINTER - NULL pointer * Note: * None */ /*修改: RTL8367C_LUT_SYSTEM_LEARN_PMASK_MASK*/ ret_t rtl8367c_getAsicSystemLutLearnPortMask(rtk_uint32 *pPortmask) { rtk_uint32 tmpmask; ret_t retVal; if(NULL == pPortmask) return RT_ERR_NULL_POINTER; retVal = rtl8367c_getAsicRegBits(RTL8367C_REG_LUT_LRN_SYS_LMT_CTRL, RTL8367C_LUT_SYSTEM_LEARN_PMASK_MASK, &tmpmask); if(retVal != RT_ERR_OK) return retVal; *pPortmask = tmpmask & 0xff; retVal = rtl8367c_getAsicRegBits(RTL8367C_REG_LUT_LRN_SYS_LMT_CTRL, RTL8367C_LUT_SYSTEM_LEARN_PMASK1_MASK, &tmpmask); if(retVal != RT_ERR_OK) return retVal; *pPortmask |= (tmpmask & 0x7) << 8; return RT_ERR_OK; } /* Function Name: * rtl8367c_setAsicL2LookupTb * Description: * Set filtering database entry * Input: * pL2Table - L2 table entry writing to 8K+64 filtering database * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_setAsicL2LookupTb(rtl8367c_luttb *pL2Table) { ret_t retVal; rtk_uint32 regData; rtk_uint16 *accessPtr; rtk_uint32 i; rtk_uint16 smil2Table[RTL8367C_LUT_TABLE_SIZE]; rtk_uint32 tblCmd; rtk_uint32 busyCounter; memset(smil2Table, 0x00, sizeof(rtk_uint16) * RTL8367C_LUT_TABLE_SIZE); _rtl8367c_fdbStUser2Smi(pL2Table, smil2Table); if(pL2Table->wait_time == 0) busyCounter = RTL8367C_LUT_BUSY_CHECK_NO; else busyCounter = pL2Table->wait_time; while(busyCounter) { retVal = rtl8367c_getAsicRegBit(RTL8367C_TABLE_ACCESS_STATUS_REG, RTL8367C_TABLE_LUT_ADDR_BUSY_FLAG_OFFSET,®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->lookup_busy = regData; if(!regData) break; busyCounter --; if(busyCounter == 0) return RT_ERR_BUSYWAIT_TIMEOUT; } accessPtr = smil2Table; regData = *accessPtr; for(i = 0; i < RTL8367C_LUT_ENTRY_SIZE; i++) { retVal = rtl8367c_setAsicReg(RTL8367C_TABLE_ACCESS_WRDATA_BASE + i, regData); if(retVal != RT_ERR_OK) return retVal; accessPtr ++; regData = *accessPtr; } tblCmd = (RTL8367C_TABLE_ACCESS_REG_DATA(TB_OP_WRITE,TB_TARGET_L2)) & (RTL8367C_TABLE_TYPE_MASK | RTL8367C_COMMAND_TYPE_MASK); /* Write Command */ retVal = rtl8367c_setAsicReg(RTL8367C_TABLE_ACCESS_CTRL_REG, tblCmd); if(retVal != RT_ERR_OK) return retVal; if(pL2Table->wait_time == 0) busyCounter = RTL8367C_LUT_BUSY_CHECK_NO; else busyCounter = pL2Table->wait_time; while(busyCounter) { retVal = rtl8367c_getAsicRegBit(RTL8367C_TABLE_ACCESS_STATUS_REG, RTL8367C_TABLE_LUT_ADDR_BUSY_FLAG_OFFSET,®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->lookup_busy = regData; if(!regData) break; busyCounter --; if(busyCounter == 0) return RT_ERR_BUSYWAIT_TIMEOUT; } /*Read access status*/ retVal = rtl8367c_getAsicRegBit(RTL8367C_TABLE_ACCESS_STATUS_REG, RTL8367C_HIT_STATUS_OFFSET, ®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->lookup_hit = regData; if(!pL2Table->lookup_hit) return RT_ERR_FAILED; /*Read access address*/ /* retVal = rtl8367c_getAsicRegBits(RTL8367C_TABLE_ACCESS_STATUS_REG, RTL8367C_TABLE_LUT_ADDR_TYPE_MASK | RTL8367C_TABLE_LUT_ADDR_ADDRESS_MASK,®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->address = regData;*/ retVal = rtl8367c_getAsicReg(RTL8367C_TABLE_ACCESS_STATUS_REG, ®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->address = (regData & 0x7ff) | ((regData & 0x4000) >> 3) | ((regData & 0x800) << 1); pL2Table->lookup_busy = 0; return RT_ERR_OK; } /* Function Name: * rtl8367c_getAsicL2LookupTb * Description: * Get filtering database entry * Input: * pL2Table - L2 table entry writing to 2K+64 filtering database * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_INPUT - Invalid input parameter * RT_ERR_BUSYWAIT_TIMEOUT - LUT is busy at retrieving * Note: * None */ ret_t rtl8367c_getAsicL2LookupTb(rtk_uint32 method, rtl8367c_luttb *pL2Table) { ret_t retVal; rtk_uint32 regData; rtk_uint16* accessPtr; rtk_uint32 i; rtk_uint16 smil2Table[RTL8367C_LUT_TABLE_SIZE]; rtk_uint32 busyCounter; rtk_uint32 tblCmd; if(pL2Table->wait_time == 0) busyCounter = RTL8367C_LUT_BUSY_CHECK_NO; else busyCounter = pL2Table->wait_time; while(busyCounter) { retVal = rtl8367c_getAsicRegBit(RTL8367C_TABLE_ACCESS_STATUS_REG, RTL8367C_TABLE_LUT_ADDR_BUSY_FLAG_OFFSET,®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->lookup_busy = regData; if(!pL2Table->lookup_busy) break; busyCounter --; if(busyCounter == 0) return RT_ERR_BUSYWAIT_TIMEOUT; } tblCmd = (method << RTL8367C_ACCESS_METHOD_OFFSET) & RTL8367C_ACCESS_METHOD_MASK; switch(method) { case LUTREADMETHOD_ADDRESS: case LUTREADMETHOD_NEXT_ADDRESS: case LUTREADMETHOD_NEXT_L2UC: case LUTREADMETHOD_NEXT_L2MC: case LUTREADMETHOD_NEXT_L3MC: case LUTREADMETHOD_NEXT_L2L3MC: retVal = rtl8367c_setAsicReg(RTL8367C_TABLE_ACCESS_ADDR_REG, pL2Table->address); if(retVal != RT_ERR_OK) return retVal; break; case LUTREADMETHOD_MAC: memset(smil2Table, 0x00, sizeof(rtk_uint16) * RTL8367C_LUT_TABLE_SIZE); _rtl8367c_fdbStUser2Smi(pL2Table, smil2Table); accessPtr = smil2Table; regData = *accessPtr; for(i=0; iaddress); if(retVal != RT_ERR_OK) return retVal; tblCmd = tblCmd | ((pL2Table->spa << RTL8367C_TABLE_ACCESS_CTRL_SPA_OFFSET) & RTL8367C_TABLE_ACCESS_CTRL_SPA_MASK); break; default: return RT_ERR_INPUT; } tblCmd = tblCmd | ((RTL8367C_TABLE_ACCESS_REG_DATA(TB_OP_READ,TB_TARGET_L2)) & (RTL8367C_TABLE_TYPE_MASK | RTL8367C_COMMAND_TYPE_MASK)); /* Read Command */ retVal = rtl8367c_setAsicReg(RTL8367C_TABLE_ACCESS_CTRL_REG, tblCmd); if(retVal != RT_ERR_OK) return retVal; if(pL2Table->wait_time == 0) busyCounter = RTL8367C_LUT_BUSY_CHECK_NO; else busyCounter = pL2Table->wait_time; while(busyCounter) { retVal = rtl8367c_getAsicRegBit(RTL8367C_TABLE_ACCESS_STATUS_REG, RTL8367C_TABLE_LUT_ADDR_BUSY_FLAG_OFFSET,®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->lookup_busy = regData; if(!pL2Table->lookup_busy) break; busyCounter --; if(busyCounter == 0) return RT_ERR_BUSYWAIT_TIMEOUT; } retVal = rtl8367c_getAsicRegBit(RTL8367C_TABLE_ACCESS_STATUS_REG, RTL8367C_HIT_STATUS_OFFSET,®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->lookup_hit = regData; if(!pL2Table->lookup_hit) return RT_ERR_L2_ENTRY_NOTFOUND; /*Read access address*/ //retVal = rtl8367c_getAsicRegBits(RTL8367C_TABLE_ACCESS_STATUS_REG, RTL8367C_TABLE_LUT_ADDR_TYPE_MASK | RTL8367C_TABLE_LUT_ADDR_ADDRESS_MASK,®Data); retVal = rtl8367c_getAsicReg(RTL8367C_TABLE_ACCESS_STATUS_REG, ®Data); if(retVal != RT_ERR_OK) return retVal; pL2Table->address = (regData & 0x7ff) | ((regData & 0x4000) >> 3) | ((regData & 0x800) << 1); /*read L2 entry */ memset(smil2Table, 0x00, sizeof(rtk_uint16) * RTL8367C_LUT_TABLE_SIZE); accessPtr = smil2Table; for(i = 0; i < RTL8367C_LUT_ENTRY_SIZE; i++) { retVal = rtl8367c_getAsicReg(RTL8367C_TABLE_ACCESS_RDDATA_BASE + i, ®Data); if(retVal != RT_ERR_OK) return retVal; *accessPtr = regData; accessPtr ++; } _rtl8367c_fdbStSmi2User(pL2Table, smil2Table); return RT_ERR_OK; } /* Function Name: * rtl8367c_getAsicLutLearnNo * Description: * Get per-Port auto learning number * Input: * port - Physical port number (0~7) * pNumber - ASIC auto learning entries number * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_ID - Invalid port number * Note: * None */ /*修改RTL8367C_PORTIDMAX, RTL8367C_REG_L2_LRN_CNT_REG, port10 reg is not contnious, wait for updating of base.h*/ ret_t rtl8367c_getAsicLutLearnNo(rtk_uint32 port, rtk_uint32* pNumber) { ret_t retVal; if(port > RTL8367C_PORTIDMAX) return RT_ERR_PORT_ID; if(port < 10) { retVal = rtl8367c_getAsicReg(RTL8367C_REG_L2_LRN_CNT_REG(port), pNumber); if (retVal != RT_ERR_OK) return retVal; } else { retVal = rtl8367c_getAsicReg(RTL8367C_REG_L2_LRN_CNT_CTRL10, pNumber); if (retVal != RT_ERR_OK) return retVal; } return RT_ERR_OK; } /* Function Name: * rtl8367c_setAsicLutFlushAll * Description: * Flush all entries in LUT. Includes static & dynamic entries * Input: * None * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_setAsicLutFlushAll(void) { return rtl8367c_setAsicRegBit(RTL8367C_REG_L2_FLUSH_CTRL3, RTL8367C_L2_FLUSH_CTRL3_OFFSET, 1); } /* Function Name: * rtl8367c_getAsicLutFlushAllStatus * Description: * Get Flush all status, 1:Busy, 0 normal * Input: * None * Output: * pBusyStatus - Busy state * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_NULL_POINTER - Null pointer * Note: * None */ ret_t rtl8367c_getAsicLutFlushAllStatus(rtk_uint32 *pBusyStatus) { if(NULL == pBusyStatus) return RT_ERR_NULL_POINTER; return rtl8367c_getAsicRegBit(RTL8367C_REG_L2_FLUSH_CTRL3, RTL8367C_L2_FLUSH_CTRL3_OFFSET, pBusyStatus); } /* Function Name: * rtl8367c_setAsicLutForceFlush * Description: * Set per port force flush setting * Input: * portmask - portmask(0~0xFF) * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_MASK - Invalid portmask * Note: * None */ /*port8~port10的设置在另外一个register, wait for updating of base.h, reg.h*/ ret_t rtl8367c_setAsicLutForceFlush(rtk_uint32 portmask) { ret_t retVal; if(portmask > RTL8367C_PORTMASK) return RT_ERR_PORT_MASK; retVal = rtl8367c_setAsicRegBits(RTL8367C_FORCE_FLUSH_REG, RTL8367C_FORCE_FLUSH_PORTMASK_MASK, portmask & 0xff); if(retVal != RT_ERR_OK) return retVal; retVal = rtl8367c_setAsicRegBits(RTL8367C_REG_FORCE_FLUSH1, RTL8367C_PORTMASK1_MASK, (portmask >> 8) & 0x7); if(retVal != RT_ERR_OK) return retVal; return RT_ERR_OK; } /* Function Name: * rtl8367c_getAsicLutForceFlushStatus * Description: * Get per port force flush status * Input: * pPortmask - portmask(0~0xFF) * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ /*port8~port10的设置在另外一个register, wait for updating of base.h, reg.h*/ ret_t rtl8367c_getAsicLutForceFlushStatus(rtk_uint32 *pPortmask) { rtk_uint32 tmpMask; ret_t retVal; retVal = rtl8367c_getAsicRegBits(RTL8367C_FORCE_FLUSH_REG, RTL8367C_BUSY_STATUS_MASK,&tmpMask); if(retVal != RT_ERR_OK) return retVal; *pPortmask = tmpMask & 0xff; retVal = rtl8367c_getAsicRegBits(RTL8367C_REG_FORCE_FLUSH1, RTL8367C_BUSY_STATUS1_MASK,&tmpMask); if(retVal != RT_ERR_OK) return retVal; *pPortmask |= (tmpMask & 7) << 8; return RT_ERR_OK; } /* Function Name: * rtl8367c_setAsicLutFlushMode * Description: * Set user force L2 pLutSt table flush mode * Input: * mode - 0:Port based 1: Port + VLAN based 2:Port + FID/MSTI based * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_NOT_ALLOWED - Actions not allowed by the function * Note: * None */ ret_t rtl8367c_setAsicLutFlushMode(rtk_uint32 mode) { if( mode >= FLUSHMDOE_END ) return RT_ERR_NOT_ALLOWED; return rtl8367c_setAsicRegBits(RTL8367C_REG_L2_FLUSH_CTRL2, RTL8367C_LUT_FLUSH_MODE_MASK, mode); } /* Function Name: * rtl8367c_getAsicLutFlushMode * Description: * Get user force L2 pLutSt table flush mode * Input: * pMode - 0:Port based 1: Port + VLAN based 2:Port + FID/MSTI based * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutFlushMode(rtk_uint32* pMode) { return rtl8367c_getAsicRegBits(RTL8367C_REG_L2_FLUSH_CTRL2, RTL8367C_LUT_FLUSH_MODE_MASK, pMode); } /* Function Name: * rtl8367c_setAsicLutFlushType * Description: * Get L2 LUT flush type * Input: * type - 0: dynamic unicast; 1: both dynamic and static unicast entry * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_setAsicLutFlushType(rtk_uint32 type) { return rtl8367c_setAsicRegBit(RTL8367C_REG_L2_FLUSH_CTRL2, RTL8367C_LUT_FLUSH_TYPE_OFFSET,type); } /* Function Name: * rtl8367c_getAsicLutFlushType * Description: * Set L2 LUT flush type * Input: * pType - 0: dynamic unicast; 1: both dynamic and static unicast entry * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutFlushType(rtk_uint32* pType) { return rtl8367c_getAsicRegBit(RTL8367C_REG_L2_FLUSH_CTRL2, RTL8367C_LUT_FLUSH_TYPE_OFFSET,pType); } /* Function Name: * rtl8367c_setAsicLutFlushVid * Description: * Set VID of Port + VID pLutSt flush mode * Input: * vid - Vid (0~4095) * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_VLAN_VID - Invalid VID parameter (0~4095) * Note: * None */ ret_t rtl8367c_setAsicLutFlushVid(rtk_uint32 vid) { if( vid > RTL8367C_VIDMAX ) return RT_ERR_VLAN_VID; return rtl8367c_setAsicRegBits(RTL8367C_REG_L2_FLUSH_CTRL1, RTL8367C_LUT_FLUSH_VID_MASK, vid); } /* Function Name: * rtl8367c_getAsicLutFlushVid * Description: * Get VID of Port + VID pLutSt flush mode * Input: * pVid - Vid (0~4095) * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutFlushVid(rtk_uint32* pVid) { return rtl8367c_getAsicRegBits(RTL8367C_REG_L2_FLUSH_CTRL1, RTL8367C_LUT_FLUSH_VID_MASK, pVid); } /* Function Name: * rtl8367c_setAsicPortFlusdFid * Description: * Set FID of Port + FID pLutSt flush mode * Input: * fid - FID/MSTI for force flush * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_L2_FID - Invalid FID (0~15) * Note: * None */ ret_t rtl8367c_setAsicLutFlushFid(rtk_uint32 fid) { if( fid > RTL8367C_FIDMAX ) return RT_ERR_L2_FID; return rtl8367c_setAsicRegBits(RTL8367C_REG_L2_FLUSH_CTRL1, RTL8367C_LUT_FLUSH_FID_MASK, fid); } /* Function Name: * rtl8367c_getAsicLutFlushFid * Description: * Get FID of Port + FID pLutSt flush mode * Input: * pFid - FID/MSTI for force flush * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * Note: * None */ ret_t rtl8367c_getAsicLutFlushFid(rtk_uint32* pFid) { return rtl8367c_getAsicRegBits(RTL8367C_REG_L2_FLUSH_CTRL1, RTL8367C_LUT_FLUSH_FID_MASK, pFid); } /* Function Name: * rtl8367c_setAsicLutDisableAging * Description: * Set L2 LUT aging per port setting * Input: * port - Physical port number (0~7) * disabled - 0: enable aging; 1: disabling aging * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_ID - Invalid port number * Note: * None */ /*修改RTL8367C_PORTIDMAX*/ ret_t rtl8367c_setAsicLutDisableAging(rtk_uint32 port, rtk_uint32 disabled) { if(port > RTL8367C_PORTIDMAX) return RT_ERR_PORT_ID; return rtl8367c_setAsicRegBit(RTL8367C_LUT_AGEOUT_CTRL_REG, port, disabled); } /* Function Name: * rtl8367c_getAsicLutDisableAging * Description: * Get L2 LUT aging per port setting * Input: * port - Physical port number (0~7) * pDisabled - 0: enable aging; 1: disabling aging * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_PORT_ID - Invalid port number * Note: * None */ /*修改RTL8367C_PORTIDMAX*/ ret_t rtl8367c_getAsicLutDisableAging(rtk_uint32 port, rtk_uint32 *pDisabled) { if(port > RTL8367C_PORTIDMAX) return RT_ERR_PORT_ID; return rtl8367c_getAsicRegBit(RTL8367C_LUT_AGEOUT_CTRL_REG, port, pDisabled); } /* Function Name: * rtl8367c_setAsicLutIPMCGroup * Description: * Set IPMC Group Table * Input: * index - the entry index in table (0 ~ 63) * group_addr - the multicast group address (224.0.0.0 ~ 239.255.255.255) * vid - VLAN ID * pmask - portmask * valid - valid bit * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_INPUT - Invalid parameter * Note: * None */ ret_t rtl8367c_setAsicLutIPMCGroup(rtk_uint32 index, ipaddr_t group_addr, rtk_uint32 vid, rtk_uint32 pmask, rtk_uint32 valid) { rtk_uint32 regAddr, regData, bitoffset; ipaddr_t ipData; ret_t retVal; if(index > RTL8367C_LUT_IPMCGRP_TABLE_MAX) return RT_ERR_INPUT; if (vid > RTL8367C_VIDMAX) return RT_ERR_VLAN_VID; ipData = group_addr; if( (ipData & 0xF0000000) != 0xE0000000) /* not in 224.0.0.0 ~ 239.255.255.255 */ return RT_ERR_INPUT; /* Group Address */ regAddr = RTL8367C_REG_IPMC_GROUP_ENTRY0_H + (index * 2); regData = ((ipData & 0x0FFFFFFF) >> 16); if( (retVal = rtl8367c_setAsicReg(regAddr, regData)) != RT_ERR_OK) return retVal; regAddr++; regData = (ipData & 0x0000FFFF); if( (retVal = rtl8367c_setAsicReg(regAddr, regData)) != RT_ERR_OK) return retVal; /* VID */ regAddr = RTL8367C_REG_IPMC_GROUP_VID_00 + index; regData = vid; if( (retVal = rtl8367c_setAsicReg(regAddr, regData)) != RT_ERR_OK) return retVal; /* portmask */ regAddr = RTL8367C_REG_IPMC_GROUP_PMSK_00 + index; regData = pmask; if( (retVal = rtl8367c_setAsicReg(regAddr, regData)) != RT_ERR_OK) return retVal; /* valid */ regAddr = RTL8367C_REG_IPMC_GROUP_VALID_15_0 + (index / 16); bitoffset = index % 16; if( (retVal = rtl8367c_setAsicRegBit(regAddr, bitoffset, valid)) != RT_ERR_OK) return retVal; return RT_ERR_OK; } /* Function Name: * rtl8367c_getAsicLutIPMCGroup * Description: * Set IPMC Group Table * Input: * index - the entry index in table (0 ~ 63) * Output: * pGroup_addr - the multicast group address (224.0.0.0 ~ 239.255.255.255) * pVid - VLAN ID * pPmask - portmask * pValid - Valid bit * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_INPUT - Invalid parameter * Note: * None */ ret_t rtl8367c_getAsicLutIPMCGroup(rtk_uint32 index, ipaddr_t *pGroup_addr, rtk_uint32 *pVid, rtk_uint32 *pPmask, rtk_uint32 *pValid) { rtk_uint32 regAddr, regData, bitoffset; ipaddr_t ipData; ret_t retVal; if(index > RTL8367C_LUT_IPMCGRP_TABLE_MAX) return RT_ERR_INPUT; if (NULL == pGroup_addr) return RT_ERR_NULL_POINTER; if (NULL == pVid) return RT_ERR_NULL_POINTER; if (NULL == pPmask) return RT_ERR_NULL_POINTER; /* Group address */ regAddr = RTL8367C_REG_IPMC_GROUP_ENTRY0_H + (index * 2); if( (retVal = rtl8367c_getAsicReg(regAddr, ®Data)) != RT_ERR_OK) return retVal; *pGroup_addr = (((regData & 0x00000FFF) << 16) | 0xE0000000); regAddr++; if( (retVal = rtl8367c_getAsicReg(regAddr, ®Data)) != RT_ERR_OK) return retVal; ipData = (*pGroup_addr | (regData & 0x0000FFFF)); *pGroup_addr = ipData; /* VID */ regAddr = RTL8367C_REG_IPMC_GROUP_VID_00 + index; if( (retVal = rtl8367c_getAsicReg(regAddr, ®Data)) != RT_ERR_OK) return retVal; *pVid = regData; /* portmask */ regAddr = RTL8367C_REG_IPMC_GROUP_PMSK_00 + index; if( (retVal = rtl8367c_getAsicReg(regAddr, ®Data)) != RT_ERR_OK) return retVal; *pPmask = regData; /* valid */ regAddr = RTL8367C_REG_IPMC_GROUP_VALID_15_0 + (index / 16); bitoffset = index % 16; if( (retVal = rtl8367c_getAsicRegBit(regAddr, bitoffset, ®Data)) != RT_ERR_OK) return retVal; *pValid = regData; return RT_ERR_OK; } /* Function Name: * rtl8367c_setAsicLutLinkDownForceAging * Description: * Set LUT link down aging setting. * Input: * enable - link down aging setting * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_ENABLE - Invalid parameter * Note: * None */ ret_t rtl8367c_setAsicLutLinkDownForceAging(rtk_uint32 enable) { if(enable > 1) return RT_ERR_ENABLE; return rtl8367c_setAsicRegBit(RTL8367C_REG_LUT_CFG, RTL8367C_LINKDOWN_AGEOUT_OFFSET, enable ? 0 : 1); } /* Function Name: * rtl8367c_getAsicLutLinkDownForceAging * Description: * Get LUT link down aging setting. * Input: * pEnable - link down aging setting * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_ENABLE - Invalid parameter * Note: * None */ ret_t rtl8367c_getAsicLutLinkDownForceAging(rtk_uint32 *pEnable) { rtk_uint32 value; ret_t retVal; if ((retVal = rtl8367c_getAsicRegBit(RTL8367C_REG_LUT_CFG, RTL8367C_LINKDOWN_AGEOUT_OFFSET, &value)) != RT_ERR_OK) return retVal; *pEnable = value ? 0 : 1; return RT_ERR_OK; } /* Function Name: * rtl8367c_setAsicLutIpmcFwdRouterPort * Description: * Set IPMC packet forward to router port also or not * Input: * enable - 1: Include router port, 0, exclude router port * Output: * None * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_ENABLE Invalid parameter * Note: * None */ ret_t rtl8367c_setAsicLutIpmcFwdRouterPort(rtk_uint32 enable) { if(enable > 1) return RT_ERR_ENABLE; return rtl8367c_setAsicRegBit(RTL8367C_REG_LUT_CFG2, RTL8367C_LUT_IPMC_FWD_RPORT_OFFSET, enable); } /* Function Name: * rtl8367c_getAsicLutIpmcFwdRouterPort * Description: * Get IPMC packet forward to router port also or not * Input: * None * Output: * pEnable - 1: Include router port, 0, exclude router port * Return: * RT_ERR_OK - Success * RT_ERR_SMI - SMI access error * RT_ERR_NULL_POINTER - Null pointer * Note: * None */ ret_t rtl8367c_getAsicLutIpmcFwdRouterPort(rtk_uint32 *pEnable) { if(NULL == pEnable) return RT_ERR_NULL_POINTER; return rtl8367c_getAsicRegBit(RTL8367C_REG_LUT_CFG2, RTL8367C_LUT_IPMC_FWD_RPORT_OFFSET, pEnable); }