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The binary GCD algorithm is based on the following facts: 1. If a and b are all evens, then gcd(a,b) = 2 * gcd(a/2, b/2) 2. If a is even and b is odd, then gcd(a,b) = gcd(a/2, b) 3. If a and b are all odds, then gcd(a,b) = gcd((a-b)/2, b) = gcd((a+b)/2, b) Even on x86 machines with reasonable division hardware, the binary algorithm runs about 25% faster (80% the execution time) than the division-based Euclidian algorithm. On platforms like Alpha and ARMv6 where division is a function call to emulation code, it's even more significant. There are two variants of the code here, depending on whether a fast __ffs (find least significant set bit) instruction is available. This allows the unpredictable branches in the bit-at-a-time shifting loop to be eliminated. If fast __ffs is not available, the "even/odd" GCD variant is used. I use the following code to benchmark: #include <stdio.h> #include <stdlib.h> #include <stdint.h> #include <string.h> #include <time.h> #include <unistd.h> #define swap(a, b) \ do { \ a ^= b; \ b ^= a; \ a ^= b; \ } while (0) unsigned long gcd0(unsigned long a, unsigned long b) { unsigned long r; if (a < b) { swap(a, b); } if (b == 0) return a; while ((r = a % b) != 0) { a = b; b = r; } return b; } unsigned long gcd1(unsigned long a, unsigned long b) { unsigned long r = a | b; if (!a || !b) return r; b >>= __builtin_ctzl(b); for (;;) { a >>= __builtin_ctzl(a); if (a == b) return a << __builtin_ctzl(r); if (a < b) swap(a, b); a -= b; } } unsigned long gcd2(unsigned long a, unsigned long b) { unsigned long r = a | b; if (!a || !b) return r; r &= -r; while (!(b & r)) b >>= 1; for (;;) { while (!(a & r)) a >>= 1; if (a == b) return a; if (a < b) swap(a, b); a -= b; a >>= 1; if (a & r) a += b; a >>= 1; } } unsigned long gcd3(unsigned long a, unsigned long b) { unsigned long r = a | b; if (!a || !b) return r; b >>= __builtin_ctzl(b); if (b == 1) return r & -r; for (;;) { a >>= __builtin_ctzl(a); if (a == 1) return r & -r; if (a == b) return a << __builtin_ctzl(r); if (a < b) swap(a, b); a -= b; } } unsigned long gcd4(unsigned long a, unsigned long b) { unsigned long r = a | b; if (!a || !b) return r; r &= -r; while (!(b & r)) b >>= 1; if (b == r) return r; for (;;) { while (!(a & r)) a >>= 1; if (a == r) return r; if (a == b) return a; if (a < b) swap(a, b); a -= b; a >>= 1; if (a & r) a += b; a >>= 1; } } static unsigned long (*gcd_func[])(unsigned long a, unsigned long b) = { gcd0, gcd1, gcd2, gcd3, gcd4, }; #define TEST_ENTRIES (sizeof(gcd_func) / sizeof(gcd_func[0])) #if defined(__x86_64__) #define rdtscll(val) do { \ unsigned long __a,__d; \ __asm__ __volatile__("rdtsc" : "=a" (__a), "=d" (__d)); \ (val) = ((unsigned long long)__a) | (((unsigned long long)__d)<<32); \ } while(0) static unsigned long long benchmark_gcd_func(unsigned long (*gcd)(unsigned long, unsigned long), unsigned long a, unsigned long b, unsigned long *res) { unsigned long long start, end; unsigned long long ret; unsigned long gcd_res; rdtscll(start); gcd_res = gcd(a, b); rdtscll(end); if (end >= start) ret = end - start; else ret = ~0ULL - start + 1 + end; *res = gcd_res; return ret; } #else static inline struct timespec read_time(void) { struct timespec time; clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time); return time; } static inline unsigned long long diff_time(struct timespec start, struct timespec end) { struct timespec temp; if ((end.tv_nsec - start.tv_nsec) < 0) { temp.tv_sec = end.tv_sec - start.tv_sec - 1; temp.tv_nsec = 1000000000ULL + end.tv_nsec - start.tv_nsec; } else { temp.tv_sec = end.tv_sec - start.tv_sec; temp.tv_nsec = end.tv_nsec - start.tv_nsec; } return temp.tv_sec * 1000000000ULL + temp.tv_nsec; } static unsigned long long benchmark_gcd_func(unsigned long (*gcd)(unsigned long, unsigned long), unsigned long a, unsigned long b, unsigned long *res) { struct timespec start, end; unsigned long gcd_res; start = read_time(); gcd_res = gcd(a, b); end = read_time(); *res = gcd_res; return diff_time(start, end); } #endif static inline unsigned long get_rand() { if (sizeof(long) == 8) return (unsigned long)rand() << 32 | rand(); else return rand(); } int main(int argc, char **argv) { unsigned int seed = time(0); int loops = 100; int repeats = 1000; unsigned long (*res)[TEST_ENTRIES]; unsigned long long elapsed[TEST_ENTRIES]; int i, j, k; for (;;) { int opt = getopt(argc, argv, "n:r:s:"); /* End condition always first */ if (opt == -1) break; switch (opt) { case 'n': loops = atoi(optarg); break; case 'r': repeats = atoi(optarg); break; case 's': seed = strtoul(optarg, NULL, 10); break; default: /* You won't actually get here. */ break; } } res = malloc(sizeof(unsigned long) * TEST_ENTRIES * loops); memset(elapsed, 0, sizeof(elapsed)); srand(seed); for (j = 0; j < loops; j++) { unsigned long a = get_rand(); /* Do we have args? */ unsigned long b = argc > optind ? strtoul(argv[optind], NULL, 10) : get_rand(); unsigned long long min_elapsed[TEST_ENTRIES]; for (k = 0; k < repeats; k++) { for (i = 0; i < TEST_ENTRIES; i++) { unsigned long long tmp = benchmark_gcd_func(gcd_func[i], a, b, &res[j][i]); if (k == 0 || min_elapsed[i] > tmp) min_elapsed[i] = tmp; } } for (i = 0; i < TEST_ENTRIES; i++) elapsed[i] += min_elapsed[i]; } for (i = 0; i < TEST_ENTRIES; i++) printf("gcd%d: elapsed %llu\n", i, elapsed[i]); k = 0; srand(seed); for (j = 0; j < loops; j++) { unsigned long a = get_rand(); unsigned long b = argc > optind ? strtoul(argv[optind], NULL, 10) : get_rand(); for (i = 1; i < TEST_ENTRIES; i++) { if (res[j][i] != res[j][0]) break; } if (i < TEST_ENTRIES) { if (k == 0) { k = 1; fprintf(stderr, "Error:\n"); } fprintf(stderr, "gcd(%lu, %lu): ", a, b); for (i = 0; i < TEST_ENTRIES; i++) fprintf(stderr, "%ld%s", res[j][i], i < TEST_ENTRIES - 1 ? ", " : "\n"); } } if (k == 0) fprintf(stderr, "PASS\n"); free(res); return 0; } Compiled with "-O2", on "VirtualBox 4.4.0-22-generic #38-Ubuntu x86_64" got: zhaoxiuzeng@zhaoxiuzeng-VirtualBox:~/develop$ ./gcd -r 500000 -n 10 gcd0: elapsed 10174 gcd1: elapsed 2120 gcd2: elapsed 2902 gcd3: elapsed 2039 gcd4: elapsed 2812 PASS zhaoxiuzeng@zhaoxiuzeng-VirtualBox:~/develop$ ./gcd -r 500000 -n 10 gcd0: elapsed 9309 gcd1: elapsed 2280 gcd2: elapsed 2822 gcd3: elapsed 2217 gcd4: elapsed 2710 PASS zhaoxiuzeng@zhaoxiuzeng-VirtualBox:~/develop$ ./gcd -r 500000 -n 10 gcd0: elapsed 9589 gcd1: elapsed 2098 gcd2: elapsed 2815 gcd3: elapsed 2030 gcd4: elapsed 2718 PASS zhaoxiuzeng@zhaoxiuzeng-VirtualBox:~/develop$ ./gcd -r 500000 -n 10 gcd0: elapsed 9914 gcd1: elapsed 2309 gcd2: elapsed 2779 gcd3: elapsed 2228 gcd4: elapsed 2709 PASS [akpm@linux-foundation.org: avoid #defining a CONFIG_ variable] Signed-off-by: Zhaoxiu Zeng <zhaoxiu.zeng@gmail.com> Signed-off-by: George Spelvin <linux@horizon.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
500 lines
12 KiB
Plaintext
500 lines
12 KiB
Plaintext
comment "Processor Type"
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choice
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prompt "CPU family support"
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default M68KCLASSIC if MMU
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default COLDFIRE if !MMU
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help
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The Freescale (was Motorola) M68K family of processors implements
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the full 68000 processor instruction set.
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The Freescale ColdFire family of processors is a modern derivative
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of the 68000 processor family. They are mainly targeted at embedded
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applications, and are all System-On-Chip (SOC) devices, as opposed
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to stand alone CPUs. They implement a subset of the original 68000
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processor instruction set.
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If you anticipate running this kernel on a computer with a classic
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MC68xxx processor, select M68KCLASSIC.
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If you anticipate running this kernel on a computer with a ColdFire
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processor, select COLDFIRE.
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config M68KCLASSIC
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bool "Classic M68K CPU family support"
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config COLDFIRE
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bool "Coldfire CPU family support"
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select ARCH_HAVE_CUSTOM_GPIO_H
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select CPU_HAS_NO_BITFIELDS
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select CPU_HAS_NO_MULDIV64
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select GENERIC_CSUM
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select GPIOLIB
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select HAVE_CLK
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endchoice
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if M68KCLASSIC
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config M68000
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bool "MC68000"
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depends on !MMU
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select CPU_HAS_NO_BITFIELDS
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select CPU_HAS_NO_MULDIV64
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select CPU_HAS_NO_UNALIGNED
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select GENERIC_CSUM
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select CPU_NO_EFFICIENT_FFS
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help
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The Freescale (was Motorola) 68000 CPU is the first generation of
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the well known M68K family of processors. The CPU core as well as
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being available as a stand alone CPU was also used in many
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System-On-Chip devices (eg 68328, 68302, etc). It does not contain
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a paging MMU.
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config MCPU32
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bool
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select CPU_HAS_NO_BITFIELDS
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select CPU_HAS_NO_UNALIGNED
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select CPU_NO_EFFICIENT_FFS
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help
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The Freescale (was then Motorola) CPU32 is a CPU core that is
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based on the 68020 processor. For the most part it is used in
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System-On-Chip parts, and does not contain a paging MMU.
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config M68020
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bool "68020 support"
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depends on MMU
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select CPU_HAS_ADDRESS_SPACES
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help
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If you anticipate running this kernel on a computer with a MC68020
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processor, say Y. Otherwise, say N. Note that the 68020 requires a
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68851 MMU (Memory Management Unit) to run Linux/m68k, except on the
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Sun 3, which provides its own version.
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config M68030
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bool "68030 support"
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depends on MMU && !MMU_SUN3
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select CPU_HAS_ADDRESS_SPACES
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help
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If you anticipate running this kernel on a computer with a MC68030
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processor, say Y. Otherwise, say N. Note that a MC68EC030 will not
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work, as it does not include an MMU (Memory Management Unit).
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config M68040
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bool "68040 support"
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depends on MMU && !MMU_SUN3
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select CPU_HAS_ADDRESS_SPACES
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help
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If you anticipate running this kernel on a computer with a MC68LC040
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or MC68040 processor, say Y. Otherwise, say N. Note that an
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MC68EC040 will not work, as it does not include an MMU (Memory
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Management Unit).
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config M68060
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bool "68060 support"
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depends on MMU && !MMU_SUN3
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select CPU_HAS_ADDRESS_SPACES
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help
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If you anticipate running this kernel on a computer with a MC68060
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processor, say Y. Otherwise, say N.
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config M68328
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bool "MC68328"
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depends on !MMU
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select M68000
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help
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Motorola 68328 processor support.
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config M68EZ328
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bool "MC68EZ328"
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depends on !MMU
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select M68000
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help
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Motorola 68EX328 processor support.
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config M68VZ328
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bool "MC68VZ328"
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depends on !MMU
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select M68000
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help
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Motorola 68VZ328 processor support.
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endif # M68KCLASSIC
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if COLDFIRE
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choice
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prompt "ColdFire SoC type"
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default M520x
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help
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Select the type of ColdFire System-on-Chip (SoC) that you want
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to build for.
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config M5206
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bool "MCF5206"
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depends on !MMU
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select COLDFIRE_SW_A7
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Motorola ColdFire 5206 processor support.
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config M5206e
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bool "MCF5206e"
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depends on !MMU
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select COLDFIRE_SW_A7
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Motorola ColdFire 5206e processor support.
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config M520x
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bool "MCF520x"
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depends on !MMU
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select GENERIC_CLOCKEVENTS
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select HAVE_CACHE_SPLIT
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help
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Freescale Coldfire 5207/5208 processor support.
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config M523x
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bool "MCF523x"
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depends on !MMU
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select GENERIC_CLOCKEVENTS
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select HAVE_CACHE_SPLIT
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select HAVE_IPSBAR
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help
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Freescale Coldfire 5230/1/2/4/5 processor support
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config M5249
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bool "MCF5249"
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depends on !MMU
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select COLDFIRE_SW_A7
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Motorola ColdFire 5249 processor support.
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config M525x
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bool "MCF525x"
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depends on !MMU
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select COLDFIRE_SW_A7
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Freescale (Motorola) Coldfire 5251/5253 processor support.
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config M5271
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bool "MCF5271"
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depends on !MMU
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select M527x
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select HAVE_CACHE_SPLIT
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select HAVE_IPSBAR
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select GENERIC_CLOCKEVENTS
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help
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Freescale (Motorola) ColdFire 5270/5271 processor support.
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config M5272
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bool "MCF5272"
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depends on !MMU
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select COLDFIRE_SW_A7
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Motorola ColdFire 5272 processor support.
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config M5275
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bool "MCF5275"
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depends on !MMU
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select M527x
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select HAVE_CACHE_SPLIT
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select HAVE_IPSBAR
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select GENERIC_CLOCKEVENTS
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help
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Freescale (Motorola) ColdFire 5274/5275 processor support.
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config M528x
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bool "MCF528x"
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depends on !MMU
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select GENERIC_CLOCKEVENTS
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select HAVE_CACHE_SPLIT
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select HAVE_IPSBAR
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help
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Motorola ColdFire 5280/5282 processor support.
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config M5307
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bool "MCF5307"
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depends on !MMU
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select COLDFIRE_SW_A7
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select HAVE_CACHE_CB
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Motorola ColdFire 5307 processor support.
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config M532x
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bool "MCF532x"
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depends on !MMU
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select M53xx
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select HAVE_CACHE_CB
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help
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Freescale (Motorola) ColdFire 532x processor support.
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config M537x
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bool "MCF537x"
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depends on !MMU
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select M53xx
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select HAVE_CACHE_CB
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help
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Freescale ColdFire 537x processor support.
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config M5407
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bool "MCF5407"
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depends on !MMU
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select COLDFIRE_SW_A7
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select HAVE_CACHE_CB
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Motorola ColdFire 5407 processor support.
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config M547x
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bool "MCF547x"
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select M54xx
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select MMU_COLDFIRE if MMU
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select HAVE_CACHE_CB
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Freescale ColdFire 5470/5471/5472/5473/5474/5475 processor support.
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config M548x
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bool "MCF548x"
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select MMU_COLDFIRE if MMU
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select M54xx
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select HAVE_CACHE_CB
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select HAVE_MBAR
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select CPU_NO_EFFICIENT_FFS
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help
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Freescale ColdFire 5480/5481/5482/5483/5484/5485 processor support.
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config M5441x
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bool "MCF5441x"
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depends on !MMU
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select GENERIC_CLOCKEVENTS
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select HAVE_CACHE_CB
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help
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Freescale Coldfire 54410/54415/54416/54417/54418 processor support.
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endchoice
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config M527x
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bool
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config M53xx
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bool
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config M54xx
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bool
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endif # COLDFIRE
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comment "Processor Specific Options"
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config M68KFPU_EMU
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bool "Math emulation support"
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depends on MMU
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help
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At some point in the future, this will cause floating-point math
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instructions to be emulated by the kernel on machines that lack a
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floating-point math coprocessor. Thrill-seekers and chronically
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sleep-deprived psychotic hacker types can say Y now, everyone else
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should probably wait a while.
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config M68KFPU_EMU_EXTRAPREC
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bool "Math emulation extra precision"
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depends on M68KFPU_EMU
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help
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The fpu uses normally a few bit more during calculations for
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correct rounding, the emulator can (often) do the same but this
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extra calculation can cost quite some time, so you can disable
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it here. The emulator will then "only" calculate with a 64 bit
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mantissa and round slightly incorrect, what is more than enough
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for normal usage.
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config M68KFPU_EMU_ONLY
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bool "Math emulation only kernel"
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depends on M68KFPU_EMU
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help
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This option prevents any floating-point instructions from being
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compiled into the kernel, thereby the kernel doesn't save any
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floating point context anymore during task switches, so this
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kernel will only be usable on machines without a floating-point
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math coprocessor. This makes the kernel a bit faster as no tests
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needs to be executed whether a floating-point instruction in the
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kernel should be executed or not.
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config ADVANCED
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bool "Advanced configuration options"
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depends on MMU
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---help---
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This gives you access to some advanced options for the CPU. The
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defaults should be fine for most users, but these options may make
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it possible for you to improve performance somewhat if you know what
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you are doing.
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Note that the answer to this question won't directly affect the
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kernel: saying N will just cause the configurator to skip all
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the questions about these options.
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Most users should say N to this question.
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config RMW_INSNS
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bool "Use read-modify-write instructions"
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depends on ADVANCED
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---help---
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This allows to use certain instructions that work with indivisible
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read-modify-write bus cycles. While this is faster than the
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workaround of disabling interrupts, it can conflict with DMA
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( = direct memory access) on many Amiga systems, and it is also said
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to destabilize other machines. It is very likely that this will
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cause serious problems on any Amiga or Atari Medusa if set. The only
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configuration where it should work are 68030-based Ataris, where it
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apparently improves performance. But you've been warned! Unless you
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really know what you are doing, say N. Try Y only if you're quite
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adventurous.
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config SINGLE_MEMORY_CHUNK
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bool "Use one physical chunk of memory only" if ADVANCED && !SUN3
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depends on MMU
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default y if SUN3
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select NEED_MULTIPLE_NODES
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help
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Ignore all but the first contiguous chunk of physical memory for VM
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purposes. This will save a few bytes kernel size and may speed up
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some operations. Say N if not sure.
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config ARCH_DISCONTIGMEM_ENABLE
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def_bool MMU && !SINGLE_MEMORY_CHUNK
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config 060_WRITETHROUGH
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bool "Use write-through caching for 68060 supervisor accesses"
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depends on ADVANCED && M68060
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---help---
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The 68060 generally uses copyback caching of recently accessed data.
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Copyback caching means that memory writes will be held in an on-chip
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cache and only written back to memory some time later. Saying Y
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here will force supervisor (kernel) accesses to use writethrough
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caching. Writethrough caching means that data is written to memory
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straight away, so that cache and memory data always agree.
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Writethrough caching is less efficient, but is needed for some
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drivers on 68060 based systems where the 68060 bus snooping signal
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is hardwired on. The 53c710 SCSI driver is known to suffer from
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this problem.
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config M68K_L2_CACHE
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bool
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depends on MAC
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default y
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config NODES_SHIFT
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int
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default "3"
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depends on !SINGLE_MEMORY_CHUNK
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config CPU_HAS_NO_BITFIELDS
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bool
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config CPU_HAS_NO_MULDIV64
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bool
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config CPU_HAS_NO_UNALIGNED
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bool
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config CPU_HAS_ADDRESS_SPACES
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bool
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config FPU
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bool
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config COLDFIRE_SW_A7
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bool
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config HAVE_CACHE_SPLIT
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bool
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config HAVE_CACHE_CB
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bool
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config HAVE_MBAR
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bool
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config HAVE_IPSBAR
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bool
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config CLOCK_FREQ
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int "Set the core clock frequency"
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default "25000000" if M5206
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default "54000000" if M5206e
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default "166666666" if M520x
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default "140000000" if M5249
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default "150000000" if M527x || M523x
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default "90000000" if M5307
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default "50000000" if M5407
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default "266000000" if M54xx
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default "66666666"
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depends on COLDFIRE
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help
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Define the CPU clock frequency in use. This is the core clock
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frequency, it may or may not be the same as the external clock
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crystal fitted to your board. Some processors have an internal
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PLL and can have their frequency programmed at run time, others
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use internal dividers. In general the kernel won't setup a PLL
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if it is fitted (there are some exceptions). This value will be
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specific to the exact CPU that you are using.
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config OLDMASK
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bool "Old mask 5307 (1H55J) silicon"
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depends on M5307
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help
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Build support for the older revision ColdFire 5307 silicon.
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Specifically this is the 1H55J mask revision.
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if HAVE_CACHE_SPLIT
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choice
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prompt "Split Cache Configuration"
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default CACHE_I
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config CACHE_I
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bool "Instruction"
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help
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Use all of the ColdFire CPU cache memory as an instruction cache.
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config CACHE_D
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bool "Data"
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help
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Use all of the ColdFire CPU cache memory as a data cache.
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config CACHE_BOTH
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bool "Both"
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help
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Split the ColdFire CPU cache, and use half as an instruction cache
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and half as a data cache.
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endchoice
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endif
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if HAVE_CACHE_CB
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choice
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prompt "Data cache mode"
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default CACHE_WRITETHRU
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config CACHE_WRITETHRU
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bool "Write-through"
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help
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The ColdFire CPU cache is set into Write-through mode.
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config CACHE_COPYBACK
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bool "Copy-back"
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help
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The ColdFire CPU cache is set into Copy-back mode.
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endchoice
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endif
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