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[/] [openrisc/] [trunk/] [orpsocv2/] [bench/] [sysc/] [include/] [DebugUnitSC.h] - Rev 702
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// ---------------------------------------------------------------------------- // SystemC OpenRISC 1000 Debug Unit: definition // Copyright (C) 2008 Embecosm Limited <info@embecosm.com> // Contributor Jeremy Bennett <jeremy.bennett@embecosm.com> // This file is part of the GDB interface to the cycle accurate model of the // OpenRISC 1000 based system-on-chip, ORPSoC, built using Verilator. // This program is free software: you can redistribute it and/or modify it // under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or (at your // option) any later version. // This program is distributed in the hope that it will be useful, but WITHOUT // ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public // License for more details. // You should have received a copy of the GNU Lesser General Public License // along with this program. If not, see <http://www.gnu.org/licenses/>. // ---------------------------------------------------------------------------- // $Id$ #ifndef DEBUG_UNIT_SC__H #define DEBUG_UNIT_SC__H // Define if no cache is wanted #define NOCACHE #include <stdint.h> #include "systemc" #include "JtagSC_includes.h" #include "OrpsocAccess.h" #include "SprCache.h" #include "MemCache.h" //----------------------------------------------------------------------------- //! Module modeling the OpenRISC 1000 Debug Unit //! Provides a high level interface to the GDB Server module with functions to //! access SPRs, Wishbone memory and CPU control. //! Provides a low level interface to the Embecosm SystemC JTAG interface, //! queueing requests to read and write JTAG registers. //----------------------------------------------------------------------------- class DebugUnitSC:public sc_core::sc_module { public: // Constructor and destructor DebugUnitSC(sc_core::sc_module_name name, sc_core::sc_fifo < TapAction * >*_tapActionQueue); ~DebugUnitSC(); // Reset function for the debug unit void resetDebugUnit(); // Functions to control and report on the CPU void reset(); void stall(); void unstall(); bool isStalled(); // Functions to access SPRs uint32_t readSpr(uint16_t sprNum); void writeSpr(uint16_t sprNum, uint32_t value); void andSpr(uint16_t sprNum, uint32_t value); void orSpr(uint16_t sprNum, uint32_t value); // Functions to access memory uint32_t readMem32(uint32_t addr); bool writeMem32(uint32_t addr, uint32_t value); uint8_t readMem8(uint32_t addr); bool writeMem8(uint32_t addr, uint8_t value); private: // JTAG instructions static const uint32_t CHAIN_SELECT_IR = 0x3; //!< Chain Select instruction static const uint32_t DEBUG_IR = 0x8; //!< Debug instruction //! JTAG instruction register length. There is no CRC for this register. static const int JTAG_IR_LEN = 4; //!< JTAG instr reg length // DEBUG UNIT CHAIN data register fields static const int DUSEL_DR_LEN = 73; //!< total DUSEL DR size static const int DUSEL_SEL_OFF = 0; //!< start of select field static const int DUSEL_SEL_LEN = 1; //!< length of select field static const int DUSEL_OPCODE_OFF = DUSEL_SEL_OFF + DUSEL_SEL_LEN; //!< start of opcode field static const int DUSEL_OPCODE_LEN = 4; //!< length of opcode field static const int DUSEL_CRC_OFF = DUSEL_OPCODE_OFF + DUSEL_OPCODE_LEN; //!< start of CRC field static const int DUSEL_CRC_LEN = 32; //!< length of CRC field static const int DUSEL_RESP_STATUS_OFF = DUSEL_CRC_OFF + DUSEL_CRC_LEN; static const int DUSEL_RESP_STATUS_LEN = 4; static const int DUSEL_RESP_CRC_OFF = DUSEL_RESP_STATUS_OFF + DUSEL_RESP_STATUS_LEN; static const int DUSEL_RESP_CRC_LEN = 32; static const uint32_t DBG_CRC32_POLY = 0x04c11db7; // OpenRISC 1000 scan chains (values in DUSEL data register field) static const int OR1K_SC_UNDEF = -1; //!< Undefined OR1K scan chain static const int OR1K_SC_WISHBONE = 0; //!< for memory access static const int OR1K_SC_CPU0 = 1; //!< for access to CPU0 static const int OR1K_SC_CPU1 = 2; //!< for access to CPU1 // JTAG RISC_DEBUG (for accessing SPR) data register fields static const int RISC_DEBUG_DR_LEN = 74; //!< Total RISC_DEBUG DR size static const int RISC_DEBUG_ADDR_OFF = 0; //!< start of address field static const int RISC_DEBUG_ADDR_LEN = 32; //!< length of address field static const int RISC_DEBUG_RW_OFF = 32; //!< start of read/write field static const int RISC_DEBUG_RW_LEN = 1; //!< length of read/write field static const int RISC_DEBUG_DATA_OFF = 33; //!< start of data field static const int RISC_DEBUG_DATA_LEN = 32; //!< length of data field static const int RISC_DEBUG_CRC_OFF = 65; //!< start of CRC field static const int RISC_DEBUG_CRC_LEN = 8; //!< length of CRC field static const int RISC_DEBUG_SPARE_OFF = 73; //!< start of spare bits static const int RISC_DEBUG_SPARE_LEN = 1; //!< length of spare bit field // JTAG REGISTER (for controlling the CPU) data register fields static const int REGISTER_DR_LEN = 47; //!< Total REGISTER DR size static const int REGISTER_ADDR_OFF = 0; //!< start of address field static const int REGISTER_ADDR_LEN = 5; //!< length of address field static const int REGISTER_RW_OFF = 5; //!< start of read/write field static const int REGISTER_RW_LEN = 1; //!< length of read/write field static const int REGISTER_DATA_OFF = 6; //!< start of data field static const int REGISTER_DATA_LEN = 32; //!< length of data field static const int REGISTER_CRC_OFF = 38; //!< start of CRC field static const int REGISTER_CRC_LEN = 8; //!< length of CRC field static const int REGISTER_SPARE_OFF = 46; //!< start of spare bits static const int REGISTER_SPARE_LEN = 1; //!< length of spare bit field // Register addresses for the REGISTER scan chain static const uint8_t OR1K_RSC_RISCOP = 0x04; //!< Used to reset/stall CPU // Bits for the RISCOP register static const uint32_t RISCOP_RESET = 0x00000001; //!< Reset the CPU static const uint32_t RISCOP_STALL = 0x00000002; //!< Stall the CPU // JTAG WISHBONE (for accessing SPR) data register fields static const int WISHBONE_DR_LEN = 74; //!< Total WISHBONE DR size static const int WISHBONE_ADDR_OFF = 0; //!< start of address field static const int WISHBONE_ADDR_LEN = 32; //!< length of address field static const int WISHBONE_RW_OFF = 32; //!< start of read/write field static const int WISHBONE_RW_LEN = 1; //!< length of read/write field static const int WISHBONE_DATA_OFF = 33; //!< start of data field static const int WISHBONE_DATA_LEN = 32; //!< length of data field static const int WISHBONE_CRC_OFF = 65; //!< start of CRC field static const int WISHBONE_CRC_LEN = 8; //!< length of CRC field static const int WISHBONE_SPARE_OFF = 73; //!< start of spare bits static const int WISHBONE_SPARE_LEN = 1; //!< length of spare bit field //! The NPC is special, so we need to know about it static const int SPR_NPC = 0x10; //! The JTAG fifo we queue on sc_core::sc_fifo < TapAction * >*tapActionQueue; //! The processor stall state. When stalled we can use cacheing on //! reads/writes of memory and SPRs. enum { UNKNOWN, STALLED, } stallState; //! The currently selected scan chain int currentScanChain; #ifdef NOCACHE //! Even if no cached, we need to cache the NPC uint32_t npcCachedValue; //! Cached NPC is valid bool npcCacheIsValid; #else //! The SPR cache SprCache *sprCache; //! The memory cache MemCache *memCache; #endif // Functions to control the CPU uint32_t readRiscop(); void writeRiscop(uint32_t value); // Or1k JTAG actions void selectDebugModule(int chain); uint32_t readJtagReg(uint32_t addr); uint32_t readJtagReg1(uint32_t addr, int bitSizeNoCrc); uint32_t readJtagReg1(uint64_t * dRegArray, uint32_t addr, int bitSizeNoCrc); void writeJtagReg(uint32_t addr, uint32_t data); // Utilities to pack and unpack bits to/from data registers. void clearBits(uint64_t regArray[], int regBits); void packBits(uint64_t regArray[], int fieldOffset, int fieldBits, uint64_t fieldVal); uint64_t unpackBits(uint64_t regArray[], int fieldOffset, int fieldBits); // Utility to compute CRC-8 the OpenRISC way. uint8_t crc8(uint64_t dataArray[], int size); // Utility to compute CRC-32 for the debug unit uint32_t crc32(uint64_t dataArray[], int size, int offset); // Functions to bitreverse values uint32_t bit_reverse_swar_2(uint32_t x); uint32_t bit_reverse_swar_4(uint32_t x); uint32_t bit_reverse_swar_8(uint32_t x); uint32_t bit_reverse_swar_16(uint32_t x); uint32_t bit_reverse_swar_32(uint32_t x); #define BITREV(x,y) bit_reverse_data(x,y) uint32_t bit_reverse_data(uint32_t x, int length); }; // DebugUnitSC () #endif // DEBUG_UNIT_SC__H
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