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// ---------------------------------------------------------------------------- // SystemC OpenRISC 1000 Debug Unit: implementation // Copyright (C) 2008 Embecosm Limited <info@embecosm.com> // Copyright (C) 2009 ORSoC // Contributor Jeremy Bennett <jeremy.bennett@embecosm.com> // Contributor Julius Baxter <julius@orsoc.se> // 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/>. // ---------------------------------------------------------------------------- // $Id$ #include <iostream> #include <iomanip> #include "DebugUnitSC.h" #include "Utils.h" using sc_core::sc_event; using sc_core::sc_fifo; using sc_core::sc_module_name; //----------------------------------------------------------------------------- //! Constructor for the Debug Unit //! This module is entirely subservient to the GDB server. It has no SystemC //! processes of its own. It provides services via calls to its API. //! The current scan chain is marked as undefined, and the current JTAG scan //! chain is maked as undefined. //! Caches for SPR and memory access are initialized. //! This makes use of the Embecosm cycle accurate SystemC JTAG interface. //! @see Embecosm Application Note 5 "Using JTAG with SystemC: Implementation //! of a Cycle Accurate Interface" //! (http://www.embecosm.com/download/ean5.html) //! @param[in] name Name of this module, passed to the parent //! constructor. //! @param[in] _tapActionQueue Pointer to fifo of actions to be performed by //! the JTAG interface //----------------------------------------------------------------------------- DebugUnitSC::DebugUnitSC (sc_module_name name, sc_fifo<TapAction *> *_tapActionQueue) : sc_module (name), tapActionQueue (_tapActionQueue), stallState (UNKNOWN), currentScanChain (OR1K_SC_UNDEF) { #ifdef NOCACHE npcCacheIsValid = false; // Always cache NPC #else sprCache = new SprCache (); memCache = new MemCache (); #endif } // DebugUnitSC () //----------------------------------------------------------------------------- //! Destructor //! Free up data structures //----------------------------------------------------------------------------- DebugUnitSC::~DebugUnitSC () { #ifndef NOCACHE delete memCache; delete sprCache; #endif } // ~DebugUnitSC //----------------------------------------------------------------------------- //! Reset the Debug Unit //! This is just a reset of the JTAG. It is quite possible to reset the debug //! unit without resetting the whole target. //! @note Must be called from a SystemC thread, because of the use of wait() //----------------------------------------------------------------------------- void DebugUnitSC::resetDebugUnit () { sc_event *done = new sc_event(); TapActionReset *resetAction; // Create and queue the reset action and wait for it to complete resetAction = new TapActionReset (done); tapActionQueue->write (resetAction); wait (*done); delete resetAction; delete done; } // resetDebugUnit () //----------------------------------------------------------------------------- //! Reset the processor //! Read the RISCOP register, OR in the reset bit and write it back. //! After reset, the processor is known to be unstalled. //----------------------------------------------------------------------------- void DebugUnitSC::reset () { writeRiscop (readRiscop () | RISCOP_RESET); stallState = UNKNOWN; } // reset () //----------------------------------------------------------------------------- //! Stall the processor //! Read the RISCOP register, OR in the stall bit and write it back. //----------------------------------------------------------------------------- void DebugUnitSC::stall () { writeRiscop (/*readRiscop () |*/ RISCOP_STALL); stallState = STALLED; } // stall () //----------------------------------------------------------------------------- //! Unstall the processor //! Read the RISCOP register, AND out the stall bit and write it back. After //! this the NPC cache will be invalid. //! @note Don't be tempted to read back for confirmation. Single stepping //! will already have stalled the processor again! //----------------------------------------------------------------------------- void DebugUnitSC::unstall () { writeRiscop (/*readRiscop () & ~RISCOP_STALL*/ 0); stallState = UNKNOWN; #ifdef NOCACHE npcCacheIsValid = false; // Always cache NPC #else // Clear the caches sprCache->clear (); memCache->clear (); #endif } // unstall () //----------------------------------------------------------------------------- //! Report if the processor is stalled. //! A stalled processor cannot spontaneously "unstall", so if the stallState //! flag is STALLED, that value is returned. Otherwise the target is //! interrogated to determine the status. //! @return TRUE if the processor is known to be stalled //----------------------------------------------------------------------------- bool DebugUnitSC::isStalled () { if (STALLED == stallState) { return true; } uint32_t riscop = readRiscop (); /* For some reason the reset bit is skipped over somewhere, so we should just get riscop = 1 if it's stalled */ //stallState = (RISCOP_STALL == (riscop & RISCOP_STALL)) ? STALLED : UNKNOWN; stallState = riscop ? STALLED : UNKNOWN; return STALLED == stallState; } // isStalled () //----------------------------------------------------------------------------- //! Read the value of an OpenRISC 1000 Special Purpose Register //! First see if we have the value in the cache, and if so return //! it. Otherwise, select the RISC_DEBUG scan chain and read from JTAG, //! storing the result in the cache. //! @param[in] sprNum The SPR to read //! @return The value of the SPR //----------------------------------------------------------------------------- uint32_t DebugUnitSC::readSpr (uint16_t sprNum) { uint32_t cachedValue; #ifdef NOCACHE // Always check NPC cache if ((STALLED == stallState) && (sprNum == SPR_NPC) && npcCacheIsValid) { return npcCachedValue; } #else // Use any cached value if we are stalled. if ((STALLED == stallState) && sprCache->read (sprNum, cachedValue)) { return cachedValue; // Already there, no more to do } #endif // Read the value selectDebugModule (OR1K_SC_CPU0); cachedValue = readJtagReg (sprNum); #ifdef NOCACHE // Always update the NPC cache if ((STALLED == stallState) && (sprNum == SPR_NPC)) { npcCachedValue = cachedValue; npcCacheIsValid = true; } #else // Update the cache if we are stalled if (STALLED == stallState) { sprCache->write (sprNum, cachedValue, sprNum == SPR_NPC); } #endif return cachedValue; } // readSpr () //----------------------------------------------------------------------------- //! Write the value of an OpenRISC 1000 Special Purpose Register //! First look to see if we are stalled and the value is cached. If the value //! has not changed, then we need to no more. Otherwise cache the value prior //! to writing it. //! Select the RISC_DEBUG scan chain and write to JTAG //! @param[in] sprNum The SPR to write //! @param[in] value The value to write //----------------------------------------------------------------------------- void DebugUnitSC::writeSpr (uint16_t sprNum, uint32_t value) { #ifdef NOCACHE // Always cache the NPC if ((STALLED == stallState) && (SPR_NPC == sprNum)) { // Have we already cached this NPC value? if (npcCacheIsValid && (value == npcCachedValue)) { return; } else { npcCachedValue = value; npcCacheIsValid = true; } } #else if (STALLED == stallState) { // Have we already cached this value? uint32_t cachedValue; if (sprCache->read (sprNum, cachedValue) && (value == cachedValue)) { return; // Already there, no more to do } else { sprCache->write (sprNum, value, sprNum == SPR_NPC); } } #endif // Write the SPR selectDebugModule (OR1K_SC_CPU0); writeJtagReg (sprNum, value); } // writeSpr () //----------------------------------------------------------------------------- //! AND the contents of an SPR with a value //! A convenience combination of read and write //! @param[in] sprNum The SPR to write //! @param[in] value The value to AND into the register //----------------------------------------------------------------------------- void DebugUnitSC::andSpr (uint16_t sprNum, uint32_t value) { writeSpr (sprNum, readSpr (sprNum) & value); } // andSpr () //----------------------------------------------------------------------------- //! OR the contents of an SPR with a value //! A convenience combination of read and write //! @param[in] sprNum The SPR to write //! @param[in] value The value to OR into the register //----------------------------------------------------------------------------- void DebugUnitSC::orSpr (uint16_t sprNum, uint32_t value) { writeSpr (sprNum, readSpr (sprNum) | value); } // orSpr () //----------------------------------------------------------------------------- //! Read a 32-bit word from the OpenRISC 1000 memory //! Select the WISHBONE scan chain, then write the register. The data is in //! model endianness and passed on without modification. //! @todo Provide code to check if the read was from a valid address. //! @param[in] addr The address to read from //! @return The 32-bit value read //----------------------------------------------------------------------------- uint32_t DebugUnitSC::readMem32 (uint32_t addr) { uint32_t cachedValue; #ifndef NOCACHE // Use any cached value if we are stalled. if ((STALLED == stallState) && memCache->read (addr, cachedValue)) { return cachedValue; // Already there, no more to do } #endif // Read the value selectDebugModule (OR1K_SC_WISHBONE); cachedValue = readJtagReg (addr); #ifndef NOCACHE // Update the cache if we are stalled if (STALLED == stallState) { memCache->write (addr, cachedValue); } #endif return cachedValue; } // readMem32 () //----------------------------------------------------------------------------- //! Write a 32-bit word to the OpenRISC 1000 memory //! Select the WISHBONE scan chain, then write the register. The data is in //! model endianness and passed on without modification. //! @todo Provide code to check if the write was to a valid address. //! @param[in] addr The address to write to //! @param[in] value The 32-bit value to write //! @return True if the write was successful. For now all writes are // successful. //----------------------------------------------------------------------------- bool DebugUnitSC::writeMem32 (uint32_t addr, uint32_t value) { #ifndef NOCACHE if (STALLED == stallState) { // Have we already cached this value? uint32_t cachedValue; if (memCache->read (addr, cachedValue) && (value == cachedValue)) { return true; // Already there, no more to do } else { memCache->write (addr, value); // Write for the future } } #endif // Write the memory selectDebugModule (OR1K_SC_WISHBONE); writeJtagReg (addr, value); return true; } // writeMem32 () //----------------------------------------------------------------------------- //! Read a byte from the OpenRISC 1000 main memory //! All we can get are 32-bits words, so we have to unpick the value. //! The underlying 32-bit routines take target endian arguments and return //! target endian results. We need to convert to host endianness to access the //! relevant byte. //! @todo Provide code to check if the read was from a valid address. //! @note Read bytes from memory mapped devices at your peril! //! @param[in] addr The address to read from //! @return The byte read //----------------------------------------------------------------------------- uint8_t DebugUnitSC::readMem8 (uint32_t addr) { uint32_t word = Utils::ttohl (readMem32 (addr & 0xfffffffc)); uint8_t *bytes = (uint8_t *)(&word); int offset = addr & 0x3; return bytes[offset]; } // readMem8 () //----------------------------------------------------------------------------- //! Write a byte to the OpenRISC 1000 main memory //! All we can get are 32-bits words, so we have to read the current value and //! construct the new value to write back. //! The underlying 32-bit routines take target endian arguments and return //! target endian results. We need to convert to host endianness to alter the //! relevant byte. //! @note Write bytes to memory mapped devices at your peril! //! @todo Provide code to check if the write was to a valid address. //! @param[in] addr The address to write to //! @param[in] value The byte to write //! @return True if the write was successful. For now all writes are // successful. //----------------------------------------------------------------------------- bool DebugUnitSC::writeMem8 (uint32_t addr, uint8_t value) { uint32_t currWord = Utils::ttohl (readMem32 (addr & 0xfffffffc)); uint8_t *currBytes = (uint8_t *)(&currWord); int offset = addr & 0x3; currBytes[offset] = value; return writeMem32 (addr & 0xfffffffc, Utils::htotl (currWord)); } // writeMem8 () //----------------------------------------------------------------------------- //! Get the debug interface CPU0 control register value //! @return The value in the RISCOP register //----------------------------------------------------------------------------- uint32_t DebugUnitSC::readRiscop () { selectDebugModule (OR1K_SC_CPU0); int drLen; // Size of the data register uint32_t calc_recv_crc = 0, recv_crc, status_ret; drLen = 1+4+32+52+4+32; // Initialize the register fields uint64_t *dRegIn = new uint64_t [(drLen + 63) / 64]; uint64_t *dRegOut = new uint64_t [(drLen + 63) / 64]; // Write the READ command clearBits (dRegIn, drLen); packBits (dRegIn, 0, 1, 0); packBits (dRegIn, 0+1, 4, BITREV(0x3,4)); // We're reading CPU0 control reg uint32_t crc32_send = crc32 (dRegIn, 0+1+4, 0); packBits (dRegIn, 0+1+4, 32, BITREV(crc32_send,32)); // Allocate a SystemC completion event sc_event *done = new sc_event(); // Loop until status is OK and CRCs match. do { TapActionDRScan *dRScan = new TapActionDRScan (done, dRegIn, drLen); tapActionQueue->write (dRScan); wait (*done); dRScan->getDRegOut (dRegOut); delete dRScan; status_ret = unpackBits (dRegOut,1+4+32+52,4); calc_recv_crc = crc32(dRegOut,52+4,1+4+32); recv_crc = BITREV(unpackBits (dRegOut,1+4+32+52+4,32),32); } while ((0 != status_ret) || ( calc_recv_crc != recv_crc)); // All done uint32_t res = BITREV(unpackBits (dRegOut, (1+4+32),2),2); delete [] dRegIn; delete [] dRegOut; delete done; return res; } // readRiscop () //----------------------------------------------------------------------------- //! Set the RISCOP control register //! Convenience function. Select the REGISTER scan chain, write the new value. //! @param[in] value The value to write into the RISCOP register //----------------------------------------------------------------------------- void DebugUnitSC::writeRiscop (uint32_t value) { selectDebugModule (OR1K_SC_CPU0); int drLen; // Size of the data register uint32_t calc_recv_crc = 0, recv_crc, status_ret; drLen = 1+4+32+52+4+32; // Initialize the register fields uint64_t *dRegIn = new uint64_t [(drLen + 63) / 64]; uint64_t *dRegOut = new uint64_t [(drLen + 63) / 64]; // Write the READ command clearBits (dRegIn, drLen); packBits (dRegIn, 0, 1, 0); packBits (dRegIn, 0+1, 4, BITREV(0x4,4)); // We're writing CPU0 control reg packBits (dRegIn, 5, 1, value&RISCOP_RESET); // First bit is reset packBits (dRegIn, 6, 1, (value&RISCOP_STALL)>>1); // Next bit is stall /* Next 50 bits should be zero */ uint32_t crc32_send = crc32 (dRegIn, 1+4+52, 0); packBits (dRegIn, 1+4+52, 32, BITREV(crc32_send,32)); // Allocate a SystemC completion event sc_event *done = new sc_event(); // Loop until status is OK and CRCs match. do { TapActionDRScan *dRScan = new TapActionDRScan (done, dRegIn, drLen); tapActionQueue->write (dRScan); wait (*done); dRScan->getDRegOut (dRegOut); delete dRScan; status_ret = unpackBits (dRegOut,1+4+32+52,4); calc_recv_crc = crc32(dRegOut,4,1+4+52+32); recv_crc = BITREV(unpackBits (dRegOut,1+4+52+32+4,32),32); } while ((0 != status_ret) || ( calc_recv_crc != recv_crc)); delete [] dRegIn; delete [] dRegOut; delete done; } // writeRiscop () //----------------------------------------------------------------------------- //! Select a module attached to the debug module //! @note Must be called from a SystemC thread, because of the use of wait() //! @param[in] chain The desired module //----------------------------------------------------------------------------- void DebugUnitSC::selectDebugModule (int module) { if (module == currentScanChain) { return; } else { currentScanChain = module; } sc_event *done = new sc_event(); TapActionIRScan *iRScan; TapActionDRScan *dRScan; // Create and queue the IR-Scan action for DEBUG (no CRC) iRScan = new TapActionIRScan (done, DEBUG_IR, JTAG_IR_LEN); tapActionQueue->write (iRScan); wait (*done); delete iRScan; // Initialize the register fields uint64_t *dRegIn = new uint64_t [(DUSEL_DR_LEN + 63) / 64]; uint64_t *dRegOut = new uint64_t [(DUSEL_DR_LEN + 63) / 64]; clearBits (dRegIn, DUSEL_DR_LEN); packBits (dRegIn, DUSEL_SEL_OFF, DUSEL_SEL_LEN, 0x1); packBits (dRegIn, DUSEL_OPCODE_OFF, DUSEL_OPCODE_LEN, bit_reverse_data(module,4)); uint32_t crc32_send = crc32 (dRegIn, DUSEL_CRC_OFF, 0); packBits (dRegIn, DUSEL_CRC_OFF, DUSEL_CRC_LEN, bit_reverse_data(crc32_send,32) ); uint32_t calc_recv_crc = 0, recv_crc, status_ret; // Loop until status is OK and CRCs match. do { TapActionDRScan *dRScan = new TapActionDRScan (done, dRegIn, DUSEL_DR_LEN); tapActionQueue->write (dRScan); wait (*done); dRScan->getDRegOut (dRegOut); delete dRScan; status_ret = unpackBits (dRegOut, DUSEL_RESP_STATUS_OFF, DUSEL_RESP_STATUS_LEN); calc_recv_crc = crc32(dRegOut, DUSEL_RESP_STATUS_LEN, DUSEL_RESP_STATUS_OFF); recv_crc = bit_reverse_data(unpackBits (dRegOut, DUSEL_RESP_CRC_OFF, DUSEL_RESP_CRC_LEN),32); } while ((0 != status_ret) || ( calc_recv_crc != recv_crc)); delete [] dRegIn; delete [] dRegOut; delete done; } // selectDebugModule() //----------------------------------------------------------------------------- //! Read a 32-bit value via the debug interface //! @note Must be called from a SystemC thread, because of the use of wait() //! @param[in] addr The address of the register //! @return The register value read //----------------------------------------------------------------------------- uint32_t DebugUnitSC::readJtagReg (uint32_t addr) { int drLen; // Size of the data register uint32_t calc_recv_crc = 0, recv_crc, status_ret; drLen = 125; // Size of write command command (bigger than data read) // Initialize the register fields uint64_t *dRegIn = new uint64_t [(drLen + 63) / 64]; uint64_t *dRegOut = new uint64_t [(drLen + 63) / 64]; // Write the READ command clearBits (dRegIn, drLen); packBits (dRegIn, 0, 1, 0); packBits (dRegIn, 0+1, 4, BITREV(0x2,4)); // We're writing a command packBits (dRegIn, 1+4, 4, BITREV(0x6,4)); // Access type, 0x6 = 32-bit READ packBits (dRegIn, 1+4+4, 32, BITREV(addr,32)); // Address packBits (dRegIn, 1+4+4+32, 16, BITREV(0x3,16)); // Length (always 32-bit,n=(32/8)-1=3) uint32_t crc32_send = crc32 (dRegIn, 1+4+4+32+16, 0); packBits (dRegIn, 1+4+4+32+16, 32, BITREV(crc32_send,32)); // Allocate a SystemC completion event sc_event *done = new sc_event(); // Loop until status is OK and CRCs match. do { TapActionDRScan *dRScan = new TapActionDRScan (done, dRegIn, 125); tapActionQueue->write (dRScan); wait (*done); dRScan->getDRegOut (dRegOut); delete dRScan; status_ret = unpackBits (dRegOut,1+4+4+32+16+32,4); calc_recv_crc = crc32(dRegOut,4,1+4+4+32+16+32); recv_crc = BITREV(unpackBits (dRegOut,1+4+4+32+16+32+4,32),32); } while ((0 != status_ret) || ( calc_recv_crc != recv_crc)); clearBits (dRegIn, drLen); packBits (dRegIn, 0, 1, 0); packBits (dRegIn, 0+1, 4, 0x0); // We're GO'ing command crc32_send = crc32 (dRegIn,1+4,0); packBits (dRegIn, 1+4, 32, BITREV(crc32_send,32)); // CRC uint32_t result; // Loop until status is OK and CRCs match. do { TapActionDRScan *dRScan = new TapActionDRScan (done, dRegIn, (1+4+32+36+((3+1)*8))); tapActionQueue->write (dRScan); wait (*done); dRScan->getDRegOut (dRegOut); delete dRScan; status_ret = BITREV(unpackBits (dRegOut,1+4+32+((3+1)*8),4),4); if (status_ret) { printf("readJtagReg(): Addr: 0x%.8x Status err: 0x%x\n",addr,status_ret); result = 0; break; } calc_recv_crc = crc32(dRegOut,((3+1)*8)+4,1+4+32); recv_crc = BITREV(unpackBits (dRegOut,1+4+32+((3+1)*8)+4,32),32); result = BITREV(unpackBits (dRegOut, (1+4+32), ((3+1)*8)),32); } while ((0 != status_ret) || ( calc_recv_crc != recv_crc)); // All done delete [] dRegIn; delete [] dRegOut; delete done; return result; } // readJtagReg () //----------------------------------------------------------------------------- //! Write a 32-bit value via the debug interface //! @note Must be called from a SystemC thread, because of the use of wait() //! @param[in] addr The address of the register //! @param[in] data The register data to write //----------------------------------------------------------------------------- void DebugUnitSC::writeJtagReg (uint32_t addr, uint32_t data) { int drLen; // Size of the data register uint32_t calc_recv_crc = 0, recv_crc, status_ret; drLen = 125; // Size of write command command (bigger than data read) // Initialize the register fields uint64_t *dRegIn = new uint64_t [(drLen + 63) / 64]; uint64_t *dRegOut = new uint64_t [(drLen + 63) / 64]; // Write the READ command clearBits (dRegIn, drLen); packBits (dRegIn, 0, 1, 0); packBits (dRegIn, 0+1, 4, BITREV(0x2,4)); // We're writing a command packBits (dRegIn, 1+4, 4, BITREV(0x2,4)); // Access type, 0x2 = 32-bit WRITE packBits (dRegIn, 1+4+4, 32, BITREV(addr,32)); // Address packBits (dRegIn, 1+4+4+32, 16, BITREV(0x3,16)); // Length (always 32-bit,n=(32/8)-1=3) uint32_t crc32_send = crc32 (dRegIn, 1+4+4+32+16, 0); packBits (dRegIn, 1+4+4+32+16, 32, BITREV(crc32_send,32)); // Allocate a SystemC completion event sc_event *done = new sc_event(); // Loop until status is OK and CRCs match. do { TapActionDRScan *dRScan = new TapActionDRScan (done, dRegIn, 125); tapActionQueue->write (dRScan); wait (*done); dRScan->getDRegOut (dRegOut); delete dRScan; status_ret = unpackBits (dRegOut,1+4+4+32+16+32,4); calc_recv_crc = crc32(dRegOut,4,1+4+4+32+16+32); recv_crc = BITREV(unpackBits (dRegOut,1+4+4+32+16+32+4,32),32); } while ((0 != status_ret) || ( calc_recv_crc != recv_crc)); clearBits (dRegIn, drLen); packBits (dRegIn, 0, 1, 0); packBits (dRegIn, 0+1, 4, 0x0); // We're GO'ing command packBits (dRegIn, 0+1+4, 32, BITREV(data,32)); // Add in data crc32_send = crc32 (dRegIn,1+4+32,0); packBits (dRegIn, 1+4+32, 32, BITREV(crc32_send,32)); // CRC // Loop until status is OK and CRCs match. do { TapActionDRScan *dRScan = new TapActionDRScan (done, dRegIn, (1+4+((3+1)*8)+32+36)); tapActionQueue->write (dRScan); wait (*done); dRScan->getDRegOut (dRegOut); delete dRScan; status_ret = unpackBits (dRegOut,1+4+32+32,4); calc_recv_crc = crc32(dRegOut,4,1+4+32+32); recv_crc = BITREV(unpackBits (dRegOut,1+4+32+32+4,32),32); } while ((0 != status_ret) || ( calc_recv_crc != recv_crc)); delete [] dRegIn; delete [] dRegOut; delete done; } // writeJtagReg () //----------------------------------------------------------------------------- //! Clear the bits in a data register //! We always clear whole 64-bit words, not just the minimum number of //! bytes. It saves all sorts of confusion when debugging code. //! @note It is the caller's responsibility to make sure the date register //! array is large enough. //! @param[in,out] regArray The data register to clear //! @param[in] regBits Size of the data register (in bits) //----------------------------------------------------------------------------- void DebugUnitSC::clearBits (uint64_t regArray[], int regBits) { memset ((char *)regArray, 0, ((regBits + 63) / 64) * 8); } // clearBits () //----------------------------------------------------------------------------- //! Set a bit field in a data register //! The field is cleared, the supplied value masked and then ored into the //! vector. //! @note It is the caller's responsibility to make sure the date register //! array is large enough. //! @param[in,out] regArray The data register //! @param[in] fieldOffset Start of the field (in bits) //! @param[in] fieldBits Size of the field (in bits) //! @param[in] fieldVal Value to set in the field //----------------------------------------------------------------------------- void DebugUnitSC::packBits (uint64_t regArray[], int fieldOffset, int fieldBits, uint64_t fieldVal) { fieldVal &= (1ULL << fieldBits) - 1ULL; // Mask the supplied value int startWord = fieldOffset / 64; int endWord = (fieldOffset + fieldBits - 1) / 64; fieldOffset = fieldOffset % 64; // Now refers to target word // Deal with the startWord. Get enough bits for the mask and put them in the // right place uint64_t startMask = ((1ULL << fieldBits) - 1ULL) << fieldOffset; regArray[startWord] &= ~startMask; regArray[startWord] |= fieldVal << fieldOffset; // If we were all in one word, we can give up now. if (startWord == endWord) { return; } // Deal with the endWord. Get enough bits for the mask. No need to shift // these up - they're always at the bottom of the word int bitsToDo = (fieldOffset + fieldBits) % 64; uint64_t endMask = (1ULL << bitsToDo) - 1ULL; regArray[endWord] &= ~endMask; regArray[endWord] |= fieldVal >> (fieldBits - bitsToDo); } // packBits () //----------------------------------------------------------------------------- //! Extract a bit field from a data register //! The field is cleared, the supplied value masked and then ored into the //! vector. //! @note It is the caller's responsibility to make sure the date register //! array is large enough. //! @param[in,out] regArray The data register //! @param[in] fieldOffset Start of the field (in bits) //! @param[in] fieldBits Size of the field (in bits) //! @return The value in the field //----------------------------------------------------------------------------- uint64_t DebugUnitSC::unpackBits (uint64_t regArray[], int fieldOffset, int fieldBits) { int startWord = fieldOffset / 64; int endWord = (fieldOffset + fieldBits - 1) / 64; fieldOffset = fieldOffset % 64; // Now refers to target word // Deal with the startWord. Get enough bits for the mask and put them in the // right place uint64_t startMask = ((1ULL << fieldBits) - 1ULL) << fieldOffset; uint64_t res = (regArray[startWord] & startMask) >> fieldOffset; // If we were all in one word, we can give up now. if (startWord == endWord) { res &= (1ULL << fieldBits) - 1ULL; // Mask off any unwanted bits return res; } // Deal with the endWord. Get enough bits for the mask. No need to shift // these up - they're always at the bottom of the word int bitsToDo = (fieldOffset + fieldBits) % 64; uint64_t endMask = (1ULL << bitsToDo) - 1ULL; res = res | ((regArray[endWord] & endMask) << (fieldBits - bitsToDo)); res &= (1ULL << fieldBits) - 1ULL; // Mask off any unwanted bits return res; } // unpackBits () //----------------------------------------------------------------------------- //! Compute CRC-8-ATM //! The data is in an array of uint64_t, for which we use the first size bits //! to compute the CRC. //! @Note I am using the same algorithm as the ORPSoC debug unit, but I //! believe its function is broken! I don't believe the data bit should //! feature in the computation of bits 2 & 1 of the new CRC. //! @Note I've realized that this is an algorithm for LSB first, so maybe it //! is correct! //! @param dataArray The array of data whose CRC is desired //! @param size The number of bits in the data //----------------------------------------------------------------------------- uint8_t DebugUnitSC::crc8 (uint64_t dataArray[], int size) { uint8_t crc = 0; for (int i = 0; i < size; i++) { uint8_t d = (dataArray[i / 64] >> (i % 64)) & 1; uint8_t oldCrc7 = (crc >> 7) & 1; uint8_t oldCrc1 = (crc >> 1) & 1; uint8_t oldCrc0 = (crc >> 0) & 1; uint8_t newCrc2 = d ^ oldCrc1 ^ oldCrc7; // Why d? uint8_t newCrc1 = d ^ oldCrc0 ^ oldCrc7; // Why d? uint8_t newCrc0 = d ^ oldCrc7; crc = ((crc << 1) & 0xf8) | (newCrc2 << 2) | (newCrc1 << 1) | newCrc0; } return crc; } // crc8 () /* Crc of current read or written data. */ uint32_t crc_r, crc_w = 0; /* Generates new crc, sending in new bit input_bit */ uint32_t DebugUnitSC::crc32(uint64_t dataArray[], int size, int offset) { uint32_t crc = 0xffffffff; for (int i = offset; i < size+offset; i++) { uint32_t d = ((dataArray[i / 64] >> (i % 64)) & 1) ? 0xfffffff : 0x0000000; uint32_t crc_32 = ((crc >> 31)&1) ? 0xfffffff : 0x0000000; crc <<= 1; crc = crc ^ ((d ^ crc_32) & DBG_CRC32_POLY); } return crc; } uint32_t DebugUnitSC::bit_reverse_swar_2(uint32_t x) { return (((x&0xaaaaaaaa)>>1)|((x&0x55555555)<<1)); } uint32_t DebugUnitSC::bit_reverse_swar_4(uint32_t x) { x=(((x&0xaaaaaaaa)>>1)|((x&0x55555555)<<1)); x=(((x&0xcccccccc)>>2)|((x&0x33333333)<<2)); return x; } uint32_t DebugUnitSC::bit_reverse_swar_8(uint32_t x) { x=(((x&0xaaaaaaaa)>>1)|((x&0x55555555)<<1)); x=(((x&0xcccccccc)>>2)|((x&0x33333333)<<2)); x=(((x&0xf0f0f0f0)>>4)|((x&0x0f0f0f0f)<<4)); return x; } uint32_t DebugUnitSC::bit_reverse_swar_16(uint32_t x) { x=(((x&0xaaaaaaaa)>>1)|((x&0x55555555)<<1)); x=(((x&0xcccccccc)>>2)|((x&0x33333333)<<2)); x=(((x&0xf0f0f0f0)>>4)|((x&0x0f0f0f0f)<<4)); x=(((x&0xff00ff00)>>8)|((x&0x00ff00ff)<<8)); return x; } uint32_t DebugUnitSC::bit_reverse_swar_32(uint32_t x) { x=(((x&0xaaaaaaaa)>>1)|((x&0x55555555)<<1)); x=(((x&0xcccccccc)>>2)|((x&0x33333333)<<2)); x=(((x&0xf0f0f0f0)>>4)|((x&0x0f0f0f0f)<<4)); x=(((x&0xff00ff00)>>8)|((x&0x00ff00ff)<<8)); x=(((x&0xffff0000)>>16)|((x&0x0000ffff)<<16)); // We could be on 64-bit arch! return x; } uint32_t DebugUnitSC::bit_reverse_data(uint32_t data, int length){ if (length == 2) return bit_reverse_swar_2(data); if (length == 4) return bit_reverse_swar_4(data); if (length == 8) return bit_reverse_swar_8(data); if (length == 16) return bit_reverse_swar_16(data); if (length == 32) return bit_reverse_swar_32(data); // Long and laborious way - hopefully never gets called anymore! uint32_t reverse=0; for (int i=0;i<length;i++) reverse |= (((data>>i)&1)<<(length-1-i)); return reverse; }
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