src/parsec/disk-image/parsec/parsec-benchmark/pkgs/libs/ssl/src/fips/fips_canister.c - public/gem5-resources - Git at Google

 /* ====================================================================
  * Copyright (c) 2005 The OpenSSL Project. Rights for redistribution
  * and usage in source and binary forms are granted according to the
  * OpenSSL license.
  */

 #include <stdio.h>
 #if defined(__DECC)
 # include <c_asm.h>
 # pragma __nostandard
 #endif

 #include "e_os.h"

 #if !defined(POINTER_TO_FUNCTION_IS_POINTER_TO_1ST_INSTRUCTION)
 # if	(defined(__sun) && (defined(__sparc) || defined(__sparcv9)))	|| \
 	(defined(__sgi) && (defined(__mips) || defined(mips)))		|| \
 	(defined(__osf__) && defined(__alpha))				|| \
 	(defined(__linux) && (defined(__arm) || defined(__arm__)))	|| \
 	(defined(__i386) || defined(__i386__))				|| \
 	(defined(__x86_64) || defined(__x86_64__))			|| \
 	(defined(vax) || defined(__vax__))
 #  define POINTER_TO_FUNCTION_IS_POINTER_TO_1ST_INSTRUCTION
 # endif
 #endif

 #if defined(__xlC__) && __xlC__>=0x600 && (defined(_POWER) || defined(_ARCH_PPC))
 static void *instruction_pointer_xlc(void);
 # pragma mc_func instruction_pointer_xlc {\
 	"7c0802a6"	/* mflr	r0  */	\
 	"48000005"	/* bl	$+4 */	\
 	"7c6802a6"	/* mflr	r3  */	\
 	"7c0803a6"	/* mtlr	r0  */	}
 # pragma reg_killed_by instruction_pointer_xlc gr0 gr3
 # define INSTRUCTION_POINTER_IMPLEMENTED(ret) (ret=instruction_pointer_xlc());
 #endif

 #ifdef FIPS_START
 #define FIPS_ref_point FIPS_text_start
 /* Some compilers put string literals into a separate segment. As we
  * are mostly interested to hash AES tables in .rodata, we declare
  * reference points accordingly. In case you wonder, the values are
  * big-endian encoded variable names, just to prevent these arrays
  * from being merged by linker. */
 const unsigned int FIPS_rodata_start[]=
 	{ 0x46495053, 0x5f726f64, 0x6174615f, 0x73746172 };
 #else
 #define FIPS_ref_point FIPS_text_end
 const unsigned int FIPS_rodata_end[]=
 	{ 0x46495053, 0x5f726f64, 0x6174615f, 0x656e645b };
 #endif

 /*
  * I declare reference function as static in order to avoid certain
  * pitfalls in -dynamic linker behaviour...
  */
 static void *instruction_pointer(void)
 { void *ret=NULL;
 /* These are ABI-neutral CPU-specific snippets. ABI-neutrality means
  * that they are designed to work under any OS running on particular
  * CPU, which is why you don't find any #ifdef THIS_OR_THAT_OS in
  * this function. */
 #if	defined(INSTRUCTION_POINTER_IMPLEMENTED)
     INSTRUCTION_POINTER_IMPLEMENTED(ret);
 #elif	defined(__GNUC__) && __GNUC__>=2
 # if	defined(__alpha) || defined(__alpha__)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     __asm __volatile (	"br	%0,1f\n1:" : "=r"(ret) );
 # elif	defined(__i386) || defined(__i386__)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     __asm __volatile (	"call 1f\n1:	popl %0" : "=r"(ret) );
     ret = (void *)((size_t)ret&~3UL); /* align for better performance */
 # elif	defined(__ia64) || defined(__ia64__)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     __asm __volatile (	"mov	%0=ip" : "=r"(ret) );
 # elif	defined(__hppa) || defined(__hppa__) || defined(__pa_risc)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     __asm __volatile (	"blr	%%r0,%0\n\tnop" : "=r"(ret) );
     ret = (void *)((size_t)ret&~3UL); /* mask privilege level */
 # elif	defined(__mips) || defined(__mips__)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     void *scratch;
     __asm __volatile (	"move	%1,$31\n\t"	/* save ra */
 			"bal	.+8; nop\n\t"
 			"move	%0,$31\n\t"
 			"move	$31,%1"		/* restore ra */
 			: "=r"(ret),"=r"(scratch) );
 # elif	defined(__ppc__) || defined(__powerpc) || defined(__powerpc__) || \
 	defined(__POWERPC__) || defined(_POWER) || defined(__PPC__) || \
 	defined(__PPC64__) || defined(__powerpc64__)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     void *scratch;
     __asm __volatile (	"mfspr	%1,8\n\t"	/* save lr */
 			"bl	$+4\n\t"
 			"mfspr	%0,8\n\t"	/* mflr ret */
 			"mtspr	8,%1"		/* restore lr */
 			: "=r"(ret),"=r"(scratch) );
 # elif	defined(__s390__) || defined(__s390x__)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     __asm __volatile (	"bras	%0,1f\n1:" : "=r"(ret) );
     ret = (void *)((size_t)ret&~3UL);
 # elif	defined(__sparc) || defined(__sparc__) || defined(__sparcv9)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     void *scratch;
     __asm __volatile (	"mov	%%o7,%1\n\t"
 			"call	.+8; nop\n\t"
 		  	"mov	%%o7,%0\n\t"
 			"mov	%1,%%o7"
 			: "=r"(ret),"=r"(scratch) );
 # elif	defined(__x86_64) || defined(__x86_64__)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     __asm __volatile (	"leaq	0(%%rip),%0" : "=r"(ret) );
     ret = (void *)((size_t)ret&~3UL); /* align for better performance */
 # endif
 #elif	defined(__DECC) && defined(__alpha)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     ret = (void *)(size_t)asm("br %v0,1f\n1:");
 #elif   defined(_MSC_VER) && defined(_M_IX86)
 #   define INSTRUCTION_POINTER_IMPLEMENTED
     void *scratch;
     _asm {
             call    self
     self:   pop     eax
             mov     scratch,eax
          }
     ret = (void *)((size_t)scratch&~3UL);
 #endif
   return ret;
 }

 /*
  * This function returns pointer to an instruction in the vicinity of
  * its entry point, but not outside this object module. This guarantees
  * that sequestered code is covered...
  */
 void *FIPS_ref_point()
 {
 #if	defined(INSTRUCTION_POINTER_IMPLEMENTED)
     return instruction_pointer();
 /* Below we essentially cover vendor compilers which do not support
  * inline assembler... */
 #elif	defined(_AIX)
     struct { void *ip,*gp,*env; } *p = (void *)instruction_pointer;
     return p->ip;
 #elif	defined(_HPUX_SOURCE)
 # if	defined(__hppa) || defined(__hppa__)
     struct { void *i[4]; } *p = (void *)FIPS_ref_point;

     if (sizeof(p) == 8)	/* 64-bit */
 	return p->i[2];
     else if ((size_t)p & 2)
     {	p = (void *)((size_t)p&~3UL);
 	return p->i[0];
     }
     else
 	return (void *)p;
 # elif	defined(__ia64) || defined(__ia64__)
     struct { unsigned long long ip,gp; } *p=(void *)instruction_pointer;
     return (void *)(size_t)p->ip;
 # endif
 #elif	(defined(__VMS) || defined(VMS)) && !(defined(vax) || defined(__vax__))
     /* applies to both alpha and ia64 */
     struct { unsigned __int64 opaque,ip; } *p=(void *)instruction_pointer;
     return (void *)(size_t)p->ip;
 #elif	defined(__VOS__)
     /* applies to both pa-risc and ia32 */
     struct { void *dp,*ip,*gp; } *p = (void *)instruction_pointer;
     return p->ip;
 #elif	defined(_WIN32)
 # if	defined(_WIN64) && defined(_M_IA64)
     struct { void *ip,*gp; } *p = (void *)FIPS_ref_point;
     return p->ip;
 # else
     return (void *)FIPS_ref_point;
 # endif
 /*
  * In case you wonder why there is no #ifdef __linux. All Linux targets
  * are GCC-based and therefore are covered by instruction_pointer above
  * [well, some are covered by by the one below]...
  */
 #elif	defined(POINTER_TO_FUNCTION_IS_POINTER_TO_1ST_INSTRUCTION)
     return (void *)instruction_pointer;
 #else
     return NULL;
 #endif
 }
	/* ====================================================================
	* Copyright (c) 2005 The OpenSSL Project. Rights for redistribution
	* and usage in source and binary forms are granted according to the
	* OpenSSL license.
	*/

	#include <stdio.h>
	#if defined(__DECC)
	# include <c_asm.h>
	# pragma __nostandard
	#endif

	#include "e_os.h"

	#if !defined(POINTER_TO_FUNCTION_IS_POINTER_TO_1ST_INSTRUCTION)
	# if (defined(__sun) && (defined(__sparc) \|\| defined(__sparcv9))) \|\| \
	(defined(__sgi) && (defined(__mips) \|\| defined(mips))) \|\| \
	(defined(__osf__) && defined(__alpha)) \|\| \
	(defined(__linux) && (defined(__arm) \|\| defined(__arm__))) \|\| \
	(defined(__i386) \|\| defined(__i386__)) \|\| \
	(defined(__x86_64) \|\| defined(__x86_64__)) \|\| \
	(defined(vax) \|\| defined(__vax__))
	# define POINTER_TO_FUNCTION_IS_POINTER_TO_1ST_INSTRUCTION
	# endif
	#endif

	#if defined(__xlC__) && __xlC__>=0x600 && (defined(_POWER) \|\| defined(_ARCH_PPC))
	static void *instruction_pointer_xlc(void);
	# pragma mc_func instruction_pointer_xlc {\
	"7c0802a6" /* mflr r0 */ \
	"48000005" /* bl $+4 */ \
	"7c6802a6" /* mflr r3 */ \
	"7c0803a6" /* mtlr r0 */ }
	# pragma reg_killed_by instruction_pointer_xlc gr0 gr3
	# define INSTRUCTION_POINTER_IMPLEMENTED(ret) (ret=instruction_pointer_xlc());
	#endif

	#ifdef FIPS_START
	#define FIPS_ref_point FIPS_text_start
	/* Some compilers put string literals into a separate segment. As we
	* are mostly interested to hash AES tables in .rodata, we declare
	* reference points accordingly. In case you wonder, the values are
	* big-endian encoded variable names, just to prevent these arrays
	* from being merged by linker. */
	const unsigned int FIPS_rodata_start[]=
	{ 0x46495053, 0x5f726f64, 0x6174615f, 0x73746172 };
	#else
	#define FIPS_ref_point FIPS_text_end
	const unsigned int FIPS_rodata_end[]=
	{ 0x46495053, 0x5f726f64, 0x6174615f, 0x656e645b };
	#endif

	/*
	* I declare reference function as static in order to avoid certain
	* pitfalls in -dynamic linker behaviour...
	*/
	static void *instruction_pointer(void)
	{ void *ret=NULL;
	/* These are ABI-neutral CPU-specific snippets. ABI-neutrality means
	* that they are designed to work under any OS running on particular
	* CPU, which is why you don't find any #ifdef THIS_OR_THAT_OS in
	* this function. */
	#if defined(INSTRUCTION_POINTER_IMPLEMENTED)
	INSTRUCTION_POINTER_IMPLEMENTED(ret);
	#elif defined(__GNUC__) && __GNUC__>=2
	# if defined(__alpha) \|\| defined(__alpha__)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	__asm __volatile ( "br %0,1f\n1:" : "=r"(ret) );
	# elif defined(__i386) \|\| defined(__i386__)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	__asm __volatile ( "call 1f\n1: popl %0" : "=r"(ret) );
	ret = (void )((size_t)ret&~3UL); / align for better performance */
	# elif defined(__ia64) \|\| defined(__ia64__)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	__asm __volatile ( "mov %0=ip" : "=r"(ret) );
	# elif defined(__hppa) \|\| defined(__hppa__) \|\| defined(__pa_risc)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	__asm __volatile ( "blr %%r0,%0\n\tnop" : "=r"(ret) );
	ret = (void )((size_t)ret&~3UL); / mask privilege level */
	# elif defined(__mips) \|\| defined(__mips__)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	void *scratch;
	__asm __volatile ( "move %1,$31\n\t" /* save ra */
	"bal .+8; nop\n\t"
	"move %0,$31\n\t"
	"move $31,%1" /* restore ra */
	: "=r"(ret),"=r"(scratch) );
	# elif defined(__ppc__) \|\| defined(__powerpc) \|\| defined(__powerpc__) \|\| \
	defined(__POWERPC__) \|\| defined(_POWER) \|\| defined(__PPC__) \|\| \
	defined(__PPC64__) \|\| defined(__powerpc64__)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	void *scratch;
	__asm __volatile ( "mfspr %1,8\n\t" /* save lr */
	"bl $+4\n\t"
	"mfspr %0,8\n\t" /* mflr ret */
	"mtspr 8,%1" /* restore lr */
	: "=r"(ret),"=r"(scratch) );
	# elif defined(__s390__) \|\| defined(__s390x__)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	__asm __volatile ( "bras %0,1f\n1:" : "=r"(ret) );
	ret = (void *)((size_t)ret&~3UL);
	# elif defined(__sparc) \|\| defined(__sparc__) \|\| defined(__sparcv9)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	void *scratch;
	__asm __volatile ( "mov %%o7,%1\n\t"
	"call .+8; nop\n\t"
	"mov %%o7,%0\n\t"
	"mov %1,%%o7"
	: "=r"(ret),"=r"(scratch) );
	# elif defined(__x86_64) \|\| defined(__x86_64__)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	__asm __volatile ( "leaq 0(%%rip),%0" : "=r"(ret) );
	ret = (void )((size_t)ret&~3UL); / align for better performance */
	# endif
	#elif defined(__DECC) && defined(__alpha)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	ret = (void *)(size_t)asm("br %v0,1f\n1:");
	#elif defined(_MSC_VER) && defined(_M_IX86)
	# define INSTRUCTION_POINTER_IMPLEMENTED
	void *scratch;
	_asm {
	call self
	self: pop eax
	mov scratch,eax
	}
	ret = (void *)((size_t)scratch&~3UL);
	#endif
	return ret;
	}

	/*
	* This function returns pointer to an instruction in the vicinity of
	* its entry point, but not outside this object module. This guarantees
	* that sequestered code is covered...
	*/
	void *FIPS_ref_point()
	{
	#if defined(INSTRUCTION_POINTER_IMPLEMENTED)
	return instruction_pointer();
	/* Below we essentially cover vendor compilers which do not support
	* inline assembler... */
	#elif defined(_AIX)
	struct { void ip,gp,env; } p = (void *)instruction_pointer;
	return p->ip;
	#elif defined(_HPUX_SOURCE)
	# if defined(__hppa) \|\| defined(__hppa__)
	struct { void i[4]; } p = (void *)FIPS_ref_point;

	if (sizeof(p) == 8) /* 64-bit */
	return p->i[2];
	else if ((size_t)p & 2)
	{ p = (void *)((size_t)p&~3UL);
	return p->i[0];
	}
	else
	return (void *)p;
	# elif defined(__ia64) \|\| defined(__ia64__)
	struct { unsigned long long ip,gp; } p=(void )instruction_pointer;
	return (void *)(size_t)p->ip;
	# endif
	#elif (defined(__VMS) \|\| defined(VMS)) && !(defined(vax) \|\| defined(__vax__))
	/* applies to both alpha and ia64 */
	struct { unsigned __int64 opaque,ip; } p=(void )instruction_pointer;
	return (void *)(size_t)p->ip;
	#elif defined(__VOS__)
	/* applies to both pa-risc and ia32 */
	struct { void dp,ip,gp; } p = (void *)instruction_pointer;
	return p->ip;
	#elif defined(_WIN32)
	# if defined(_WIN64) && defined(_M_IA64)
	struct { void ip,gp; } p = (void )FIPS_ref_point;
	return p->ip;
	# else
	return (void *)FIPS_ref_point;
	# endif
	/*
	* In case you wonder why there is no #ifdef __linux. All Linux targets
	* are GCC-based and therefore are covered by instruction_pointer above
	* [well, some are covered by by the one below]...
	*/
	#elif defined(POINTER_TO_FUNCTION_IS_POINTER_TO_1ST_INSTRUCTION)
	return (void *)instruction_pointer;
	#else
	return NULL;
	#endif
	}