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[/] [openrisc/] [trunk/] [or1ksim/] [testsuite/] [test-code/] [lib-upcalls/] [lib-upcalls.c] - Rev 582
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/* lib-upcalls.c. Test of Or1ksim library upcall interface. Copyright (C) 1999-2006 OpenCores Copyright (C) 2010 Embecosm Limited Contributors various OpenCores participants Contributor Jeremy Bennett <jeremy.bennett@embecosm.com> This file is part of OpenRISC 1000 Architectural Simulator. 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 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see <http: www.gnu.org/licenses/>. */ /* ---------------------------------------------------------------------------- This code is commented throughout for use with Doxygen. --------------------------------------------------------------------------*/ #include <errno.h> #include <stddef.h> #include <stdlib.h> #include <stdio.h> #include <string.h> #include "or1ksim.h" /*! Memory mapped register memory */ static unsigned char *regv; /*! Number of bytes of register memory */ static int regc; /*! Number of times each upcall has been called */ static int upcall_count; /* --------------------------------------------------------------------------*/ /*!Read upcall Upcall from Or1ksim to read a word from an external peripheral. Read the specified bytes from the peripheral if available. We only ever expect to get 4 byte reads here (modeling Wishbone). @note We receive the full address, since there is a single upcall routine, and this allows us to decode between potentially multiple devices. @todo We assume that the register memory size is a power of 2, making address shortening a simple modulo exercise. We should use a more generic solution. @note The mask is a byte mask. Since this is testing, we warn if any byte is not either 0xff or 0x00. @param[in] class_ptr A handle pass back from the initalization. Intended for C++ callers, not used here. @param[in] addr Address to read from. @param[in] mask Byte mask for the read. @param[out] rdata Buffer for the data read. @param[in] data_len Number of bytes in mask and rdata. @return Zero on success, non-zero on failure. */ /* --------------------------------------------------------------------------*/ static int read_upcall (void *class_ptr, unsigned long int addr, unsigned char mask[], unsigned char rdata[], int data_len) { unsigned long int devaddr = addr % regc; upcall_count--; /* One less upcall to do */ if (4 != data_len) { printf ("Warning: 4-byte reads only supported for this device.\n"); return -1; } if (devaddr > regc - data_len) { printf ("Warning: read from 0x%08lx out of range: zero result.\n", devaddr); return -1; } /* Read the data */ int i; for (i = 0; i < 4; i++) { switch (mask[i]) { case 0x00: rdata[i] = 0; break; case 0xff: rdata[i] = regv[devaddr + i]; break; default: printf ("Warning: invalid mask byte %d for read 0x%02x: " "treated as 0xff.\n", i, mask[i]); rdata[i] = regv[devaddr + i]; break; } } /* printf ("Read from 0x%08lx: vector [%02x %02x %02x %02x ], " */ /* "mask [%02x %02x %02x %02x ].\n", devaddr, rdata[0], rdata[1], */ /* rdata[2], rdata[3], mask[0], mask[1], mask[2], mask[3]); */ return 0; /* Success */ } /* read_upcall () */ /* --------------------------------------------------------------------------*/ /*!Write upcall Upcall from Or1ksim to write a word to an external peripheral. Read the specified bytes from the peripheral if available. We only ever expect to get 4 byte reads here (modeling Wishbone). @note We receive the full address, since there is a single upcall routine, and this allows us to decode between potentially multiple devices. @todo We assume that the register memory size is a power of 2, making address shortening a simple modulo exercise. We should use a more generic solution. @note The mask is a byte mask. Since this is testing, we warn if any byte is not either 0xff or 0x00. @param[in] class_ptr A handle pass back from the initalization. Intended for C++ callers, not used here. @param[in] addr Address to write to. @param[in] mask Byte mask for the write. @param[in] wdata The data to write. @param[in] data_len Number of bytes in mask and rdata. @return Zero on success, non-zero on failure. */ /* --------------------------------------------------------------------------*/ static int write_upcall (void *class_ptr, unsigned long int addr, unsigned char mask[], unsigned char wdata[], int data_len) { unsigned long int devaddr = addr % regc; upcall_count--; /* One less upcall to do */ if (4 != data_len) { printf ("Warning: 4-byte writes only supported for this device.\n"); return -1; } if (devaddr > regc - data_len) { printf ("Warning: write to 0x%08lx out of range: ignored.\n", devaddr); return -1; } /* printf ("Write to 0x%08lx: vector [%02x %02x %02x %02x ], " */ /* "mask [%02x %02x %02x %02x ].\n", devaddr, wdata[0], wdata[1], */ /* wdata[2], wdata[3], mask[0], mask[1], mask[2], mask[3]); */ /* Write the data */ int i; for (i = 0; i < 4; i++) { switch (mask[i]) { case 0x00: break; case 0xff: regv[devaddr + i] = wdata[i]; break; default: printf ("Warning: invalid mask byte %d for write 0x%02x: " "treated as 0xff.\n", i, mask[i]); regv[devaddr + i] = wdata[i]; break; } } return 0; /* Success */ } /* write_upcall () */ /* --------------------------------------------------------------------------*/ /*!Main program Build an or1ksim program using the library which loads a program and config from the command line which will drive upcalls. lib-upcalls <config-file> <image> <upcall_count> <reg_bytes> [<reg_file>] A register memory of <reg_bytes> bytes is initalized from <reg_file> if present, or zeroed if not. <image> is run continuously, making upcalls, which are satisfied using the register memory. The program exits successfully when <upcall_count> upcalls have been made. @param[in] argc Number of elements in argv @param[in] argv Vector of program name and arguments @return Return code for the program. */ /* --------------------------------------------------------------------------*/ int main (int argc, char *argv[]) { char *reg_file; /* Parse args */ switch (argc) { case 5: reg_file = NULL; break; case 6: reg_file = argv[5]; break; default: printf ("usage: lib-upcalls <config-file> <image> " "<upcall_count> <reg_bytes> [<reg_file>]\n"); return 1; } upcall_count = atoi (argv[3]); if (upcall_count <= 0) { printf ("ERROR: Upcall count must be positive\n"); return 1; } regc = atoi (argv[4]); if (regc < 0) { printf ("ERROR: Register memory size must be positive\n"); return 1; } /* Read the register file if provided. */ regv = malloc (regc * sizeof (unsigned char)); if (NULL == regv) { printf ("ERROR: Failed to allocate register memory\n"); return 1; } int next_free_byte = 0; if (NULL != reg_file) { FILE *fd = fopen (reg_file, "r"); if (NULL == fd) { printf ("ERROR: Failed to open register file: %s\n", strerror (errno)); free (regv); return 1; } for (; next_free_byte < regc; next_free_byte++) { unsigned char byte; if (1 == fscanf (fd, "%2hhx ", &byte)) { regv[next_free_byte] = byte; } else { break; } } /* Should have read the whole file successfully. */ if (ferror (fd)) { printf ("ERROR: Reading register file: %s\n", strerror (errno)); free (regv); return 1; } if (!feof (fd)) { printf ("Warning: additional register file data ignored.\n"); } if (0 != fclose (fd)) { printf ("ERROR: Failed to close register file: %s\n", strerror (errno)); free (regv); return 1; } } /* Fill in any remaining bytes with zero */ if (next_free_byte < regc) { (void)memset (&(regv[next_free_byte]), 0, regc - next_free_byte); } /* Dummy argv array to pass arguments to or1ksim_init. Varies depending on whether an image file is specified. */ int dummy_argc; char *dummy_argv[5]; dummy_argv[0] = "libsim"; dummy_argv[1] = "-q"; dummy_argv[2] = "-f"; dummy_argv[3] = argv[1]; dummy_argv[4] = argv[2]; dummy_argc = 5; /* Initialize the program. Put the initialization message afterwards, or it will get swamped by the Or1ksim header. */ if (0 == or1ksim_init (dummy_argc, dummy_argv, NULL, &read_upcall, &write_upcall)) { printf ("Initalization succeeded.\n"); } else { printf ("Initalization failed.\n"); return 1; } /* Run repeatedly for 1 millisecond until we hit a breakpoint or all upcalls are done. */ do { switch (or1ksim_run (1.0e-3)) { case OR1KSIM_RC_OK: break; case OR1KSIM_RC_HALTED: printf ("Test completed successfully: hit exit l.nop.\n"); return 0; case OR1KSIM_RC_BRKPT: printf ("Test completed successfully: hit breakpoint.\n"); return 0; default: printf ("ERROR: run failed\n"); return 1; } } while (upcall_count > 0); /* A little longer to allow response to last upcall to be handled. */ switch (or1ksim_run (1.0e-3)) { case OR1KSIM_RC_OK: printf ("Test completed successfully: All upcalls processed.\n"); return 0; case OR1KSIM_RC_HALTED: printf ("Test completed successfully: hit exit l.nop.\n"); return 0; case OR1KSIM_RC_BRKPT: printf ("Test completed successfully: hit breakpoint.\n"); return 0; default: printf ("ERROR: run failed\n"); return 1; } } /* main () */
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