/* Copyright (c) 2008-2011 Freescale Semiconductor, Inc. * 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 Freescale Semiconductor nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * * ALTERNATIVELY, this software may be distributed under the terms of the * GNU General Public License ("GPL") as published by the Free Software * Foundation, either version 2 of that License or (at your option) any * later version. * * THIS SOFTWARE IS PROVIDED BY Freescale Semiconductor ``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 Freescale Semiconductor 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. */ /****************************************************************************** @File fm_common.h @Description FM internal structures and definitions. *//***************************************************************************/ #ifndef __FM_COMMON_H #define __FM_COMMON_H #include "error_ext.h" #include "std_ext.h" #include "fm_pcd_ext.h" #include "fm_port_ext.h" #define CLS_PLAN_NUM_PER_GRP 8 #if defined(__MWERKS__) && !defined(__GNUC__) #pragma pack(push,1) #endif /* defined(__MWERKS__) && ... */ #define MEM_MAP_START /**************************************************************************//** @Description PCD KG scheme registers *//***************************************************************************/ typedef _Packed struct t_FmPcdPlcrInterModuleProfileRegs { volatile uint32_t fmpl_pemode; /* 0x090 FMPL_PEMODE - FM Policer Profile Entry Mode*/ volatile uint32_t fmpl_pegnia; /* 0x094 FMPL_PEGNIA - FM Policer Profile Entry GREEN Next Invoked Action*/ volatile uint32_t fmpl_peynia; /* 0x098 FMPL_PEYNIA - FM Policer Profile Entry YELLOW Next Invoked Action*/ volatile uint32_t fmpl_pernia; /* 0x09C FMPL_PERNIA - FM Policer Profile Entry RED Next Invoked Action*/ volatile uint32_t fmpl_pecir; /* 0x0A0 FMPL_PECIR - FM Policer Profile Entry Committed Information Rate*/ volatile uint32_t fmpl_pecbs; /* 0x0A4 FMPL_PECBS - FM Policer Profile Entry Committed Burst Size*/ volatile uint32_t fmpl_pepepir_eir; /* 0x0A8 FMPL_PEPIR_EIR - FM Policer Profile Entry Peak/Excess Information Rate*/ volatile uint32_t fmpl_pepbs_ebs; /* 0x0AC FMPL_PEPBS_EBS - FM Policer Profile Entry Peak/Excess Information Rate*/ volatile uint32_t fmpl_pelts; /* 0x0B0 FMPL_PELTS - FM Policer Profile Entry Last TimeStamp*/ volatile uint32_t fmpl_pects; /* 0x0B4 FMPL_PECTS - FM Policer Profile Entry Committed Token Status*/ volatile uint32_t fmpl_pepts_ets; /* 0x0B8 FMPL_PEPTS_ETS - FM Policer Profile Entry Peak/Excess Token Status*/ volatile uint32_t fmpl_pegpc; /* 0x0BC FMPL_PEGPC - FM Policer Profile Entry GREEN Packet Counter*/ volatile uint32_t fmpl_peypc; /* 0x0C0 FMPL_PEYPC - FM Policer Profile Entry YELLOW Packet Counter*/ volatile uint32_t fmpl_perpc; /* 0x0C4 FMPL_PERPC - FM Policer Profile Entry RED Packet Counter */ volatile uint32_t fmpl_perypc; /* 0x0C8 FMPL_PERYPC - FM Policer Profile Entry Recolored YELLOW Packet Counter*/ volatile uint32_t fmpl_perrpc; /* 0x0CC FMPL_PERRPC - FM Policer Profile Entry Recolored RED Packet Counter*/ volatile uint32_t fmpl_res1[12]; /* 0x0D0-0x0FF Reserved */ } _PackedType t_FmPcdPlcrInterModuleProfileRegs; /**************************************************************************//** @Description PCD KG scheme registers *//***************************************************************************/ typedef _Packed struct t_FmPcdKgInterModuleSchemeRegs { volatile uint32_t kgse_mode; /**< MODE */ volatile uint32_t kgse_ekfc; /**< Extract Known Fields Command */ volatile uint32_t kgse_ekdv; /**< Extract Known Default Value */ volatile uint32_t kgse_bmch; /**< Bit Mask Command High */ volatile uint32_t kgse_bmcl; /**< Bit Mask Command Low */ volatile uint32_t kgse_fqb; /**< Frame Queue Base */ volatile uint32_t kgse_hc; /**< Hash Command */ volatile uint32_t kgse_ppc; /**< Policer Profile Command */ volatile uint32_t kgse_gec[FM_PCD_KG_NUM_OF_GENERIC_REGS]; /**< Generic Extract Command */ volatile uint32_t kgse_spc; /**< KeyGen Scheme Entry Statistic Packet Counter */ volatile uint32_t kgse_dv0; /**< KeyGen Scheme Entry Default Value 0 */ volatile uint32_t kgse_dv1; /**< KeyGen Scheme Entry Default Value 1 */ volatile uint32_t kgse_ccbs; /**< KeyGen Scheme Entry Coarse Classification Bit*/ volatile uint32_t kgse_mv; /**< KeyGen Scheme Entry Match vector */ } _PackedType t_FmPcdKgInterModuleSchemeRegs; typedef _Packed struct t_FmPcdCcCapwapReassmTimeoutParams { volatile uint32_t portIdAndCapwapReassmTbl; volatile uint32_t fqidForTimeOutFrames; volatile uint32_t timeoutRequestTime; }_PackedType t_FmPcdCcCapwapReassmTimeoutParams; #define MEM_MAP_END #if defined(__MWERKS__) && !defined(__GNUC__) #pragma pack(pop) #endif /* defined(__MWERKS__) && ... */ typedef struct { uint8_t baseEntry; uint16_t numOfClsPlanEntries; uint32_t vectors[FM_PCD_MAX_NUM_OF_CLS_PLANS]; } t_FmPcdKgInterModuleClsPlanSet; /**************************************************************************//** @Description Structure for binding a port to keygen schemes. *//***************************************************************************/ typedef struct t_FmPcdKgInterModuleBindPortToSchemes { uint8_t hardwarePortId; uint8_t netEnvId; bool useClsPlan; /**< TRUE if this port uses the clsPlan mechanism */ uint8_t numOfSchemes; uint8_t schemesIds[FM_PCD_KG_NUM_OF_SCHEMES]; } t_FmPcdKgInterModuleBindPortToSchemes; typedef struct { uint32_t nextCcNodeInfo; t_List node; } t_CcNodeInfo; typedef struct { t_Handle h_CcNode; uint16_t index; t_List node; }t_CcNodeInformation; #define CC_NODE_F_OBJECT(ptr) LIST_OBJECT(ptr, t_CcNodeInformation, node) typedef struct { t_Handle h_Manip; t_List node; }t_ManipInfo; #define CC_NEXT_NODE_F_OBJECT(ptr) LIST_OBJECT(ptr, t_CcNodeInfo, node) typedef struct { uint32_t type; uint8_t prOffset; uint16_t dataOffset; uint8_t poolIndex; uint8_t poolIdForManip; uint8_t numOfTasks; uint8_t hardwarePortId; } t_GetCcParams; typedef struct { uint32_t type; int psoSize; uint32_t nia; } t_SetCcParams; typedef struct { t_GetCcParams getCcParams; t_SetCcParams setCcParams; } t_FmPortGetSetCcParams; static __inline__ bool TRY_LOCK(t_Handle h_Spinlock, volatile bool *p_Flag) { uint32_t intFlags; if (h_Spinlock) intFlags = XX_LockIntrSpinlock(h_Spinlock); else intFlags = XX_DisableAllIntr(); if (*p_Flag) { if (h_Spinlock) XX_UnlockIntrSpinlock(h_Spinlock, intFlags); else XX_RestoreAllIntr(intFlags); return FALSE; } *p_Flag = TRUE; if (h_Spinlock) XX_UnlockIntrSpinlock(h_Spinlock, intFlags); else XX_RestoreAllIntr(intFlags); return TRUE; } #define RELEASE_LOCK(_flag) _flag = FALSE; /**************************************************************************//** @Collection Defines used for manipulation CC and BMI @{ *//***************************************************************************/ #define INTERNAL_CONTEXT_OFFSET 0x80000000 #define OFFSET_OF_PR 0x40000000 #define BUFFER_POOL_ID_FOR_MANIP 0x20000000 #define NUM_OF_TASKS 0x10000000 #define OFFSET_OF_DATA 0x08000000 #define HW_PORT_ID 0x04000000 #define UPDATE_NIA_PNEN 0x80000000 #define UPDATE_PSO 0x40000000 #define UPDATE_NIA_PNDN 0x20000000 #define UPDATE_FMFP_PRC_WITH_ONE_RISC_ONLY 0x10000000 /* @} */ /**************************************************************************//** @Collection Defines used for manipulation CC and CC @{ *//***************************************************************************/ #define UPDATE_NIA_ENQ_WITHOUT_DMA 0x80000000 #define UPDATE_CC_WITH_TREE 0x40000000 #define UPDATE_CC_WITH_DELETE_TREE 0x20000000 /* @} */ /**************************************************************************//** @Collection Defines used for enabling/disabling FM interrupts @{ *//***************************************************************************/ typedef uint32_t t_FmBlockErrIntrEnable; #define ERR_INTR_EN_DMA 0x00010000 #define ERR_INTR_EN_FPM 0x80000000 #define ERR_INTR_EN_BMI 0x00800000 #define ERR_INTR_EN_QMI 0x00400000 #define ERR_INTR_EN_PRS 0x00200000 #define ERR_INTR_EN_KG 0x00100000 #define ERR_INTR_EN_PLCR 0x00080000 #define ERR_INTR_EN_MURAM 0x00040000 #define ERR_INTR_EN_IRAM 0x00020000 #define ERR_INTR_EN_10G_MAC0 0x00008000 #define ERR_INTR_EN_1G_MAC0 0x00004000 #define ERR_INTR_EN_1G_MAC1 0x00002000 #define ERR_INTR_EN_1G_MAC2 0x00001000 #define ERR_INTR_EN_1G_MAC3 0x00000800 #define ERR_INTR_EN_1G_MAC4 0x00000400 #define ERR_INTR_EN_MACSEC_MAC0 0x00000200 typedef uint32_t t_FmBlockIntrEnable; #define INTR_EN_BMI 0x80000000 #define INTR_EN_QMI 0x40000000 #define INTR_EN_PRS 0x20000000 #define INTR_EN_KG 0x10000000 #define INTR_EN_PLCR 0x08000000 #define INTR_EN_1G_MAC0_TMR 0x00080000 #define INTR_EN_1G_MAC1_TMR 0x00040000 #define INTR_EN_1G_MAC2_TMR 0x00020000 #define INTR_EN_1G_MAC3_TMR 0x00010000 #define INTR_EN_1G_MAC4_TMR 0x00000040 #define INTR_EN_REV0 0x00008000 #define INTR_EN_REV1 0x00004000 #define INTR_EN_REV2 0x00002000 #define INTR_EN_REV3 0x00001000 #define INTR_EN_BRK 0x00000080 #define INTR_EN_TMR 0x01000000 #define INTR_EN_MACSEC_MAC0 0x00000001 /* @} */ #define FM_MAX_NUM_OF_PORTS (FM_MAX_NUM_OF_OH_PORTS + \ FM_MAX_NUM_OF_1G_RX_PORTS + \ FM_MAX_NUM_OF_10G_RX_PORTS + \ FM_MAX_NUM_OF_1G_TX_PORTS + \ FM_MAX_NUM_OF_10G_TX_PORTS) #define MODULE_NAME_SIZE 30 #define DUMMY_PORT_ID 0 #define FM_LIODN_OFFSET_MASK 0x3FF /**************************************************************************//** @Description NIA Description *//***************************************************************************/ #define NIA_ORDER_RESTOR 0x00800000 #define NIA_ENG_FM_CTL 0x00000000 #define NIA_ENG_PRS 0x00440000 #define NIA_ENG_KG 0x00480000 #define NIA_ENG_PLCR 0x004C0000 #define NIA_ENG_BMI 0x00500000 #define NIA_ENG_QMI_ENQ 0x00540000 #define NIA_ENG_QMI_DEQ 0x00580000 #define NIA_ENG_MASK 0x007C0000 #define NIA_FM_CTL_AC_CC 0x00000006 #define NIA_FM_CTL_AC_HC 0x0000000C #define NIA_FM_CTL_AC_IND_MODE_TX 0x00000008 #define NIA_FM_CTL_AC_IND_MODE_RX 0x0000000A #define NIA_FM_CTL_AC_FRAG 0x0000000e #define NIA_FM_CTL_AC_PRE_FETCH 0x00000010 #define NIA_FM_CTL_AC_POST_FETCH_PCD 0x00000012 #define NIA_FM_CTL_AC_POST_FETCH_PCD_UDP_LEN 0x00000018 #define NIA_FM_CTL_AC_POST_FETCH_NO_PCD 0x00000012 #define NIA_FM_CTL_AC_FRAG_CHECK 0x00000014 #define NIA_FM_CTL_AC_MASK 0x0000001f #define NIA_BMI_AC_ENQ_FRAME 0x00000002 #define NIA_BMI_AC_TX_RELEASE 0x000002C0 #define NIA_BMI_AC_RELEASE 0x000000C0 #define NIA_BMI_AC_DISCARD 0x000000C1 #define NIA_BMI_AC_TX 0x00000274 #define NIA_BMI_AC_FETCH 0x00000208 #define NIA_BMI_AC_MASK 0x000003FF #define NIA_KG_DIRECT 0x00000100 #define NIA_KG_CC_EN 0x00000200 #define NIA_PLCR_ABSOLUTE 0x00008000 #define NIA_BMI_AC_ENQ_FRAME_WITHOUT_DMA 0x00000202 /**************************************************************************//** @Description Port Id defines *//***************************************************************************/ #define BASE_OH_PORTID 1 #define BASE_1G_RX_PORTID 8 #define BASE_10G_RX_PORTID 0x10 #define BASE_1G_TX_PORTID 0x28 #define BASE_10G_TX_PORTID 0x30 #define FM_PCD_PORT_OH_BASE_INDX 0 #define FM_PCD_PORT_1G_RX_BASE_INDX (FM_PCD_PORT_OH_BASE_INDX+FM_MAX_NUM_OF_OH_PORTS) #define FM_PCD_PORT_10G_RX_BASE_INDX (FM_PCD_PORT_1G_RX_BASE_INDX+FM_MAX_NUM_OF_1G_RX_PORTS) #define FM_PCD_PORT_1G_TX_BASE_INDX (FM_PCD_PORT_10G_RX_BASE_INDX+FM_MAX_NUM_OF_10G_RX_PORTS) #define FM_PCD_PORT_10G_TX_BASE_INDX (FM_PCD_PORT_1G_TX_BASE_INDX+FM_MAX_NUM_OF_1G_TX_PORTS) #if (FM_MAX_NUM_OF_OH_PORTS > 0) #define CHECK_PORT_ID_OH_PORTS(_relativePortId) \ if ((_relativePortId) >= FM_MAX_NUM_OF_OH_PORTS) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal OH_PORT port id")) #else #define CHECK_PORT_ID_OH_PORTS(_relativePortId) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal OH_PORT port id")) #endif #if (FM_MAX_NUM_OF_1G_RX_PORTS > 0) #define CHECK_PORT_ID_1G_RX_PORTS(_relativePortId) \ if ((_relativePortId) >= FM_MAX_NUM_OF_1G_RX_PORTS) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal 1G_RX_PORT port id")) #else #define CHECK_PORT_ID_1G_RX_PORTS(_relativePortId) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal 1G_RX_PORT port id")) #endif #if (FM_MAX_NUM_OF_10G_RX_PORTS > 0) #define CHECK_PORT_ID_10G_RX_PORTS(_relativePortId) \ if ((_relativePortId) >= FM_MAX_NUM_OF_10G_RX_PORTS) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal 10G_RX_PORT port id")) #else #define CHECK_PORT_ID_10G_RX_PORTS(_relativePortId) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal 10G_RX_PORT port id")) #endif #if (FM_MAX_NUM_OF_1G_TX_PORTS > 0) #define CHECK_PORT_ID_1G_TX_PORTS(_relativePortId) \ if ((_relativePortId) >= FM_MAX_NUM_OF_1G_TX_PORTS) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal 1G_TX_PORT port id")) #else #define CHECK_PORT_ID_1G_TX_PORTS(_relativePortId) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal 1G_TX_PORT port id")) #endif #if (FM_MAX_NUM_OF_10G_TX_PORTS > 0) #define CHECK_PORT_ID_10G_TX_PORTS(_relativePortId) \ if ((_relativePortId) >= FM_MAX_NUM_OF_10G_TX_PORTS) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal 10G_TX_PORT port id")) #else #define CHECK_PORT_ID_10G_TX_PORTS(_relativePortId) \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal 10G_TX_PORT port id")) #endif #define SW_PORT_ID_TO_HW_PORT_ID(_port, _type, _relativePortId) \ switch(_type) { \ case(e_FM_PORT_TYPE_OH_OFFLINE_PARSING): \ case(e_FM_PORT_TYPE_OH_HOST_COMMAND): \ CHECK_PORT_ID_OH_PORTS(_relativePortId); \ _port = (uint8_t)(BASE_OH_PORTID + (_relativePortId)); \ break; \ case(e_FM_PORT_TYPE_RX): \ CHECK_PORT_ID_1G_RX_PORTS(_relativePortId); \ _port = (uint8_t)(BASE_1G_RX_PORTID + (_relativePortId)); \ break; \ case(e_FM_PORT_TYPE_RX_10G): \ CHECK_PORT_ID_10G_RX_PORTS(_relativePortId); \ _port = (uint8_t)(BASE_10G_RX_PORTID + (_relativePortId)); \ break; \ case(e_FM_PORT_TYPE_TX): \ CHECK_PORT_ID_1G_TX_PORTS(_relativePortId); \ _port = (uint8_t)(BASE_1G_TX_PORTID + (_relativePortId)); \ break; \ case(e_FM_PORT_TYPE_TX_10G): \ CHECK_PORT_ID_10G_TX_PORTS(_relativePortId); \ _port = (uint8_t)(BASE_10G_TX_PORTID + (_relativePortId)); \ break; \ default: \ REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("Illegal port type")); \ _port = 0; \ break; \ } #define HW_PORT_ID_TO_SW_PORT_ID(_relativePortId, hardwarePortId) \ { if (((hardwarePortId) >= BASE_OH_PORTID) && \ ((hardwarePortId) < BASE_OH_PORTID+FM_MAX_NUM_OF_OH_PORTS)) \ _relativePortId = (uint8_t)((hardwarePortId)-BASE_OH_PORTID); \ else if (((hardwarePortId) >= BASE_10G_TX_PORTID) && \ ((hardwarePortId) < BASE_10G_TX_PORTID+FM_MAX_NUM_OF_10G_TX_PORTS)) \ _relativePortId = (uint8_t)((hardwarePortId)-BASE_10G_TX_PORTID); \ else if (((hardwarePortId) >= BASE_1G_TX_PORTID) && \ ((hardwarePortId) < BASE_1G_TX_PORTID+FM_MAX_NUM_OF_1G_TX_PORTS)) \ _relativePortId = (uint8_t)((hardwarePortId)-BASE_1G_TX_PORTID); \ else if (((hardwarePortId) >= BASE_10G_RX_PORTID) && \ ((hardwarePortId) < BASE_10G_RX_PORTID+FM_MAX_NUM_OF_10G_RX_PORTS)) \ _relativePortId = (uint8_t)((hardwarePortId)-BASE_10G_RX_PORTID); \ else if (((hardwarePortId) >= BASE_1G_RX_PORTID) && \ ((hardwarePortId) < BASE_1G_RX_PORTID+FM_MAX_NUM_OF_1G_RX_PORTS)) \ _relativePortId = (uint8_t)((hardwarePortId)-BASE_1G_RX_PORTID); \ else { \ _relativePortId = (uint8_t)DUMMY_PORT_ID; \ ASSERT_COND(TRUE); \ } \ } #define HW_PORT_ID_TO_SW_PORT_INDX(swPortIndex, hardwarePortId) \ do { \ if (((hardwarePortId) >= BASE_OH_PORTID) && ((hardwarePortId) < BASE_OH_PORTID+FM_MAX_NUM_OF_OH_PORTS)) \ swPortIndex = (uint8_t)((hardwarePortId)-BASE_OH_PORTID+FM_PCD_PORT_OH_BASE_INDX); \ else if (((hardwarePortId) >= BASE_1G_RX_PORTID) && \ ((hardwarePortId) < BASE_1G_RX_PORTID+FM_MAX_NUM_OF_1G_RX_PORTS)) \ swPortIndex = (uint8_t)((hardwarePortId)-BASE_1G_RX_PORTID+FM_PCD_PORT_1G_RX_BASE_INDX); \ else if (((hardwarePortId) >= BASE_10G_RX_PORTID) && \ ((hardwarePortId) < BASE_10G_RX_PORTID+FM_MAX_NUM_OF_10G_RX_PORTS)) \ swPortIndex = (uint8_t)((hardwarePortId)-BASE_10G_RX_PORTID+FM_PCD_PORT_10G_RX_BASE_INDX); \ else if (((hardwarePortId) >= BASE_1G_TX_PORTID) && \ ((hardwarePortId) < BASE_1G_TX_PORTID+FM_MAX_NUM_OF_1G_TX_PORTS)) \ swPortIndex = (uint8_t)((hardwarePortId)-BASE_1G_TX_PORTID+FM_PCD_PORT_1G_TX_BASE_INDX); \ else if (((hardwarePortId) >= BASE_10G_TX_PORTID) && \ ((hardwarePortId) < BASE_10G_TX_PORTID+FM_MAX_NUM_OF_10G_TX_PORTS)) \ swPortIndex = (uint8_t)((hardwarePortId)-BASE_10G_TX_PORTID+FM_PCD_PORT_10G_TX_BASE_INDX); \ else ASSERT_COND(FALSE); \ } while (0) #define SW_PORT_INDX_TO_HW_PORT_ID(hardwarePortId, swPortIndex) \ do { \ if (((swPortIndex) >= FM_PCD_PORT_OH_BASE_INDX) && ((swPortIndex) < FM_PCD_PORT_1G_RX_BASE_INDX)) \ hardwarePortId = (uint8_t)((swPortIndex)-FM_PCD_PORT_OH_BASE_INDX+BASE_OH_PORTID); \ else if (((swPortIndex) >= FM_PCD_PORT_1G_RX_BASE_INDX) && ((swPortIndex) < FM_PCD_PORT_10G_RX_BASE_INDX)) \ hardwarePortId = (uint8_t)((swPortIndex)-FM_PCD_PORT_1G_RX_BASE_INDX+BASE_1G_RX_PORTID); \ else if (((swPortIndex) >= FM_PCD_PORT_10G_RX_BASE_INDX) && ((swPortIndex) < FM_MAX_NUM_OF_PORTS)) \ hardwarePortId = (uint8_t)((swPortIndex)-FM_PCD_PORT_10G_RX_BASE_INDX+BASE_10G_RX_PORTID); \ else if (((swPortIndex) >= FM_PCD_PORT_1G_TX_BASE_INDX) && ((swPortIndex) < FM_PCD_PORT_10G_TX_BASE_INDX)) \ hardwarePortId = (uint8_t)((swPortIndex)-FM_PCD_PORT_1G_TX_BASE_INDX+BASE_1G_TX_PORTID); \ else if (((swPortIndex) >= FM_PCD_PORT_10G_TX_BASE_INDX) && ((swPortIndex) < FM_MAX_NUM_OF_PORTS)) \ hardwarePortId = (uint8_t)((swPortIndex)-FM_PCD_PORT_10G_TX_BASE_INDX+BASE_10G_TX_PORTID); \ else ASSERT_COND(FALSE); \ } while (0) #define BMI_FIFO_UNITS 0x100 typedef struct { void (*f_Isr) (t_Handle h_Arg); t_Handle h_SrcHandle; uint8_t guestId; } t_FmIntrSrc; #define ILLEGAL_HDR_NUM 0xFF #define NO_HDR_NUM FM_PCD_PRS_NUM_OF_HDRS #define IS_PRIVATE_HEADER(hdr) (((hdr) == HEADER_TYPE_USER_DEFINED_SHIM1) || \ ((hdr) == HEADER_TYPE_USER_DEFINED_SHIM2)) #define IS_SPECIAL_HEADER(hdr) ((hdr) == HEADER_TYPE_MACSEC) #define GET_PRS_HDR_NUM(num, hdr) \ switch(hdr) \ { case(HEADER_TYPE_ETH): num = 0; break; \ case(HEADER_TYPE_LLC_SNAP): num = 1; break; \ case(HEADER_TYPE_VLAN): num = 2; break; \ case(HEADER_TYPE_PPPoE): num = 3; break; \ case(HEADER_TYPE_MPLS): num = 4; break; \ case(HEADER_TYPE_IPv4): num = 5; break; \ case(HEADER_TYPE_IPv6): num = 6; break; \ case(HEADER_TYPE_GRE): num = 7; break; \ case(HEADER_TYPE_MINENCAP): num = 8; break; \ case(HEADER_TYPE_USER_DEFINED_L3): num = 9; break; \ case(HEADER_TYPE_TCP): num = 10; break; \ case(HEADER_TYPE_UDP): num = 11; break; \ case(HEADER_TYPE_IPSEC_AH): \ case(HEADER_TYPE_IPSEC_ESP): num = 12; break; \ case(HEADER_TYPE_SCTP): num = 13; break; \ case(HEADER_TYPE_DCCP): num = 14; break; \ case(HEADER_TYPE_USER_DEFINED_L4): num = 15; break; \ case(HEADER_TYPE_USER_DEFINED_SHIM1): \ case(HEADER_TYPE_USER_DEFINED_SHIM2): \ case(HEADER_TYPE_MACSEC): \ num = NO_HDR_NUM; break; \ default: \ REPORT_ERROR(MAJOR, E_NOT_SUPPORTED, ("Unsupported header for parser"));\ num = ILLEGAL_HDR_NUM; break; \ } /***********************************************************************/ /* Policer defines */ /***********************************************************************/ #define FM_PCD_PLCR_PAR_GO 0x80000000 #define FM_PCD_PLCR_PAR_PWSEL_MASK 0x0000FFFF #define FM_PCD_PLCR_PAR_R 0x40000000 /* shifts */ #define FM_PCD_PLCR_PAR_PNUM_SHIFT 16 /***********************************************************************/ /* Keygen defines */ /***********************************************************************/ /* maskes */ #define KG_SCH_PP_SHIFT_HIGH 0x80000000 #define KG_SCH_PP_NO_GEN 0x10000000 #define KG_SCH_PP_SHIFT_LOW 0x0000F000 #define KG_SCH_MODE_NIA_PLCR 0x40000000 #define KG_SCH_GEN_EXTRACT_TYPE 0x00008000 #define KG_SCH_BITMASK_MASK 0x000000FF #define KG_SCH_GEN_VALID 0x80000000 #define KG_SCH_GEN_MASK 0x00FF0000 #define FM_PCD_KG_KGAR_ERR 0x20000000 #define FM_PCD_KG_KGAR_SEL_CLS_PLAN_ENTRY 0x01000000 #define FM_PCD_KG_KGAR_SEL_PORT_ENTRY 0x02000000 #define FM_PCD_KG_KGAR_SEL_PORT_WSEL_SP 0x00008000 #define FM_PCD_KG_KGAR_SEL_PORT_WSEL_CPP 0x00004000 #define FM_PCD_KG_KGAR_WSEL_MASK 0x0000FF00 #define KG_SCH_HASH_CONFIG_NO_FQID 0x80000000 #define KG_SCH_HASH_CONFIG_SYM 0x40000000 #define FM_PCD_KG_KGAR_GO 0x80000000 #define FM_PCD_KG_KGAR_READ 0x40000000 #define FM_PCD_KG_KGAR_WRITE 0x00000000 #define FM_PCD_KG_KGAR_SEL_SCHEME_ENTRY 0x00000000 #define FM_PCD_KG_KGAR_SCHEME_WSEL_UPDATE_CNT 0x00008000 typedef uint32_t t_KnownFieldsMasks; #define KG_SCH_KN_PORT_ID 0x80000000 #define KG_SCH_KN_MACDST 0x40000000 #define KG_SCH_KN_MACSRC 0x20000000 #define KG_SCH_KN_TCI1 0x10000000 #define KG_SCH_KN_TCI2 0x08000000 #define KG_SCH_KN_ETYPE 0x04000000 #define KG_SCH_KN_PPPSID 0x02000000 #define KG_SCH_KN_PPPID 0x01000000 #define KG_SCH_KN_MPLS1 0x00800000 #define KG_SCH_KN_MPLS2 0x00400000 #define KG_SCH_KN_MPLS_LAST 0x00200000 #define KG_SCH_KN_IPSRC1 0x00100000 #define KG_SCH_KN_IPDST1 0x00080000 #define KG_SCH_KN_PTYPE1 0x00040000 #define KG_SCH_KN_IPTOS_TC1 0x00020000 #define KG_SCH_KN_IPV6FL1 0x00010000 #define KG_SCH_KN_IPSRC2 0x00008000 #define KG_SCH_KN_IPDST2 0x00004000 #define KG_SCH_KN_PTYPE2 0x00002000 #define KG_SCH_KN_IPTOS_TC2 0x00001000 #define KG_SCH_KN_IPV6FL2 0x00000800 #define KG_SCH_KN_GREPTYPE 0x00000400 #define KG_SCH_KN_IPSEC_SPI 0x00000200 #define KG_SCH_KN_IPSEC_NH 0x00000100 #define KG_SCH_KN_L4PSRC 0x00000004 #define KG_SCH_KN_L4PDST 0x00000002 #define KG_SCH_KN_TFLG 0x00000001 typedef uint8_t t_GenericCodes; #define KG_SCH_GEN_SHIM1 0x70 #define KG_SCH_GEN_DEFAULT 0x10 #define KG_SCH_GEN_PARSE_RESULT_N_FQID 0x20 #define KG_SCH_GEN_START_OF_FRM 0x40 #define KG_SCH_GEN_SHIM2 0x71 #define KG_SCH_GEN_IP_PID_NO_V 0x72 #define KG_SCH_GEN_ETH 0x03 #define KG_SCH_GEN_ETH_NO_V 0x73 #define KG_SCH_GEN_SNAP 0x04 #define KG_SCH_GEN_SNAP_NO_V 0x74 #define KG_SCH_GEN_VLAN1 0x05 #define KG_SCH_GEN_VLAN1_NO_V 0x75 #define KG_SCH_GEN_VLAN2 0x06 #define KG_SCH_GEN_VLAN2_NO_V 0x76 #define KG_SCH_GEN_ETH_TYPE 0x07 #define KG_SCH_GEN_ETH_TYPE_NO_V 0x77 #define KG_SCH_GEN_PPP 0x08 #define KG_SCH_GEN_PPP_NO_V 0x78 #define KG_SCH_GEN_MPLS1 0x09 #define KG_SCH_GEN_MPLS2 0x19 #define KG_SCH_GEN_MPLS3 0x29 #define KG_SCH_GEN_MPLS1_NO_V 0x79 #define KG_SCH_GEN_MPLS_LAST 0x0a #define KG_SCH_GEN_MPLS_LAST_NO_V 0x7a #define KG_SCH_GEN_IPV4 0x0b #define KG_SCH_GEN_IPV6 0x1b #define KG_SCH_GEN_L3_NO_V 0x7b #define KG_SCH_GEN_IPV4_TUNNELED 0x0c #define KG_SCH_GEN_IPV6_TUNNELED 0x1c #define KG_SCH_GEN_MIN_ENCAP 0x2c #define KG_SCH_GEN_IP2_NO_V 0x7c #define KG_SCH_GEN_GRE 0x0d #define KG_SCH_GEN_GRE_NO_V 0x7d #define KG_SCH_GEN_TCP 0x0e #define KG_SCH_GEN_UDP 0x1e #define KG_SCH_GEN_IPSEC_AH 0x2e #define KG_SCH_GEN_SCTP 0x3e #define KG_SCH_GEN_DCCP 0x4e #define KG_SCH_GEN_IPSEC_ESP 0x6e #define KG_SCH_GEN_L4_NO_V 0x7e #define KG_SCH_GEN_NEXTHDR 0x7f /* shifts */ #define KG_SCH_PP_SHIFT_HIGH_SHIFT 27 #define KG_SCH_PP_SHIFT_LOW_SHIFT 12 #define KG_SCH_PP_MASK_SHIFT 16 #define KG_SCH_MODE_CCOBASE_SHIFT 24 #define KG_SCH_DEF_MAC_ADDR_SHIFT 30 #define KG_SCH_DEF_TCI_SHIFT 28 #define KG_SCH_DEF_ENET_TYPE_SHIFT 26 #define KG_SCH_DEF_PPP_SESSION_ID_SHIFT 24 #define KG_SCH_DEF_PPP_PROTOCOL_ID_SHIFT 22 #define KG_SCH_DEF_MPLS_LABEL_SHIFT 20 #define KG_SCH_DEF_IP_ADDR_SHIFT 18 #define KG_SCH_DEF_PROTOCOL_TYPE_SHIFT 16 #define KG_SCH_DEF_IP_TOS_TC_SHIFT 14 #define KG_SCH_DEF_IPV6_FLOW_LABEL_SHIFT 12 #define KG_SCH_DEF_IPSEC_SPI_SHIFT 10 #define KG_SCH_DEF_L4_PORT_SHIFT 8 #define KG_SCH_DEF_TCP_FLAG_SHIFT 6 #define KG_SCH_HASH_CONFIG_SHIFT_SHIFT 24 #define KG_SCH_GEN_MASK_SHIFT 16 #define KG_SCH_GEN_HT_SHIFT 8 #define KG_SCH_GEN_SIZE_SHIFT 24 #define KG_SCH_GEN_DEF_SHIFT 29 #define FM_PCD_KG_KGAR_NUM_SHIFT 16 /* others */ #define NUM_OF_SW_DEFAULTS 3 #define MAX_PP_SHIFT 15 #define MAX_KG_SCH_SIZE 16 #define MASK_FOR_GENERIC_BASE_ID 0x20 #define MAX_HASH_SHIFT 40 #define MAX_KG_SCH_FQID_BIT_OFFSET 31 #define MAX_KG_SCH_PP_BIT_OFFSET 15 #define MAX_DIST_FQID_SHIFT 23 #define GET_MASK_SEL_SHIFT(shift,i) \ switch(i) { \ case(0):shift = 26;break; \ case(1):shift = 20;break; \ case(2):shift = 10;break; \ case(3):shift = 4;break; \ default: \ RETURN_ERROR(MAJOR, E_INVALID_VALUE, NO_MSG);\ } #define GET_MASK_OFFSET_SHIFT(shift,i) \ switch(i) { \ case(0):shift = 16;break; \ case(1):shift = 0;break; \ case(2):shift = 28;break; \ case(3):shift = 24;break; \ default: \ RETURN_ERROR(MAJOR, E_INVALID_VALUE, NO_MSG);\ } #define GET_MASK_SHIFT(shift,i) \ switch(i) { \ case(0):shift = 24;break; \ case(1):shift = 16;break; \ case(2):shift = 8;break; \ case(3):shift = 0;break; \ default: \ RETURN_ERROR(MAJOR, E_INVALID_VALUE, NO_MSG);\ } #define FM_PCD_MAX_NUM_OF_OPTIONS(clsPlanEntries) ((clsPlanEntries==256)? 8:((clsPlanEntries==128)? 7: ((clsPlanEntries==64)? 6: ((clsPlanEntries==32)? 5:0)))) typedef struct { uint16_t num; uint8_t hardwarePortId; uint16_t plcrProfilesBase; } t_FmPortPcdInterModulePlcrParams; /**************************************************************************//** @Description A structure for initializing a keygen classification plan group *//***************************************************************************/ typedef struct t_FmPcdKgInterModuleClsPlanGrpParams { uint8_t netEnvId; /* IN */ bool grpExists; /* OUT (unused in FmPcdKgBuildClsPlanGrp)*/ uint8_t clsPlanGrpId; /* OUT */ bool emptyClsPlanGrp; /* OUT */ uint8_t numOfOptions; /* OUT in FmPcdGetSetClsPlanGrpParams IN in FmPcdKgBuildClsPlanGrp*/ protocolOpt_t options[FM_PCD_MAX_NUM_OF_OPTIONS(FM_PCD_MAX_NUM_OF_CLS_PLANS)]; /* OUT in FmPcdGetSetClsPlanGrpParams IN in FmPcdKgBuildClsPlanGrp*/ uint32_t optVectors[FM_PCD_MAX_NUM_OF_OPTIONS(FM_PCD_MAX_NUM_OF_CLS_PLANS)]; /* OUT in FmPcdGetSetClsPlanGrpParams IN in FmPcdKgBuildClsPlanGrp*/ } t_FmPcdKgInterModuleClsPlanGrpParams; typedef struct t_FmInterModulePortRxPoolsParams { uint8_t numOfPools; uint16_t secondLargestBufSize; uint16_t largestBufSize; } t_FmInterModulePortRxPoolsParams; typedef t_Error (t_FmPortGetSetCcParamsCallback) (t_Handle h_FmPort, t_FmPortGetSetCcParams *p_FmPortGetSetCcParams); t_Handle FmPcdGetHcHandle(t_Handle h_FmPcd); uint32_t FmPcdGetSwPrsOffset(t_Handle h_FmPcd, e_NetHeaderType hdr, uint8_t indexPerHdr); uint32_t FmPcdGetLcv(t_Handle h_FmPcd, uint32_t netEnvId, uint8_t hdrNum); uint32_t FmPcdGetMacsecLcv(t_Handle h_FmPcd, uint32_t netEnvId); void FmPcdIncNetEnvOwners(t_Handle h_FmPcd, uint8_t netEnvId); void FmPcdDecNetEnvOwners(t_Handle h_FmPcd, uint8_t netEnvId); void FmPcdPortRegister(t_Handle h_FmPcd, t_Handle h_FmPort, uint8_t hardwarePortId); uint32_t FmPcdLock(t_Handle h_FmPcd); void FmPcdUnlock(t_Handle h_FmPcd, uint32_t intFlags); bool FmPcdNetEnvIsHdrExist(t_Handle h_FmPcd, uint8_t netEnvId, e_NetHeaderType hdr); bool FmPcdIsIpFrag(t_Handle h_FmPcd, uint8_t netEnvId); t_Error FmPcdCcReleaseModifiedDataStructure(t_Handle h_FmPcd, t_List *h_FmPcdOldPointersLst, t_List *h_FmPcdNewPointersLst, uint16_t numOfGoodChanges, t_Handle *h_Params); uint32_t FmPcdCcGetNodeAddrOffset(t_Handle h_FmPcd, t_Handle h_Pointer); t_Error FmPcdCcRemoveKey(t_Handle h_FmPcd, t_Handle h_FmPcdCcNode, uint8_t keyIndex, t_List *h_OldLst, t_List *h_NewLst, t_Handle *h_AdditionalParams); t_Error FmPcdCcAddKey(t_Handle h_FmPcd, t_Handle h_CcNode, uint8_t keyIndex, uint8_t keySize, t_FmPcdCcKeyParams *p_FmPCdCcKeyParams, t_List *h_OldLst, t_List *h_NewLst, t_Handle *h_Params); t_Error FmPcdCcModifyKey(t_Handle h_FmPcd, t_Handle h_CcNode, uint8_t keyIndex, uint8_t keySize, uint8_t *p_Key, uint8_t *p_Mask, t_List *h_OldLst, t_List *h_NewLst, t_Handle *h_AdditionalParams); t_Error FmPcdCcModifyKeyAndNextEngine(t_Handle h_FmPcd, t_Handle h_FmPcdCcNode, uint8_t keyIndex, uint8_t keySize, t_FmPcdCcKeyParams *p_FmPcdCcKeyParams, t_List *h_OldLst, t_List *h_NewLst, t_Handle *h_AdditionalParams); t_Error FmPcdCcModifyMissNextEngineParamNode(t_Handle h_FmPcd,t_Handle h_FmPcdCcNode, t_FmPcdCcNextEngineParams *p_FmPcdCcNextEngineParams,t_List *h_OldPointer, t_List *h_NewPointer,t_Handle *h_AdditionalParams); t_Error FmPcdCcModifyNextEngineParamTree(t_Handle h_FmPcd, t_Handle h_FmPcdCcTree, uint8_t grpId, uint8_t index, t_FmPcdCcNextEngineParams *p_FmPcdCcNextEngineParams, t_List *h_OldLst, t_List *h_NewLst, t_Handle *h_AdditionalParams); t_Error FmPcdCcModiyNextEngineParamNode(t_Handle h_FmPcd,t_Handle h_FmPcdCcNode, uint8_t keyIndex,t_FmPcdCcNextEngineParams *p_FmPcdCcNextEngineParams,t_List *h_OldPointer, t_List *h_NewPointer,t_Handle *h_AdditionalParams); uint32_t FmPcdCcGetNodeAddrOffsetFromNodeInfo(t_Handle h_FmPcd, t_Handle h_Pointer); t_Error FmPcdCcTreeTryLock(t_Handle h_FmPcdCcTree); t_Error FmPcdCcNodeTreeTryLock(t_Handle h_FmPcd,t_Handle h_FmPcdCcNode, t_List *p_List); void FmPcdCcTreeReleaseLock(t_Handle h_FmPcdCcTree); void FmPcdCcNodeTreeReleaseLock(t_List *p_List); t_Handle FmPcdCcTreeGetSavedManipParams(t_Handle h_FmTree, uint8_t manipIndx); void FmPcdCcTreeSetSavedManipParams(t_Handle h_FmTree, t_Handle h_SavedManipParams, uint8_t manipIndx); bool FmPcdKgIsSchemeValidSw(t_Handle h_FmPcd, uint8_t schemeId); uint8_t FmPcdKgGetClsPlanGrpBase(t_Handle h_FmPcd, uint8_t clsPlanGrp); uint16_t FmPcdKgGetClsPlanGrpSize(t_Handle h_FmPcd, uint8_t clsPlanGrp); t_Error FmPcdKgBuildScheme(t_Handle h_FmPcd, t_FmPcdKgSchemeParams *p_Scheme, t_FmPcdKgInterModuleSchemeRegs *p_SchemeRegs); t_Error FmPcdKgBuildClsPlanGrp(t_Handle h_FmPcd, t_FmPcdKgInterModuleClsPlanGrpParams *p_Grp, t_FmPcdKgInterModuleClsPlanSet *p_ClsPlanSet); uint8_t FmPcdKgGetNumOfPartitionSchemes(t_Handle h_FmPcd); uint8_t FmPcdKgGetPhysicalSchemeId(t_Handle h_FmPcd, uint8_t schemeId); uint8_t FmPcdKgGetRelativeSchemeId(t_Handle h_FmPcd, uint8_t schemeId); void FmPcdKgDestroyClsPlanGrp(t_Handle h_FmPcd, uint8_t grpId); void FmPcdKgValidateSchemeSw(t_Handle h_FmPcd, uint8_t schemeId); void FmPcdKgInvalidateSchemeSw(t_Handle h_FmPcd, uint8_t schemeId); t_Error FmPcdKgCheckInvalidateSchemeSw(t_Handle h_FmPcd, uint8_t schemeId); t_Error FmPcdKgBuildBindPortToSchemes(t_Handle h_FmPcd , t_FmPcdKgInterModuleBindPortToSchemes *p_BindPortToSchemes, uint32_t *p_SpReg, bool add); void FmPcdKgIncSchemeOwners(t_Handle h_FmPcd , t_FmPcdKgInterModuleBindPortToSchemes *p_BindPort); void FmPcdKgDecSchemeOwners(t_Handle h_FmPcd , t_FmPcdKgInterModuleBindPortToSchemes *p_BindPort); bool FmPcdKgIsDriverClsPlan(t_Handle h_FmPcd); bool FmPcdKgHwSchemeIsValid(uint32_t schemeModeReg); uint32_t FmPcdKgBuildCppReg(t_Handle h_FmPcd, uint8_t clsPlanGrpId); uint32_t FmPcdKgBuildWriteSchemeActionReg(uint8_t schemeId, bool updateCounter); uint32_t FmPcdKgBuildReadSchemeActionReg(uint8_t schemeId); uint32_t FmPcdKgBuildWriteClsPlanBlockActionReg(uint8_t grpId); uint32_t FmPcdKgBuildReadClsPlanBlockActionReg(uint8_t grpId); uint32_t FmPcdKgBuildWritePortSchemeBindActionReg(uint8_t hardwarePortId); uint32_t FmPcdKgBuildReadPortSchemeBindActionReg(uint8_t hardwarePortId); uint32_t FmPcdKgBuildWritePortClsPlanBindActionReg(uint8_t hardwarePortId); uint8_t FmPcdKgGetSchemeSwId(t_Handle h_FmPcd, uint8_t schemeHwId); t_Error FmPcdKgSchemeTryLock(t_Handle h_FmPcd, uint8_t schemeId, bool intr); void FmPcdKgReleaseSchemeLock(t_Handle h_FmPcd, uint8_t schemeId); void FmPcdKgUpatePointedOwner(t_Handle h_FmPcd, uint8_t schemeId, bool add); t_Error FmPcdKgBindPortToSchemes(t_Handle h_FmPcd , t_FmPcdKgInterModuleBindPortToSchemes *p_SchemeBind); t_Error FmPcdKgUnbindPortToSchemes(t_Handle h_FmPcd , t_FmPcdKgInterModuleBindPortToSchemes *p_SchemeBind); uint32_t FmPcdKgGetRequiredAction(t_Handle h_FmPcd, uint8_t schemeId); uint32_t FmPcdKgGetPointedOwners(t_Handle h_FmPcd, uint8_t schemeId); e_FmPcdDoneAction FmPcdKgGetDoneAction(t_Handle h_FmPcd, uint8_t schemeId); e_FmPcdEngine FmPcdKgGetNextEngine(t_Handle h_FmPcd, uint8_t schemeId); void FmPcdKgUpdateRequiredAction(t_Handle h_FmPcd, uint8_t schemeId, uint32_t requiredAction); bool FmPcdKgIsDirectPlcr(t_Handle h_FmPcd, uint8_t schemeId); bool FmPcdKgIsDistrOnPlcrProfile(t_Handle h_FmPcd, uint8_t schemeId); uint16_t FmPcdKgGetRelativeProfileId(t_Handle h_FmPcd, uint8_t schemeId); /* FM-PCD parser API routines */ t_Error FmPcdPrsIncludePortInStatistics(t_Handle p_FmPcd, uint8_t hardwarePortId, bool include); /* FM-PCD policer API routines */ t_Error FmPcdPlcrAllocProfiles(t_Handle h_FmPcd, uint8_t hardwarePortId, uint16_t numOfProfiles); t_Error FmPcdPlcrFreeProfiles(t_Handle h_FmPcd, uint8_t hardwarePortId); bool FmPcdPlcrIsProfileValid(t_Handle h_FmPcd, uint16_t absoluteProfileId); uint16_t FmPcdPlcrGetPortProfilesBase(t_Handle h_FmPcd, uint8_t hardwarePortId); uint16_t FmPcdPlcrGetPortNumOfProfiles(t_Handle h_FmPcd, uint8_t hardwarePortId); uint32_t FmPcdPlcrBuildWritePlcrActionRegs(uint16_t absoluteProfileId); uint32_t FmPcdPlcrBuildCounterProfileReg(e_FmPcdPlcrProfileCounters counter); uint32_t FmPcdPlcrBuildWritePlcrActionReg(uint16_t absoluteProfileId); uint32_t FmPcdPlcrBuildReadPlcrActionReg(uint16_t absoluteProfileId); t_Error FmPcdPlcrBuildProfile(t_Handle h_FmPcd, t_FmPcdPlcrProfileParams *p_Profile, t_FmPcdPlcrInterModuleProfileRegs *p_PlcrRegs); t_Error FmPcdPlcrGetAbsoluteProfileId(t_Handle h_FmPcd, e_FmPcdProfileTypeSelection profileType, t_Handle h_FmPort, uint16_t relativeProfile, uint16_t *p_AbsoluteId); void FmPcdPlcrInvalidateProfileSw(t_Handle h_FmPcd, uint16_t absoluteProfileId); void FmPcdPlcrValidateProfileSw(t_Handle h_FmPcd, uint16_t absoluteProfileId); bool FmPcdPlcrHwProfileIsValid(uint32_t profileModeReg); t_Error FmPcdPlcrProfileTryLock(t_Handle h_FmPcd, uint16_t profileId, bool intr); void FmPcdPlcrReleaseProfileLock(t_Handle h_FmPcd, uint16_t profileId); uint32_t FmPcdPlcrGetRequiredAction(t_Handle h_FmPcd, uint16_t absoluteProfileId); uint32_t FmPcdPlcrGetPointedOwners(t_Handle h_FmPcd, uint16_t absoluteProfileId); void FmPcdPlcrUpatePointedOwner(t_Handle h_FmPcd, uint16_t absoluteProfileId, bool add); uint32_t FmPcdPlcrBuildNiaProfileReg(bool green, bool yellow, bool red); void FmPcdPlcrUpdateRequiredAction(t_Handle h_FmPcd, uint16_t absoluteProfileId, uint32_t requiredAction); /* FM-PCD Coarse-Classification API routines */ uint8_t FmPcdCcGetParseCode(t_Handle h_CcNode); uint8_t FmPcdCcGetOffset(t_Handle h_CcNode); t_Error FmPcdManipUpdate(t_Handle h_FmPcd, t_Handle h_FmPort, t_Handle h_Manip, t_Handle h_Ad, bool validate, int level, t_Handle h_FmTree, bool modify); t_Error FmPortGetSetCcParams(t_Handle h_FmPort, t_FmPortGetSetCcParams *p_FmPortGetSetCcParams); uint32_t FmPcdManipGetRequiredAction (t_Handle h_Manip); t_Error FmPcdCcBindTree(t_Handle h_FmPcd, t_Handle h_CcTree, uint32_t *p_Offset,t_Handle h_FmPort); t_Error FmPcdCcUnbindTree(t_Handle h_FmPcd, t_Handle h_CcTree); t_Error FmPcdPlcrCcGetSetParams(t_Handle h_FmPcd, uint16_t profileIndx,uint32_t requiredAction); t_Error FmPcdKgCcGetSetParams(t_Handle h_FmPcd, t_Handle h_Scheme, uint32_t requiredAction); uint8_t FmPortGetNetEnvId(t_Handle h_FmPort); uint8_t FmPortGetHardwarePortId(t_Handle h_FmPort); uint32_t FmPortGetPcdEngines(t_Handle h_FmPort); void FmPortPcdKgSwUnbindClsPlanGrp (t_Handle h_FmPort); t_Error FmPortAttachPCD(t_Handle h_FmPort); t_Error FmPcdKgSetOrBindToClsPlanGrp(t_Handle h_FmPcd, uint8_t hardwarePortId, uint8_t netEnvId, protocolOpt_t *p_OptArray, uint8_t *p_ClsPlanGrpId, bool *p_IsEmptyClsPlanGrp); t_Error FmPcdKgDeleteOrUnbindPortToClsPlanGrp(t_Handle h_FmPcd, uint8_t hardwarePortId, uint8_t clsPlanGrpId); /**************************************************************************//** @Function FmRegisterIntr @Description Used to register an inter-module event handler to be processed by FM @Param[in] h_Fm A handle to an FM Module. @Param[in] mod The module that causes the event @Param[in] modId Module id - if more than 1 instansiation of this mode exists,0 otherwise. @Param[in] intrType Interrupt type (error/normal) selection. @Param[in] f_Isr The interrupt service routine. @Param[in] h_Arg Argument to be passed to f_Isr. @Return None. *//***************************************************************************/ void FmRegisterIntr(t_Handle h_Fm, e_FmEventModules mod, uint8_t modId, e_FmIntrType intrType, void (*f_Isr) (t_Handle h_Arg), t_Handle h_Arg); /**************************************************************************//** @Function FmUnregisterIntr @Description Used to un-register an inter-module event handler that was processed by FM @Param[in] h_Fm A handle to an FM Module. @Param[in] mod The module that causes the event @Param[in] modId Module id - if more than 1 instansiation of this mode exists,0 otherwise. @Param[in] intrType Interrupt type (error/normal) selection. @Return None. *//***************************************************************************/ void FmUnregisterIntr(t_Handle h_Fm, e_FmEventModules mod, uint8_t modId, e_FmIntrType intrType); /**************************************************************************//** @Function FmRegisterFmCtlIntr @Description Used to register to one of the fmCtl events in the FM module @Param[in] h_Fm A handle to an FM Module. @Param[in] eventRegId FmCtl event id (0-7). @Param[in] f_Isr The interrupt service routine. @Return E_OK on success; Error code otherwise. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ void FmRegisterFmCtlIntr(t_Handle h_Fm, uint8_t eventRegId, void (*f_Isr) (t_Handle h_Fm, uint32_t event)); /**************************************************************************//** @Description enum for defining MAC types *//***************************************************************************/ typedef enum e_FmMacType { e_FM_MAC_10G = 0, /**< 10G MAC */ e_FM_MAC_1G /**< 1G MAC */ } e_FmMacType; /**************************************************************************//** @Description Structure for port-FM communication during FM_PORT_Init. Fields commented 'IN' are passed by the port module to be used by the FM module. Fields commented 'OUT' will be filled by FM before returning to port. Some fields are optional (depending on configuration) and will be analized by the port and FM modules accordingly. *//***************************************************************************/ typedef struct t_FmInterModulePortInitParams { uint8_t hardwarePortId; /**< IN. port Id */ e_FmPortType portType; /**< IN. Port type */ bool independentMode; /**< IN. TRUE if FM Port operates in independent mode */ uint16_t liodnOffset; /**< IN. Port's requested resource */ uint8_t numOfTasks; /**< IN. Port's requested resource */ uint8_t numOfExtraTasks; /**< IN. Port's requested resource */ uint8_t numOfOpenDmas; /**< IN. Port's requested resource */ uint8_t numOfExtraOpenDmas; /**< IN. Port's requested resource */ uint32_t sizeOfFifo; /**< IN. Port's requested resource */ uint32_t extraSizeOfFifo; /**< IN. Port's requested resource */ uint8_t deqPipelineDepth; /**< IN. Port's requested resource */ uint16_t liodnBase; /**< IN. Irrelevant for P4080 rev 1. LIODN base for this port, to be used together with LIODN offset. */ t_FmPhysAddr fmMuramPhysBaseAddr;/**< OUT. FM-MURAM physical address*/ } t_FmInterModulePortInitParams; /**************************************************************************//** @Description Structure for port-FM communication during FM_PORT_Free. *//***************************************************************************/ typedef struct t_FmInterModulePortFreeParams { uint8_t hardwarePortId; /**< IN. port Id */ e_FmPortType portType; /**< IN. Port type */ #ifdef FM_QMI_DEQ_OPTIONS_SUPPORT uint8_t deqPipelineDepth; /**< IN. Port's requested resource */ #endif /* FM_QMI_DEQ_OPTIONS_SUPPORT */ } t_FmInterModulePortFreeParams; /**************************************************************************//** @Function FmGetPcdPrsBaseAddr @Description Get the base address of the Parser from the FM module @Param[in] h_Fm A handle to an FM Module. @Return Base address. *//***************************************************************************/ uintptr_t FmGetPcdPrsBaseAddr(t_Handle h_Fm); /**************************************************************************//** @Function FmGetPcdKgBaseAddr @Description Get the base address of the Keygen from the FM module @Param[in] h_Fm A handle to an FM Module. @Return Base address. *//***************************************************************************/ uintptr_t FmGetPcdKgBaseAddr(t_Handle h_Fm); /**************************************************************************//** @Function FmGetPcdPlcrBaseAddr @Description Get the base address of the Policer from the FM module @Param[in] h_Fm A handle to an FM Module. @Return Base address. *//***************************************************************************/ uintptr_t FmGetPcdPlcrBaseAddr(t_Handle h_Fm); /**************************************************************************//** @Function FmGetMuramHandle @Description Get the handle of the MURAM from the FM module @Param[in] h_Fm A handle to an FM Module. @Return MURAM module handle. *//***************************************************************************/ t_Handle FmGetMuramHandle(t_Handle h_Fm); /**************************************************************************//** @Function FmGetPhysicalMuramBase @Description Get the physical base address of the MURAM from the FM module @Param[in] h_Fm A handle to an FM Module. @Param[in] fmPhysAddr Physical MURAM base @Return Physical base address. *//***************************************************************************/ void FmGetPhysicalMuramBase(t_Handle h_Fm, t_FmPhysAddr *fmPhysAddr); /**************************************************************************//** @Function FmGetTimeStampScale @Description Used internally by other modules in order to get the timeStamp period as requested by the application. @Param[in] h_Fm A handle to an FM Module. @Return TimeStamp period in nanoseconds. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ uint32_t FmGetTimeStampScale(t_Handle h_Fm); /**************************************************************************//** @Function FmResumeStalledPort @Description Used internally by FM port to release a stalled port. @Param[in] h_Fm A handle to an FM Module. @Param[in] hardwarePortId HW port id. @Return E_OK on success; Error code otherwise. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ t_Error FmResumeStalledPort(t_Handle h_Fm, uint8_t hardwarePortId); /**************************************************************************//** @Function FmIsPortStalled @Description Used internally by FM port to read the port's status. @Param[in] h_Fm A handle to an FM Module. @Param[in] hardwarePortId HW port id. @Param[in] p_IsStalled A pointer to the boolean port stalled state @Return E_OK on success; Error code otherwise. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ t_Error FmIsPortStalled(t_Handle h_Fm, uint8_t hardwarePortId, bool *p_IsStalled); /**************************************************************************//** @Function FmResetMac @Description Used by MAC driver to reset the MAC registers @Param[in] h_Fm A handle to an FM Module. @Param[in] type MAC type. @Param[in] macId MAC id - according to type. @Return E_OK on success; Error code otherwise. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ t_Error FmResetMac(t_Handle h_Fm, e_FmMacType type, uint8_t macId); /**************************************************************************//** @Function FmGetClockFreq @Description Used by MAC driver to get the FM clock frequency @Param[in] h_Fm A handle to an FM Module. @Return clock-freq on success; 0 otherwise. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ uint16_t FmGetClockFreq(t_Handle h_Fm); /**************************************************************************//** @Function FmGetId @Description Used by PCD driver to read rhe FM id @Param[in] h_Fm A handle to an FM Module. @Return E_OK on success; Error code otherwise. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ uint8_t FmGetId(t_Handle h_Fm); /**************************************************************************//** @Function FmGetSetPortParams @Description Used by FM-PORT driver to pass and receive parameters between PORT and FM modules. @Param[in] h_Fm A handle to an FM Module. @Param[in,out] p_PortParams A structure of FM Port parameters. @Return E_OK on success; Error code otherwise. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ t_Error FmGetSetPortParams(t_Handle h_Fm,t_FmInterModulePortInitParams *p_PortParams); /**************************************************************************//** @Function FmFreePortParams @Description Used by FM-PORT driver to free port's resources within the FM. @Param[in] h_Fm A handle to an FM Module. @Param[in,out] p_PortParams A structure of FM Port parameters. @Return None. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ void FmFreePortParams(t_Handle h_Fm,t_FmInterModulePortFreeParams *p_PortParams); /**************************************************************************//** @Function FmSetPortToWorkWithOneRiscOnly @Description Used by FM-PORT driver to pass parameter between PORT and FM modules for working with number of RISC.. @Param[in] h_Fm A handle to an FM Module. @Param[in,out] p_PortParams A structure of FM Port parameters. @Return None. @Cautions Allowed only following FM_Init(). *//***************************************************************************/ t_Error FmSetNumOfRiscsPerPort(t_Handle h_Fm, uint8_t hardwarePortId, uint8_t numOfFmanCtrls); void FmRegisterPcd(t_Handle h_Fm, t_Handle h_FmPcd); void FmUnregisterPcd(t_Handle h_Fm); t_Handle FmGetPcdHandle(t_Handle h_Fm); bool FmRamsEccIsExternalCtl(t_Handle h_Fm); t_Error FmEnableRamsEcc(t_Handle h_Fm); t_Error FmDisableRamsEcc(t_Handle h_Fm); void FmGetRevision(t_Handle h_Fm, t_FmRevisionInfo *p_FmRevisionInfo); t_Error FmAllocFmanCtrlEventReg(t_Handle h_Fm, uint8_t *p_EventId); void FmFreeFmanCtrlEventReg(t_Handle h_Fm, uint8_t eventId); void FmSetFmanCtrlIntr(t_Handle h_Fm, uint8_t eventRegId, uint32_t enableEvents); uint32_t FmGetFmanCtrlIntr(t_Handle h_Fm, uint8_t eventRegId); void FmRegisterFmanCtrlIntr(t_Handle h_Fm, uint8_t eventRegId, void (*f_Isr) (t_Handle h_Fm, uint32_t event), t_Handle h_Arg); void FmUnregisterFmanCtrlIntr(t_Handle h_Fm, uint8_t eventRegId); t_Error FmSetMacMaxFrame(t_Handle h_Fm, e_FmMacType type, uint8_t macId, uint16_t mtu); bool FmIsMaster(t_Handle h_Fm); uint8_t FmGetGuestId(t_Handle h_Fm); #ifdef FM_TX_ECC_FRMS_ERRATA_10GMAC_A004 t_Error Fm10GTxEccWorkaround(t_Handle h_Fm, uint8_t macId); #endif /* FM_TX_ECC_FRMS_ERRATA_10GMAC_A004 */ void FmMuramClear(t_Handle h_FmMuram); t_Error FmSetNumOfOpenDmas(t_Handle h_Fm, uint8_t hardwarePortId, uint8_t numOfOpenDmas, uint8_t numOfExtraOpenDmas, bool initialConfig); t_Error FmSetNumOfTasks(t_Handle h_Fm, uint8_t hardwarePortId, uint8_t numOfTasks, uint8_t numOfExtraTasks, bool initialConfig); t_Error FmSetSizeOfFifo(t_Handle h_Fm, uint8_t hardwarePortId, e_FmPortType portType, bool independentMode, uint32_t *p_SizeOfFifo, uint32_t extraSizeOfFifo, uint8_t deqPipelineDepth, t_FmInterModulePortRxPoolsParams *p_RxPoolsParams, bool initialConfig); #endif /* __FM_COMMON_H */