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[/] [openrisc/] [trunk/] [or1ksim/] [testsuite/] [test-code-or1k/] [support/] [support.c] - Rev 297
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/* support.c -- Support code for Or1ksim testing. Copyright (C) 1999 Damjan Lampret, lampret@opencores.org Copyright (C) 2008, 2010 Embecosm Limited Contributor Damjan Lampret <lampret@opencores.org> 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. --------------------------------------------------------------------------*/ /* Support */ #include "spr-defs.h" #include "support.h" #include "int.h" /* Forward declarations of interrupt handlers */ static void excpt_dummy(); extern void int_main(); /* Exception handlers. All are dummy except the interrupt handler */ unsigned long excpt_buserr = (unsigned long) excpt_dummy; unsigned long excpt_dpfault = (unsigned long) excpt_dummy; unsigned long excpt_ipfault = (unsigned long) excpt_dummy; unsigned long excpt_tick = (unsigned long) excpt_dummy; unsigned long excpt_align = (unsigned long) excpt_dummy; unsigned long excpt_illinsn = (unsigned long) excpt_dummy; unsigned long excpt_int = (unsigned long) int_main; unsigned long excpt_dtlbmiss = (unsigned long) excpt_dummy; unsigned long excpt_itlbmiss = (unsigned long) excpt_dummy; unsigned long excpt_range = (unsigned long) excpt_dummy; unsigned long excpt_syscall = (unsigned long) excpt_dummy; unsigned long excpt_break = (unsigned long) excpt_dummy; unsigned long excpt_trap = (unsigned long) excpt_dummy; /* --------------------------------------------------------------------------*/ /*!Is a character a decimal digit? @param[in] c The character to test @return 1 (TRUE) if the character is a decimal digit, 0 (FALSE) otherwise */ /* --------------------------------------------------------------------------*/ static int is_digit (char c) { return ('0' <= c) && (c <= '9'); } /* is_digit () */ /* --------------------------------------------------------------------------*/ /*!Print a char in a width The char is always right justified. @param[in] c The character to print @param[in] width The width to print in @return The number of characters actually printed (always width) */ /* --------------------------------------------------------------------------*/ static int printf_char (char c, int width) { int i; /* Spacing */ for (i = 1; i < width; i++) { putchar (' '); } /* The char */ putchar (c); return width; } /* printf_char () */ /* --------------------------------------------------------------------------*/ /*!Convert a digit to a char We don't worry about the base. If the value supplied is over 10, we assume its a letter. @param[in] d The digit to convert. @return The character representation. */ /* --------------------------------------------------------------------------*/ static char dig2char (int d) { return (d < 10) ? '0' + d : 'a' + d - 10; } /* dit2char () */ /* --------------------------------------------------------------------------*/ /*!Print a number to a base to a string The number is unsigned, left justified and null terminated @param[in] uval The value to print @param[in] buf The buffer to print in @param[in] base The base to use. @return the length of the string created. */ /* --------------------------------------------------------------------------*/ static int print_base (long unsigned int uval, char buf[], unsigned int base) { /* Initially print backwards. Always have at least a zero. */ int i = 0; do { buf[i] = dig2char (uval % base); uval = uval / base; i++; } while (0 != uval); buf[i] = 0; /* End of string */ int len = i; /* Length of the string */ /* Reverse the string */ for (i = 0; i < (len / 2); i++) { char c = buf[i]; buf[i] = buf[len - i - 1]; buf[len - i - 1] = c; } return len; } /* print_base () */ /* --------------------------------------------------------------------------*/ /*!Print a character multiple times @param[in] c The char to print @param[in] num Number of times to print */ /* --------------------------------------------------------------------------*/ static void print_multichar (char c, int num) { for (; num > 0; num--) { putchar (c); } } /* print_multichar () */ /* --------------------------------------------------------------------------*/ /*!Print a string @param[in] str The string to print */ /* --------------------------------------------------------------------------*/ static void print_str (char str []) { int i; for (i = 0; 0 != str[i]; i++) { putchar (str[i]); } } /* print_str () */ /* --------------------------------------------------------------------------*/ /*!Return the length of a string @param[in] str The string whose length is wanted @return The length of the string */ /* --------------------------------------------------------------------------*/ static int strlen (char str []) { int i; for (i = 0; str[i] != 0; i++) { } return i; } /* strlen () */ /* --------------------------------------------------------------------------*/ /*!Print a string in a width @param[in] str The string to print @param[in] width The width to print it in (at least) @return The number of chars printed */ /* --------------------------------------------------------------------------*/ static int printf_str (char str [], int width) { int len = strlen (str); if (width > len) { print_multichar (' ', width - len); } print_str (str); return (width > len) ? width : len; } /* printf_str () */ /* --------------------------------------------------------------------------*/ /*!Print a decimal in a width The number is always right justified and signed. @param[in] val The value to print @param[in] width The width to print in (at least) @param[in] leading_zeros_p 1 (TRUE) if we should print leading zeros, 0 (FALSE) otherwise @return The number of chars printed */ /* --------------------------------------------------------------------------*/ static int printf_decimal (long int val, int width, int leading_zeros_p) { int is_signed_p = 0; /* Note if we need a sign */ if (val < 0) { val = -val; is_signed_p = 1; } /* Array to store the number in. We know the max for 32 bits is 10 digits. Allow for end of string marker */ char num_array[11]; int num_width = print_base ((unsigned long int) val, num_array, 10); /* Now print out the number. */ num_width += is_signed_p ? 1 : 0; if (num_width < width) { if (leading_zeros_p) { if (is_signed_p) { putchar ('-'); } print_multichar ('0', width - num_width); } else { print_multichar (' ', width - num_width); if (is_signed_p) { putchar ('-'); } } } else { if (is_signed_p) { putchar ('-'); } } print_str (num_array); return width > num_width ? width : num_width; } /* printf_decimal () */ /* --------------------------------------------------------------------------*/ /*!Print a unsigned to a base in a width The number is always right justified and unsigned. @param[in] val The value to print @param[in] width The width to print in (at least) @param[in] leading_zeros_p 1 (TRUE) if we should print leading zeros, 0 (FALSE) otherwise @param[in] base Base to use when printing @return The number of chars printed */ /* --------------------------------------------------------------------------*/ static int printf_unsigned_base (unsigned long int val, int width, int leading_zeros_p, unsigned int base) { int is_signed_p = 0; /* Note if we need a sign */ if (val < 0) { val = -val; is_signed_p = 1; } /* Array to store the number in. We know the max for 32 bits of octal is 11 digits. Allow for end of string marker */ char num_array[12]; int num_width = print_base (val, num_array, base); /* Now print out the number. */ num_width += is_signed_p ? 1 : 0; if (num_width < width) { print_multichar (leading_zeros_p ? '0' : ' ', width - num_width); } print_str (num_array); return width > num_width ? width : num_width; } /* printf_unsigned_base () */ /* --------------------------------------------------------------------------*/ /*!Dummy exception handler Used for most exceptions as the default hander which does nothing. */ /* --------------------------------------------------------------------------*/ static void excpt_dummy() { } /* excpt_dummy ()*/ /*! Function to be called at entry point - not defined here. */ extern int main (); /* --------------------------------------------------------------------------*/ /*!Start function Called by reset exception handler. */ /* --------------------------------------------------------------------------*/ void reset () { exit (main ()); } /* reset () */ /* --------------------------------------------------------------------------*/ /*!Exit function Return value by making a syscall @param[in] rc Return code */ /* --------------------------------------------------------------------------*/ void exit (int rc) { __asm__ __volatile__ ("l.add r3,r0,%0\n\t" "l.nop %1": : "r" (rc), "K" (NOP_EXIT)); /* Header declares function as __noreturn, so ensure that is so. */ while (1) { } } /* exit () */ /* --------------------------------------------------------------------------*/ /*!Activate printing a character in the simulator @param[in] c The character to print @return The char printed cast to an int */ /* --------------------------------------------------------------------------*/ int putchar (int c) { __asm__ __volatile__ ("l.addi\tr3,%0,0\n\t" "l.nop %1": : "r" (c), "K" (NOP_PUTC)); return c; } /* putchar () */ /* --------------------------------------------------------------------------*/ /*!Print a string We need to define this, since the compiler will replace calls to printf using just constant strings with trailing newlines with calls to puts without the newline. @param[in] str The string to print (without a newline) @return The char printed cast to an int */ /* --------------------------------------------------------------------------*/ int puts (const char *str) { return printf ("%s\n", str); } /* puts () */ /* --------------------------------------------------------------------------*/ /*!Activate printf support in simulator @note This doesn't actually work, so we implement the basics of printf by steam, calling useful subsidiary functions based on putchar (), which does work. @param[in] fmt The format string @param[in] ... The variable arguments if any @return The number of characters printed */ /* --------------------------------------------------------------------------*/ int printf(const char *fmt, ...) { int num_chars = 0; /* How many chars printed */ va_list args; va_start (args, fmt); int i; /* Index into the string */ for (i = 0; fmt[i] != 0; i++) { if ('%' == fmt[i]) { int width; int leading_zeros_p; /* Decode the field */ i++; /* Are leading zeros requested? */ if ('0' == fmt[i]) { leading_zeros_p = 1; i++; } else { leading_zeros_p = 0; } /* Is there a width specification? */ width = 0; while (is_digit (fmt[i])) { width = width * 10 + fmt[i] - '0'; i++; } /* We just ignore any "l" specification. We do everything as 32-bit. */ i += ('l' == fmt[i]) ? 1 : 0; /* Deal with each field according to the type indicactor */ char ch; char *str; long int val; unsigned long int uval; /* There is a bug in GCC for OR1K, which can't handle two many cases. For now we split this into two disjoint case statements. */ switch (fmt[i]) { case 'c': ch = va_arg (args, int); num_chars += printf_char (ch, width); break; case 'o': uval = va_arg (args, unsigned long int); num_chars +=printf_unsigned_base (uval, width, leading_zeros_p, 8); break; case 's': str = va_arg (args, char *); num_chars += printf_str (str, width); break; case 'x': uval = va_arg (args, unsigned long int); num_chars += printf_unsigned_base (uval, width, leading_zeros_p, 16); break; default: /* Default is to do nothing silently */ break; } switch (fmt[i]) { case'd': case 'i': val = va_arg (args, long int); num_chars += printf_decimal (val, width, leading_zeros_p); break; } } else { putchar (fmt[i]); num_chars++; } } va_end (args); return num_chars; } /* printf () */ /* --------------------------------------------------------------------------*/ /*!Report a 32-bit value Uses the built-in simulator functionality. @param[in] value Value to report. */ /* --------------------------------------------------------------------------*/ void report (unsigned long int value) { __asm__ __volatile__ ("l.addi\tr3,%0,0\n\t" "l.nop %1": : "r" (value), "K" (NOP_REPORT)); } /* report () */ /* --------------------------------------------------------------------------*/ /*!Mutliply two 32-bit values to give a 64-bit result This is not supported by the OR1K GCC. Use the identity (ax + b).(cx + d) = ac.x^2 + (ad + bc).x + bd x = 2^16. None of this should overflow. @param[in] op1 First operand @param[in] op2 Second operand @return The result */ /* --------------------------------------------------------------------------*/ static unsigned long long int l_mulu (unsigned long int op1, unsigned long int op2) { unsigned long int a, b, c, d; a = op1 >> 16; b = op1 & 0xffff; c = op2 >> 16; d = op2 & 0xffff; /* Add in the terms */ unsigned long long int res; /* printf ("a = 0x%08lx, b = 0x%08lx, c = 0x%08lx, d = 0x%08lx\n", a, b, c, d); */ res = (unsigned long long int) (a * c) << 32; /* printf (" interim res = 0x%08lx%08lx\n", (unsigned long int) (res >> 32), */ /* (unsigned long int) res); */ res += ((unsigned long long int) (a * d) << 16); /* printf (" interim res = 0x%08lx%08lx\n", (unsigned long int) (res >> 32), */ /* (unsigned long int) res); */ res += ((unsigned long long int) (b * c) << 16); /* printf (" interim res = 0x%08lx%08lx\n", (unsigned long int) (res >> 32), */ /* (unsigned long int) res); */ res += (unsigned long long int) (b * d); /* printf (" interim res = 0x%08lx%08lx\n", (unsigned long int) (res >> 32), */ /* (unsigned long int) res); */ /* printf ("0x%08lx * 0x%08lx = 0x%08lx%08lx\n", op1, op2, */ /* (unsigned long int) (res >> 32), (unsigned long int) res); */ return res; } /* l_mulu () */ /* --------------------------------------------------------------------------*/ /*!Mutliply two 64-bit values This is not supported by the OR1K GCC. Use the identity (ax + b).(cx + d) = ac.x^2 + (ad + bc).x + bd x = 2^32. We can discard the first term (overflow), though since this is for testing we'll print a message. The second term may overflow, so we compute the coefficient to 64-bit to see if we have overflowed. The final term may overflow, so we also compute this to 64-bit, so we can add the top 64-bits in. @param[in] op1 First operand @param[in] op2 Second operand @return The result */ /* --------------------------------------------------------------------------*/ static unsigned long long int ll_mulu (unsigned long long int op1, unsigned long long int op2) { unsigned long int a, b, c, d; unsigned long long int tmp, res; a = op1 >> 32; b = op1 & 0xffffffff; c = op2 >> 32; d = op2 & 0xffffffff; if ((a > 0) && (c > 0)) { printf ("ll_mulu overflows\n"); } /* Compute and test the second term */ tmp = l_mulu (a, d); if (tmp >= 0x100000000ULL) { printf ("ll_mulu overflows\n"); } res = tmp << 32; tmp = l_mulu (b, c); if (tmp >= 0x100000000ULL) { printf ("ll_mulu overflows\n"); } res += tmp << 32; /* Compute the third term. Although the term can't overflow, it could overflow the result. So just check our answer is larger when the final term is added in. */ tmp = res; res += l_mulu (b, d); if (res < tmp) { printf ("ll_mulu overflows\n"); } /* printf ("0x%08lx%08lx * 0x%08lx%08lx = 0x%08lx%08lx\n", a, b, c, d, */ /* (unsigned long int) (res >> 32), (unsigned long int) res); */ return res; } /* ll_mulu () */ /* --------------------------------------------------------------------------*/ /*!Divide a 64-bit value by a 32 bit value Until I can get hold of a copy of Knuth volume 2 to check the algorithm, this is a bitwise version. @param[in] op1 First operand @param[in] op2 Second operand @return The result */ /* --------------------------------------------------------------------------*/ static unsigned long long int ll_divu (unsigned long long int dividend, unsigned long int divisor) { unsigned long long int t, num_bits; unsigned long long int q, bit, d; int i; if (divisor == 0) { printf ("ERROR: Invalid division by zero\n"); return 0; } if (divisor > dividend) { return 0; } if (divisor == dividend) { return 1ULL; } /* printf ("0x%08x%08x / 0x%08x = ", (unsigned int) (dividend >> 32), */ /* (unsigned int) (dividend & 0xffffffff), (unsigned int) divisor); */ num_bits = 64; unsigned long long int remainder = 0; unsigned long long int quotient = 0; while (remainder < divisor) { bit = (dividend & 0x8000000000000000ULL) >> 63; remainder = (remainder << 1) | bit; d = dividend; dividend = dividend << 1; num_bits--; } /* The loop, above, always goes one iteration too far. To avoid inserting an "if" statement inside the loop the last iteration is simply reversed. */ dividend = d; remainder = remainder >> 1; num_bits++; for (i = 0; i < num_bits; i++) { bit = (dividend & 0x8000000000000000ULL) >> 63; remainder = (remainder << 1) | bit; t = remainder - divisor; q = !((t & 0x8000000000000000ULL) >> 63); dividend = dividend << 1; quotient = (quotient << 1) | q; if (q) { remainder = t; } } /* printf ("0x%08x%08x\n", (unsigned int) (quotient >> 32), */ /* (unsigned int) (quotient & 0xffffffff)); */ return quotient; } /* ll_divu () */ /* --------------------------------------------------------------------------*/ /*!Read the simulator timer Uses the built-in simulator functionality to return the time in microseconds. @note Beware that this timer can wrap around. @return The time used since the simulator started. */ /* --------------------------------------------------------------------------*/ unsigned long int read_timer() { unsigned long int cycles_lo; unsigned long int cycles_hi; unsigned long int cycle_ps; unsigned long long int time_us; __asm__ __volatile__ ("l.nop\t\t%0" : : "K" (NOP_GET_TICKS)); __asm__ __volatile__ ("l.add\t\t%0,r0,r11": "=r" (cycles_lo) : ); __asm__ __volatile__ ("l.add\t\t%0,r0,r12": "=r" (cycles_hi) : ); __asm__ __volatile__ ("l.nop\t\t%0" : : "K" (NOP_GET_PS)); __asm__ __volatile__ ("l.add\t\t%0,r0,r11": "=r" (cycle_ps) : ); unsigned long long int cycles = ((unsigned long long int) cycles_hi << 32) | ((unsigned long long int) cycles_lo); /* This could overflow 64 bits, but if so then the result would overflow 32 bits. */ time_us = ll_mulu (cycles, (unsigned long long int) cycle_ps); time_us = ll_divu (time_us, 1000000UL); return (unsigned long int) time_us; } /* read_timer () */ /* --------------------------------------------------------------------------*/ /*!Write a SPR @todo Surely the SPR should be a short int, since it is only 16-bits. Left as is for now due to large amount of user code that might need changing. @param[in] spr The SPR to write @param[in] value The value to write to the SPR */ /* --------------------------------------------------------------------------*/ void mtspr (unsigned long int spr, unsigned long int value) { __asm__ __volatile__ ("l.mtspr\t\t%0,%1,0": : "r" (spr), "r" (value)); } /* mtspr () */ /* --------------------------------------------------------------------------*/ /*!Read a SPR @todo Surely the SPR should be a short int, since it is only 16-bits. Left as is for now due to large amount of user code that might need changing. @param[in] spr The SPR to write @return The value read from the SPR */ /* --------------------------------------------------------------------------*/ unsigned long int mfspr (unsigned long spr) { unsigned long value; __asm__ __volatile__ ("l.mfspr\t\t%0,%1,0" : "=r" (value) : "r" (spr)); return value; } /* mfspr () */ /* --------------------------------------------------------------------------*/ /*!Copy between regions of memory This should match the library version of memcpy @param[out] dstvoid Pointer to the destination memory area @param[in] srcvoid Pointer to the source memory area @param[in] length Number of bytes to copy. */ /* --------------------------------------------------------------------------*/ void * memcpy (void *__restrict dstvoid, __const void *__restrict srcvoid, size_t length) { char *dst = dstvoid; const char *src = (const char *) srcvoid; while (length--) { *dst++ = *src++; } return dst; } /* memcpy () */ /* --------------------------------------------------------------------------*/ /*!Pseudo-random number generator This should return pseudo-random numbers, based on a Galois LFSR @return The next pseudo-random number */ /* --------------------------------------------------------------------------*/ unsigned long int rand () { static unsigned long int lfsr = 1; static int period = 0; /* taps: 32 31 29 1; characteristic polynomial: x^32 + x^31 + x^29 + x + 1 */ lfsr = (lfsr >> 1) ^ (unsigned long int)((0 - (lfsr & 1u)) & 0xd0000001u); ++period; return lfsr; }
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