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[/] [openrisc/] [trunk/] [rtos/] [ecos-3.0/] [host/] [tools/] [ecostest/] [common/] [eCosTestSerialFilter.cpp] - Rev 790
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// ####ECOSHOSTGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of the eCos host tools. // Copyright (C) 1998, 1999, 2000 Free Software Foundation, Inc. // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation; either version 2 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 // General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program; if not, write to the // Free Software Foundation, Inc., 51 Franklin Street, // Fifth Floor, Boston, MA 02110-1301, USA. // ------------------------------------------- // ####ECOSHOSTGPLCOPYRIGHTEND#### //================================================================= // // eCosTestSerialFilter.cpp // // Serial test filter class // //================================================================= //================================================================= //#####DESCRIPTIONBEGIN#### // // Author(s): jskov // Contributors: jskov // Date: 1999-03-01 // Description: This filter sits between GDB and the test running on // the target, allowing testing of the serial driver // without confusing GDB. // To Do: // o Add timeout setup and handling for recovery, can rely on testing // agent to control global timeout. // o Saving chunks that caused transfer failure? // - In SEND with echo, do CRC on 32-byte sub-packets // o Additional To Do items under each sub-protocol function. // o Option to get all serial IO written (in hex, > and < prepends // input/output lines) to a file. // o Clean up the mess in this file.... //####DESCRIPTIONEND#### #include "eCosStd.h" #include "eCosTestSerialFilter.h" #include "eCosThreadUtils.h" char msg_ok[] = "OK"; char msg_er[] = "ER"; CeCosTestSerialFilter::CeCosTestSerialFilter(): m_bOptConsoleOutput(false), m_bOptSerDebug(false), m_bOptFilterTrace(false), m_xUnreadBuffer(NULL), m_nUnreadBufferIndex(0), m_nUnreadBufferSize(0), m_xStoredTraceBuffer(NULL), m_nStoredTraceBufferSize(0), m_bNullFilter(false), m_nCmdIndex(0), m_bCmdFlag(false), m_bFirstCommandSeen(false), m_cGDBSocket(NULL) { } CeCosTestSerialFilter::~CeCosTestSerialFilter() { } //------------------------ // Output helpers. // Encode string in an O-packet and send it to GDB. void CeCosTestSerialFilter::GDBWrite(const char* pszStr) { if (m_cGDBSocket) { static const char hexchars[] = "0123456789abcdef"; char* packet = new char[strlen(pszStr)*2+6]; char* p = packet; *p++ = '$'; *p++ = 'O'; unsigned char crc = 'O'; char c; for (;;) { c = *pszStr++; if (0 == c) break; char h = hexchars[(c >> 4) & 0x0f]; char l = hexchars[c & 0x0f]; *p++ = h; *p++ = l; crc = (unsigned char) (crc + h + l); }; *p++ = '#'; *p++ = hexchars[(crc >> 4) & 0x0f]; *p++ = hexchars[crc & 0x0f]; // Only try to send once. If it fails, it's probably because // GDB has disconnected. m_cGDBSocket->send(packet, p - packet); m_cGDBSocket->recv(&c, 1); delete [] packet; } } void CeCosTestSerialFilter::ConsoleWrite(const char* pszStr) { fputs(pszStr, stderr); fflush(stderr); } void CeCosTestSerialFilter::Trace(const char* pszFormat, ...) { va_list marker; va_start (marker, pszFormat); for(int nLength=100;nLength;) { char *buf=new char[1+nLength]; int n=vsnprintf(buf+4, nLength-4, pszFormat, marker ); if(-1==n){ nLength*=2; // NT behavior } else if (n<nLength){ memcpy(buf,"[f] ",4); if (m_bOptConsoleOutput) { ConsoleWrite(buf); } else { GDBWrite(buf); } nLength=0; // trigger exit from loop } else { nLength=n+1; // UNIX behavior generally, or NT behavior when buffer size exactly matches required length } delete [] buf; } va_end (marker); } void CeCosTestSerialFilter::Log(const char* pszFormat, ...) { va_list marker; va_start (marker, pszFormat); for(int nLength=100;nLength;) { char *buf=new char[1+nLength]; int n=vsnprintf(buf, nLength, pszFormat, marker ); if(-1==n){ nLength*=2; // NT behavior } else if (n<nLength){ if (m_bOptConsoleOutput) { ConsoleWrite(buf); } else { GDBWrite(buf); } nLength=0; // trigger exit from loop } else { nLength=n+1; // UNIX behavior generally, or NT behavior when buffer size exactly matches required length } delete [] buf; } va_end (marker); } void CeCosTestSerialFilter::PrintHex(const unsigned char* d1, int len, data_origin_t origin/*=SF_TARGET*/) { int offset = 0; int i; char buf[128]; int width = 8; while (len) { int count = MIN(width, len); char* p = buf; switch (origin) { case SF_TARGET: p += sprintf(p, "T"); break; case SF_FILTER: p += sprintf(p, "F"); break; } p += sprintf(p, ":%04x ", offset); // Print hex values. for (i = 0; i < count; i++) p += sprintf(p, "%02x ", d1[i]); for ( ; i < width ; i++) p += sprintf(p, ".. "); // Print ASCII string p += sprintf(p, "'"); for (i = 0; i < count; i++) { int c = d1[i]; if (' ' > c || 'z' < c) c = '.'; p += sprintf(p, "%c", c); } sprintf(p, "'\n"); Trace("%s", buf); len -= count; offset += count; d1 += count; } } void CeCosTestSerialFilter::TargetWrite(CeCosSerial &pSer, const unsigned char* buffer, int len) { unsigned int __written; if (m_bOptFilterTrace) PrintHex(buffer, len, SF_FILTER); do { if (!(pSer.Write((void*) buffer, len, __written))) { fprintf(stderr, "Writing %d bytes to serial failed\n", len); fprintf(stderr, "%s", (LPCTSTR)pSer.ErrString()); throw "serial write failed"; } buffer += __written; len -= __written; } while (len); } bool CeCosTestSerialFilter::TargetRead(CeCosSerial &pSer, unsigned char* buffer, int len) { unsigned int __read; int __total_read = 0; unsigned char* __buffer_base = buffer; int __timeouts = 0; int __timeout_failure = 0; int __orig_len = len; do { // First check for unread data. if (m_nUnreadBufferSize) { int i = 0; __read = 0; while (i < len && m_nUnreadBufferIndex < m_nUnreadBufferSize) { buffer[i++] = m_xUnreadBuffer[m_nUnreadBufferIndex++]; __read++; } if (m_nUnreadBufferIndex == m_nUnreadBufferSize) { free(m_xUnreadBuffer); m_nUnreadBufferSize = 0; m_nUnreadBufferIndex = 0; } } else { // Then read directly from serial. if (!(pSer.Read((void*) buffer, len, __read))) { fprintf(stderr,"Reading %d bytes from serial failed (read %d).\n", len, __read); char *pszErr=pSer.ErrString().GetCString(); fprintf(stderr, "%s", pszErr); delete [] pszErr; throw "serial read failed"; } } __total_read += __read; unsigned int i; for (i = 0; i < __read; i++) { if ('$' == buffer[i]) { Log("FAIL:<target crashed>\n"); Trace("**** Detected $ -- resuming as null filter ****\n"); Trace("Data received %d bytes (of %d) from target:\n", __total_read, __orig_len); PrintHex(__buffer_base, __total_read); Trace("<end>\n"); filter_abort_t* msg = new filter_abort_t(); msg->data_ptr = &buffer[i]; msg->data_len = __read - i; throw msg; } } if (0 == __read) { CeCosThreadUtils::Sleep(20); __timeouts++; if (25 == __timeouts) { __timeouts = 0; if (5 == __timeout_failure++) { Log("FAIL:<target timed out>\n"); Trace("**** Timed out while reading -- resuming as null filter\n"); Trace("Data received %d bytes (of %d) from target:\n", __total_read, __orig_len); PrintHex(__buffer_base, __total_read); Trace("<end>\n"); static const char kill_msg[] = "$X00#b8"; filter_abort_t* msg = new filter_abort_t(); msg->data_len = strlen(kill_msg); msg->data_ptr = (const unsigned char *)kill_msg; throw msg; } } } else { __timeouts = 0; __timeout_failure = 0; } buffer += __read; len -= __read; } while (len); return true; } // Send C ASCII string to target. void CeCosTestSerialFilter::TargetASCIIWrite(CeCosSerial &pSer, const char* s) { TargetWrite(pSer, (const unsigned char*) s, strlen(s)); } //------------------------ // Configuration Command. // Set serial configuration. bool CeCosTestSerialFilter::SetConfig(CeCosSerial &pSer, const ser_cfg_t* new_cfg, ser_cfg_t* old_cfg) { // Note that for flow control, we assume that *both* receive and transmit // flow control are set or not set if (old_cfg) { old_cfg->baud_rate = pSer.GetBaud(); old_cfg->parity = (0 != pSer.GetParity()) ? true : false; old_cfg->data_bits = pSer.GetDataBits(); old_cfg->stop_bits = pSer.GetStopBits(); old_cfg->flags = pSer.GetXONXOFFFlowControl() ? FLOW_XONXOFF_RX : 0; old_cfg->flags |= pSer.GetRTSCTSFlowControl() ? FLOW_RTSCTS_RX : 0; old_cfg->flags |= pSer.GetDSRDTRFlowControl() ? FLOW_DSRDTR_RX : 0; } pSer.SetBaud(new_cfg->baud_rate, false); pSer.SetParity(new_cfg->parity, false); pSer.SetDataBits(new_cfg->data_bits, false); pSer.SetXONXOFFFlowControl((new_cfg->flags&FLOW_XONXOFF_RX) != 0, false); pSer.SetRTSCTSFlowControl((new_cfg->flags&FLOW_RTSCTS_RX) != 0, false); pSer.SetDSRDTRFlowControl((new_cfg->flags&FLOW_DSRDTR_RX) != 0, false); return pSer.SetStopBits(new_cfg->stop_bits, true); // apply settings } // Return false if the serial configuration is not valid for the host. bool CeCosTestSerialFilter::VerifyConfig(CeCosSerial &pSer, ser_cfg_t* new_cfg) { ser_cfg_t old_cfg; bool rc; // Try changing to the new config, recording the result. Then restore // the original config. rc = SetConfig(pSer, new_cfg, &old_cfg); SetConfig(pSer, &old_cfg, NULL); return rc; } //----------------------------------------------------------------------------- // Configuration changing function. // // First change to the new config and back again to determine if the driver // can handle the config. // If not, return error. // // Then query the host for its capability to use the config: // Format out: // "@CONFIG:<baud rate code>:<#data bits>:<#stop bits>:<parity on/off>!" // Format in: // OK/ER // // On ER, return error. // // On OK, change to the new configuration. Resynchronize with the host: // Target waits for host to send S(ync) // [host will delay at least .1 secs after changing baud rate so the // line has time to settle.] // // When receiving S(ync), target replies OK to the host which then // acknowledges with D(one). // // Host can also send R(esync) which means it didn't receieve the OK. If // so the target resends its S(ync) message. // // If the synchronization has not succeeded within 1 second // (configurable in the protocol), both host and target will revert to // the previous configuration and attempt to synchronize again. If // this fails, this call will hang and the host will consider the test // a failure. // // To Do: // Host&protocol currently only supports: // - no/even parity void CeCosTestSerialFilter::CMD_ChangeConfig(CeCosSerial &pSer, char* cfg_str) { ser_cfg_t new_cfg, old_cfg; ParseConfig(cfg_str, &new_cfg); // Return without changing the config if it's not valid. if (!VerifyConfig(pSer, &new_cfg)) { TargetASCIIWrite(pSer, "ER"); return; } // Tell target we're ready to go, wait 1/10 sec, and then change // the config. TargetASCIIWrite(pSer, "OK"); CeCosThreadUtils::Sleep(100); SetConfig(pSer, &new_cfg, &old_cfg); int loops; for (loops = 0; loops < 3; loops++) { unsigned int len, read; unsigned char buffer[2]; int delay_mticks = 0; // millisecond-ticks. 10 of these per target tick // Start by sending a Sync. TargetASCIIWrite(pSer, "S"); for(;;) { // Did target reply? len = 2; read = 0; buffer[0] = 0; buffer[1] = 0; if (!pSer.Read((void*) buffer, len, read)) { throw "CMD_ChangeConfig: serial read failure"; } if (read) { // If only one char read, try to get the next one. if (1 == read) { unsigned int read2 = 0; len = 1; if (!pSer.Read((void*) &buffer[1], len, read2)) { throw "CMD_ChangeConfig: serial read failure"; } read += read2; } if (m_bOptSerDebug) PrintHex(buffer, read); if ('O' == buffer[0] && 'K' == buffer[1]) { // success! TargetASCIIWrite(pSer, "D"); Trace("Config change succeeded.\n"); return; } else { // Garbage, ask target to resend its OK message. TargetASCIIWrite(pSer, "R"); } } else { // Resend Sync message. TargetASCIIWrite(pSer, "S"); } CeCosThreadUtils::Sleep(1); delay_mticks++; // Timeout. if (100 == delay_mticks/10) break; } SetConfig(pSer, &old_cfg, NULL); } // Abort the test. Log("FAIL:<target timed out>\n"); Trace("**** Timed out while changing config\n"); static const char kill_msg[] = "$X00#b8"; filter_abort_t* msg = new filter_abort_t(); msg->data_len = strlen(kill_msg); msg->data_ptr = (const unsigned char *)kill_msg; throw msg; } // Set default configuration. void CeCosTestSerialFilter::CMD_DefaultConfig(CeCosSerial &pSer) { static const ser_cfg_t default_ser_cfg = { 9600, 8, CeCosSerial::ONE_STOP_BIT, false }; TargetASCIIWrite(pSer, "OK"); SetConfig(pSer, &default_ser_cfg, NULL); } // Parse config string from target and set new_cfg accordingly. // String from target is: // <baud rate>:<data bits>:<stop bits>:<parity>:.... void CeCosTestSerialFilter::ParseConfig(char* args, ser_cfg_t* new_cfg) { int ecos_parity, ecos_stop_bits, ecos_baud_rate, ecos_flags; CeCosSerial::StopBitsType t2h_stop_bits[3] = { CeCosSerial::ONE_STOP_BIT, CeCosSerial::ONE_POINT_FIVE_STOP_BITS, CeCosSerial::TWO_STOP_BITS}; INIT_VALUE(args); SET_VALUE(int, ecos_baud_rate); SET_VALUE(int, new_cfg->data_bits); SET_VALUE(int, ecos_stop_bits); SET_VALUE(int, ecos_parity); SET_VALUE(int, ecos_flags); new_cfg->parity = (ecos_parity != 0) ? true : false; new_cfg->stop_bits = t2h_stop_bits[ecos_stop_bits - 1]; // flags is an optional field if ( -1 == ecos_flags ) new_cfg->flags = FLOW_NONE; else new_cfg->flags = ecos_flags; // eCos->human translation of serial baud rate. This table must // match the one in io/serial/current/include/serialio.h static const int tt_baud_rate[] = { -1, // 0 invalid 50, // 1 50 75, // 2 75 110, // 3 135, // 4 134_5 150, // 5 200, // 6 200 300, // 7 600, // 8 1200, // 9 1800, // 10 1800 2400, // 11 3600, // 12 3600 4800, // 13 7200, // 14 7200 9600, // 15 14400, // 16 14400 19200, // 17 38400, // 18 57600, // 19 115200, // 20 234000 // 21 234000 }; if (ecos_baud_rate > 0 && ecos_baud_rate < (int) sizeof(tt_baud_rate)) ecos_baud_rate = tt_baud_rate[ecos_baud_rate]; else ecos_baud_rate = -2; new_cfg->baud_rate = ecos_baud_rate; Trace("Parsed Config baud=%d, bParity=%d, stopbits=%d, databits=%d\n", new_cfg->baud_rate, (int) new_cfg->parity, new_cfg->stop_bits, new_cfg->data_bits); Trace("Parsed Config xonxoff_rx=%d,tx=%d, rtscts_rx=%d,tx=%d, " "dsrdtr_rx=%d,tx=%d\n", (new_cfg->flags & FLOW_XONXOFF_RX) != 0, (new_cfg->flags & FLOW_XONXOFF_TX) != 0, (new_cfg->flags & FLOW_RTSCTS_RX) != 0, (new_cfg->flags & FLOW_RTSCTS_TX) != 0, (new_cfg->flags & FLOW_DSRDTR_RX) != 0, (new_cfg->flags & FLOW_DSRDTR_TX) != 0); } // Always make sure CRC fits in 31 bits. Bit of a hack, but we want // to send CRC as ASCII without too much hassle. int CeCosTestSerialFilter::DoCRC(unsigned char* data, int size) { int i; unsigned long crc; for (i = 0, crc = 0; i < size; i++) { crc = (crc << 1) ^ data[i]; // FIXME: standard definition? } i = (int) crc; if (i < 0) i = -i; return i; } void CeCosTestSerialFilter::SendChecksum(CeCosSerial &pSer, int crc) { char buffer[128]; int len; len = sprintf(buffer, "%d!", crc); TargetWrite(pSer, (const unsigned char*)buffer, len); } void CeCosTestSerialFilter::SendStatus(CeCosSerial &pSer, int state) { if (state) TargetWrite(pSer, (unsigned char*) &msg_ok, 2); else TargetWrite(pSer, (unsigned char*) &msg_er, 2); } // Receive test DONE message from target. void CeCosTestSerialFilter::ReceiveDone(CeCosSerial &pSer, unsigned char* data_in, int size) { static const char msg_done[] = "DONE"; unsigned char data_reply[4]; int first = 1; TargetRead(pSer, data_reply, 4); while (0 != strncmp((char*) data_reply, msg_done, 4)) { if (first) { if (data_in && size) { Trace("Data received from target:\n"); PrintHex(data_in, size); Trace("<end>\n"); } Trace("Receiving junk instead of DONE:\n"); first = 0; } PrintHex(data_reply, 4); data_reply[0] = data_reply[1]; data_reply[1] = data_reply[2]; data_reply[2] = data_reply[3]; // The TargetRead call will handle recovery in case of timeout... TargetRead(pSer, &data_reply[3], 1); } } //----------------------------------------------------------------------------- // Test binary data transmission. // Format in: // <byte size>:<mode> // Format out: // <4 bytes binary checksum><#size bytes data> // If echo mode, also: // Format in: // <#size bytes data> // Format out: // OK/ER - according to CRC match on incomin data // Format in: // DONE // // To Do: // o Add mode/flag specifying 5-8 bit transfer. // Test that 0xff gets masked off accordingly when transfered. // (This should be an INFO result if failing) // o Clean up the DUPLEX_ECHO implementation. Currently it's an ugly hack // that doesn't match the arguments / behavior of the two other modes. void CeCosTestSerialFilter::CMD_TestBinary(CeCosSerial &pSer, char* args) { int size; cyg_mode_t mode; unsigned char *data_out, *data_in; int i; int crc; int loop_count = 0; INIT_VALUE(args); SET_VALUE(int, size); SET_VALUE(cyg_mode_t, mode); // Change behavior for DUPLEX mode. if (MODE_DUPLEX_ECHO == mode) { loop_count = size; size = 1024; // must be at least 4*block_size } // Generate data. data_out = (unsigned char*) malloc(size); if (!data_out) { fprintf(stderr, "Could not allocate %d byte buffer for data!\n", size); throw "data_out malloc failed"; } data_in = (unsigned char*) malloc(size); if (!data_in) { fprintf(stderr, "Could not allocate %d byte buffer for data!\n", size); throw "data_in malloc failed"; } int count = 0; for (i = 0; i < size; i++) { // Output 255 chars, not 256 so that we aren't a multiple/factor of the // likely buffer sizes in the system, this can mask problems as I've // found to my cost! unsigned char c = (unsigned char) (count++ % 255); // don't allow $s and @s in the data, nor 0x03 (GDB C-c), nor flow // control chars if ('$' == c || '@' == c || 0x03 == c || 0x11 == c || 0x13 == c) c = (unsigned char) '*'; data_out[i] = c; } // Do checksum. crc = DoCRC(data_out, size); // Send checksum to target. SendChecksum(pSer, crc); // Give the target 1/10th of a sec to digest it CeCosThreadUtils::Sleep(100); switch (mode) { case MODE_NO_ECHO: { // Simple transmit. Don't expect target to echo data back. TargetWrite(pSer, data_out, size); ReceiveDone(pSer, NULL, 0); } break; case MODE_EOP_ECHO: { int in_crc; TargetWrite(pSer, data_out, size); Trace("Finished write, waiting for target echo.\n"); // Expect target to echo the data TargetRead(pSer, data_in, size); // Check echoed data, and reply OK/ER accordingly. in_crc = DoCRC(data_in, size); SendStatus(pSer, (in_crc == crc)); // Dump seen/expected on console. if (in_crc != crc) { Trace("Data seen:\n"); PrintHex(data_in, size); Trace("<end>\n"); Trace("Data expected:\n"); PrintHex(data_out, size); Trace("<end>\n"); } ReceiveDone(pSer, data_in, size); } break; case MODE_DUPLEX_ECHO: { int block_size = 64; int fail, j; // This is a simple implementation (maybe too simple). // Host sends 4 packets with the same size (64 bytes atm). // Target echoes in this way: // packet1 -> packet1 // packet2 -> packet2, packet2 // packet3 -> packet3 // packet4 -> /dev/null // // The reads/writes are interleaved in a way that should ensure // the target out buffer to be full before the target starts to read // packet3. That is, the target should be both receiving (packet3) // and sending (packet2) at the same time. // This code needs restructuring. It's not very obvious what's // happening: The same block of data is output several times, // the target echoes the data back (one of the blocks is // echoed twice). Then the echoed data is compared agains the // outgoing data block. fail = 0; while (loop_count--) { int i; for (i = 0; i < block_size*4; i++) data_in[i] = 0; // out1: block_size -> block_size TargetWrite(pSer, data_out, block_size); // out2: block_size -> 2 x block_size TargetWrite(pSer, data_out, block_size); // in1: TargetRead(pSer, data_in, block_size); // out3: block_size -> block_size TargetWrite(pSer, data_out, block_size); // in2: TargetRead(pSer, &data_in[block_size], 2*block_size); // out4: block_size -> 0 TargetWrite(pSer, data_out, block_size); // in3: TargetRead(pSer, &data_in[block_size*3], block_size); if (0 == loop_count % 10) Trace("%d loops to go\n", loop_count); // Verify data. if (!fail) { for (j = 0; j < 4 && !fail; j++) { for (i = 0; i < block_size && !fail; i++) { if (data_out[i] != data_in[j*block_size + i]) { fail = 1; Trace("Failed at byte %d\n", j*block_size + i); Trace("Data seen:\n"); PrintHex(&data_in[j*block_size], block_size); Trace("<end>\n"); Trace("Data expected:\n"); PrintHex(data_out, block_size); Trace("<end>\n"); } } } } } // Check echoed data, and reply OK/ER accordingly. SendStatus(pSer, (!fail)); ReceiveDone(pSer, data_in, block_size*4); } break; default: Trace("Unknown mode. Ignoring.\n"); } // Free buffer. free(data_in); free(data_out); } //----------------------------------------------------------------------------- // Test transformations on text transmissions // // This test transmits null-terminated C strings back and forth. Since // the translation is under test and may fail, the length of the data is // (potentially) unknown. Sending with a null-terminator allows proper // recovery even if the translations do not work as intended. // // Format in: // <flags>!<4 bytes binary checksum><C string> // Format out: // <C string> // OK/ER // // Mode: // MODE_EOP_ECHO: // Receive data, verify CRC, resend data. // Send OK/ER reply when done. // MODE_DUPLEX_ECHO: // Receive data, echo data, verify CRC. // Send OK/ER reply when done. // // To Do: // Implement. void CeCosTestSerialFilter::CMD_TestText(CeCosSerial &pSer, char* /*args*/) { SendStatus(pSer, 1); } //----------------------------------------------------------------------------- // Reply to PING packet from target. // Format in: // "!" // Format out: // OK void CeCosTestSerialFilter::CMD_TestPing(CeCosSerial &pSer, char* /*args*/) { SendStatus(pSer, 1); } //----------------------------------------------------------------------------- // Dispatch test command. void CeCosTestSerialFilter::DispatchCommand(CeCosSerial &pSer, char* cmd) { char* args; args = strchr(cmd, (int) ':'); if (!args) { Trace("Bogus command (%s) Ignoring.\n", cmd); return; } *args++ = 0; Trace("Dispatching command %s.\n", cmd); if (0 == strcmp("CONFIG", cmd)) { CMD_ChangeConfig(pSer, args); } else if (0 == strcmp("DEFCONFIG", cmd)) { // Note: Currently the arguments are ignored. 9600 8N1 is default. CMD_DefaultConfig(pSer); } else if (0 == strcmp("BINARY", cmd)) { CMD_TestBinary(pSer, args); } else if (0 == strcmp("TEXT", cmd)) { CMD_TestText(pSer, args); } else if (0 == strcmp("PING", cmd)) { CMD_TestPing(pSer, args); } else Trace("Unknown command '%s'.\n", cmd); Trace("Command %s completed.\n", cmd); } bool CALLBACK SerialFilterFunction(void*& pBuf, unsigned int& nRead, CeCosSerial& serial, CeCosSocket& socket, void* pParem) { CeCosTestSerialFilter* p = (CeCosTestSerialFilter*) pParem; return p->FilterFunctionProper(pBuf, nRead, serial, socket); } bool CeCosTestSerialFilter::FilterFunctionProper(void*& pBuf, unsigned int& nRead, CeCosSerial& serial, CeCosSocket& socket) { char* buffer = (char*) pBuf; // Don't do anything in the null filter mode. if (m_bNullFilter) return true; // Allows trace to be called without a reference to the socket... m_cGDBSocket = &socket; // Put in trace buffer in case we have to leave it because the packet // is incomplete m_xStoredTraceBuffer = (unsigned char *) realloc( m_xStoredTraceBuffer, m_nStoredTraceBufferSize + nRead ); if ( NULL == m_xStoredTraceBuffer ) throw "Could not allocate stored trace buffer"; memcpy( m_xStoredTraceBuffer + m_nStoredTraceBufferSize, buffer, nRead ); m_nStoredTraceBufferSize += nRead; // Now search for distinct packets, delimited by '@' (filter commands) // and '$' (GDB packets) unsigned int i, newStart=0; for (i=0; i<m_nStoredTraceBufferSize; i++) { if ( m_xStoredTraceBuffer[i] == '@' || m_xStoredTraceBuffer[i] == '$' ) { if (m_bOptSerDebug && (m_bOptConsoleOutput || m_bFirstCommandSeen)) { // Output the serial data if option enabled - but only if // dumping state to the console or after the first command // has been seen from the filter. GDB gets confused by // O-packets if they appear when it's trying to connect. PrintHex(&m_xStoredTraceBuffer[newStart], i - newStart); } newStart = i; } } // If we managed to print output, rejig the buffer size, and shunt // the new start of the data to the front of the trace buffer m_nStoredTraceBufferSize -= newStart; memmove( m_xStoredTraceBuffer, &m_xStoredTraceBuffer[newStart], m_nStoredTraceBufferSize ); // Command handling. // If we are not presently reading a command, look for the // start marker. i = 0; if (!m_bCmdFlag) for (; i < nRead; i++) { if ('@' == buffer[i]) { m_bCmdFlag = true; // Send the data before the marker. if (i) socket.send(buffer, i); break; } } // If reading a command, look for the end marker. if (m_bCmdFlag) { char c = 0; while (i < nRead && m_nCmdIndex < MAX_CMD_LEN) { c = buffer[i++]; m_aCmd[m_nCmdIndex++] = c; if ('!' == c) { if (i != nRead) { m_nUnreadBufferIndex = 0; m_nUnreadBufferSize = nRead - i; m_xUnreadBuffer = (unsigned char*) malloc(m_nUnreadBufferSize); if (!m_xUnreadBuffer) { m_nUnreadBufferSize = 0; throw "Could not allocate unread buffer!"; } int ix = 0; while (i < nRead) m_xUnreadBuffer[ix++] = buffer[i++]; } break; } } if (MAX_CMD_LEN == m_nCmdIndex) { Trace("Received too long command. Ignoring it!\n"); m_nCmdIndex = 0; m_bCmdFlag = false; } else if ('!' == c) { // Was the command completed? m_aCmd[m_nCmdIndex - 1] = 0;// terminate cmd m_nCmdIndex = 0; m_bCmdFlag = false; // First command dispatched. Initialize serial to nonblocking. if (!m_bFirstCommandSeen) { m_bFirstCommandSeen = true; serial.SetBlockingReads(false); } try { // skip @ when passing ptr DispatchCommand(serial, &m_aCmd[1]); } catch (filter_abort_t* msg) { // This allows the filter to unwind, wherever in the // protocol it may be, when a $ is detected from the // target side. When this happens, we may have a // trap/exception on the target and we want the user // to access the target via GDB without intervention. // Do nothing from next call. m_bNullFilter = true; // Copy the start of the $-packet to the inbuffer. unsigned char *d = (unsigned char*) pBuf; const unsigned char *s = msg->data_ptr; unsigned int len = msg->data_len; // It should be possible to re-allocate buffer. Didn't seem // to work properly though. Probably won't be a problem // since we would normally only see 1-2 bytes of the // $-packet anyway. if (len > nRead) throw "Not enough room for $-message"; while (len--) *d++ = *s++; nRead = msg->data_len; delete msg; return true; } } nRead = 0; // Never leave anything for caller // This is a violation of the intended // filter function behavior. } return true; }
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