s390x/emulator.c - kvm-unit-tests - Git at Google

 /*
  * Emulator tests - for s390x CPU instructions that are usually interpreted
  *                  by the hardware
  *
  * Copyright (c) 2017 Red Hat Inc
  *
  * Authors:
  *  David Hildenbrand <david@redhat.com>
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU Library General Public License version 2.
  */
 #include <libcflat.h>
 #include <asm/cpacf.h>
 #include <asm/interrupt.h>

 static inline void __test_spm_ipm(uint8_t cc, uint8_t key)
 {
 	uint64_t in = (cc << 28) | (key << 24);
 	uint64_t out = ~0ULL;

 	report_prefix_pushf("cc=%d,key=%x", cc, key);

 	asm volatile ("spm %1\n"
 		      "ipm %0\n"
 		      : "+r"(out) : "r"(in) : "cc");

 	report("bit 32 and 33 set to zero", !(out & 0xc0000000UL));
 	report("bit 0-31, 40-63 unchanged",
 		(out & ~0xff000000ULL) == ~0xff000000ULL);
 	report("cc and key applied", !((in ^ out) & 0x3f000000UL));

 	report_prefix_pop();
 }

 /* Test the SET PROGRAM PARAMETER and INSERT PROGRAM PARAMETER instruction */
 static void test_spm_ipm(void)
 {
 	__test_spm_ipm(0, 0xf);
 	__test_spm_ipm(1, 0x9);
 	__test_spm_ipm(2, 0x5);
 	__test_spm_ipm(3, 0x3);
 	__test_spm_ipm(0, 0);
 }

 static inline void __test_cpacf(unsigned int opcode, unsigned long func,
 				unsigned int r1, unsigned int r2,
 				unsigned int r3)
 {
 	register unsigned long gr0 asm("0") = func;
 	cpacf_mask_t mask;
 	register unsigned long gr1 asm("1") = (unsigned long)&mask;

 	asm volatile(".insn rrf,%[opc] << 16,%[r1],%[r2],%[r3],0\n"
 		     : : "d" (gr0), "d" (gr1), [opc] "i" (opcode),
 		         [r1] "i" (r1), [r2] "i" (r2), [r3] "i" (r3));
 }

 static inline void __test_cpacf_r1_odd(unsigned int opcode)
 {
 	report_prefix_push("r1 odd");
 	expect_pgm_int();
 	__test_cpacf(opcode, 0, 1, 4, 6);
 	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_r1_null(unsigned int opcode)
 {
 	report_prefix_push("r1 null");
 	expect_pgm_int();
 	__test_cpacf(opcode, 0, 0, 4, 6);
 	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_r2_odd(unsigned int opcode)
 {
 	report_prefix_push("r2 odd");
 	expect_pgm_int();
 	__test_cpacf(opcode, 0, 2, 3, 6);
 	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_r2_null(unsigned int opcode)
 {
 	report_prefix_push("r2 null");
 	expect_pgm_int();
 	__test_cpacf(opcode, 0, 2, 0, 6);
 	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_r3_odd(unsigned int opcode)
 {
 	report_prefix_push("r3 odd");
 	expect_pgm_int();
 	__test_cpacf(opcode, 0, 2, 4, 5);
 	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_r3_null(unsigned int opcode)
 {
 	report_prefix_push("r3 null");
 	expect_pgm_int();
 	__test_cpacf(opcode, 0, 2, 4, 0);
 	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_mod_bit(unsigned int opcode)
 {
 	report_prefix_push("mod bit");
 	expect_pgm_int();
 	__test_cpacf(opcode, CPACF_DECRYPT, 2, 4, 6);
 	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_invalid_func(unsigned int opcode)
 {
 	report_prefix_push("invalid subfunction");
 	expect_pgm_int();
 	/* 127 is unassigned for now. We don't simply use any, as HW
 	 * might simply mask valid codes in query but they might still work */
 	if (cpacf_query_func(opcode, 127)) {
 		report_skip("127 not invalid");
 	} else {
 		__test_cpacf(opcode, 127, 2, 4, 6);
 	}
 	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_invalid_parm(unsigned int opcode)
 {
 	report_prefix_push("invalid parm address");
 	expect_pgm_int();
 	__cpacf_query(opcode, (void *) -1);
 	check_pgm_int_code(PGM_INT_CODE_ADDRESSING);
 	report_prefix_pop();
 }

 static inline void __test_cpacf_protected_parm(unsigned int opcode)
 {
 	report_prefix_push("protected parm address");
 	expect_pgm_int();
 	low_prot_enable();
 	__cpacf_query(opcode, (void *) 8);
 	low_prot_disable();
 	check_pgm_int_code(PGM_INT_CODE_PROTECTION);
 	report_prefix_pop();
 }

 static inline void __test_basic_cpacf_opcode(unsigned int opcode)
 {
 	bool mod_bit_allowed = false;

 	if (!__cpacf_check_opcode(opcode)) {
 		report_skip("not available");
 		return;
 	}
 	report("query indicated in query", cpacf_query_func(opcode, 0));

 	switch (opcode) {
 	case CPACF_KMCTR:
 		__test_cpacf_r3_odd(opcode);
 		__test_cpacf_r3_null(opcode);
 		/* FALL THROUGH */
 	case CPACF_PRNO:
 	case CPACF_KMF:
 	case CPACF_KMC:
 	case CPACF_KMO:
 	case CPACF_KM:
 		__test_cpacf_r1_odd(opcode);
 		__test_cpacf_r1_null(opcode);
 		mod_bit_allowed = true;
 		/* FALL THROUGH */
 	case CPACF_KMAC:
 	case CPACF_KIMD:
 	case CPACF_KLMD:
 		__test_cpacf_r2_odd(opcode);
 		__test_cpacf_r2_null(opcode);
 	        break;
 	}
 	if (!mod_bit_allowed)
 		__test_cpacf_mod_bit(opcode);
 	__test_cpacf_invalid_func(opcode);
 	__test_cpacf_invalid_parm(opcode);
 	__test_cpacf_protected_parm(opcode);
 }

 /* COMPUTE MESSAGE AUTHENTICATION CODE */
 static void test_kmac(void)
 {
 	__test_basic_cpacf_opcode(CPACF_KMAC);
 }

 /* CIPHER MESSAGE */
 static void test_km(void)
 {
 	__test_basic_cpacf_opcode(CPACF_KM);
 }
 /* CIPHER MESSAGE WITH CHAINING */
 static void test_kmc(void)
 {
 	__test_basic_cpacf_opcode(CPACF_KMC);
 }

 /* COMPUTE INTERMEDIATE MESSAGE DIGEST */
 static void test_kimd(void)
 {
 	__test_basic_cpacf_opcode(CPACF_KIMD);
 }

 /* COMPUTE LAST MESSAGE DIGEST */
 static void test_klmd(void)
 {
 	__test_basic_cpacf_opcode(CPACF_KLMD);
 }

 /* PERFORM CRYPTOGRAPHIC KEY MANAGEMENT OPERATION */
 static void test_pckmo(void)
 {
 	__test_basic_cpacf_opcode(CPACF_PCKMO);
 }

 /* CIPHER MESSAGE WITH CIPHER FEEDBACK */
 static void test_kmf(void)
 {
 	__test_basic_cpacf_opcode(CPACF_KMF);
 }

 /* PERFORM CRYPTOGRAPHIC KEY MANAGEMENT OPERATION */
 static void test_kmo(void)
 {
 	__test_basic_cpacf_opcode(CPACF_KMO);
 }

 /* PERFORM CRYPTOGRAPHIC COMPUTATION */
 static void test_pcc(void)
 {
 	__test_basic_cpacf_opcode(CPACF_PCC);
 }

 /* CIPHER MESSAGE WITH COUNTER */
 static void test_kmctr(void)
 {
 	__test_basic_cpacf_opcode(CPACF_KMCTR);
 }

 /* PERFORM RANDOM NUMBER OPERATION (formerly PPNO) */
 static void test_prno(void)
 {
 	__test_basic_cpacf_opcode(CPACF_PRNO);
 }

 static struct {
 	const char *name;
 	void (*func)(void);
 } tests[] = {
 	{ "spm/ipm", test_spm_ipm },
 	{ "kmac", test_kmac },
 	{ "km", test_km },
 	{ "kmc", test_kmc },
 	{ "kimd", test_kimd },
 	{ "klmd", test_klmd },
 	{ "pckmo", test_pckmo },
 	{ "kmf", test_kmf },
 	{ "kmo", test_kmo },
 	{ "pcc", test_pcc },
 	{ "kmctr", test_kmctr },
 	{ "prno", test_prno },
 	{ NULL, NULL }
 };

 int main(int argc, char**argv)
 {
 	int i;

 	report_prefix_push("emulator");
 	for (i = 0; tests[i].name; i++) {
 		report_prefix_push(tests[i].name);
 		tests[i].func();
 		report_prefix_pop();
 	}
 	report_prefix_pop();

 	return report_summary();
 }
	/*
	* Emulator tests - for s390x CPU instructions that are usually interpreted
	* by the hardware
	*
	* Copyright (c) 2017 Red Hat Inc
	*
	* Authors:
	* David Hildenbrand <david@redhat.com>
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU Library General Public License version 2.
	*/
	#include <libcflat.h>
	#include <asm/cpacf.h>
	#include <asm/interrupt.h>

	static inline void __test_spm_ipm(uint8_t cc, uint8_t key)
	{
	uint64_t in = (cc << 28) \| (key << 24);
	uint64_t out = ~0ULL;

	report_prefix_pushf("cc=%d,key=%x", cc, key);

	asm volatile ("spm %1\n"
	"ipm %0\n"
	: "+r"(out) : "r"(in) : "cc");

	report("bit 32 and 33 set to zero", !(out & 0xc0000000UL));
	report("bit 0-31, 40-63 unchanged",
	(out & ~0xff000000ULL) == ~0xff000000ULL);
	report("cc and key applied", !((in ^ out) & 0x3f000000UL));

	report_prefix_pop();
	}

	/* Test the SET PROGRAM PARAMETER and INSERT PROGRAM PARAMETER instruction */
	static void test_spm_ipm(void)
	{
	__test_spm_ipm(0, 0xf);
	__test_spm_ipm(1, 0x9);
	__test_spm_ipm(2, 0x5);
	__test_spm_ipm(3, 0x3);
	__test_spm_ipm(0, 0);
	}

	static inline void __test_cpacf(unsigned int opcode, unsigned long func,
	unsigned int r1, unsigned int r2,
	unsigned int r3)
	{
	register unsigned long gr0 asm("0") = func;
	cpacf_mask_t mask;
	register unsigned long gr1 asm("1") = (unsigned long)&mask;

	asm volatile(".insn rrf,%[opc] << 16,%[r1],%[r2],%[r3],0\n"
	: : "d" (gr0), "d" (gr1), [opc] "i" (opcode),
	[r1] "i" (r1), [r2] "i" (r2), [r3] "i" (r3));
	}

	static inline void __test_cpacf_r1_odd(unsigned int opcode)
	{
	report_prefix_push("r1 odd");
	expect_pgm_int();
	__test_cpacf(opcode, 0, 1, 4, 6);
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
	report_prefix_pop();
	}

	static inline void __test_cpacf_r1_null(unsigned int opcode)
	{
	report_prefix_push("r1 null");
	expect_pgm_int();
	__test_cpacf(opcode, 0, 0, 4, 6);
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
	report_prefix_pop();
	}

	static inline void __test_cpacf_r2_odd(unsigned int opcode)
	{
	report_prefix_push("r2 odd");
	expect_pgm_int();
	__test_cpacf(opcode, 0, 2, 3, 6);
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
	report_prefix_pop();
	}

	static inline void __test_cpacf_r2_null(unsigned int opcode)
	{
	report_prefix_push("r2 null");
	expect_pgm_int();
	__test_cpacf(opcode, 0, 2, 0, 6);
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
	report_prefix_pop();
	}

	static inline void __test_cpacf_r3_odd(unsigned int opcode)
	{
	report_prefix_push("r3 odd");
	expect_pgm_int();
	__test_cpacf(opcode, 0, 2, 4, 5);
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
	report_prefix_pop();
	}

	static inline void __test_cpacf_r3_null(unsigned int opcode)
	{
	report_prefix_push("r3 null");
	expect_pgm_int();
	__test_cpacf(opcode, 0, 2, 4, 0);
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
	report_prefix_pop();
	}

	static inline void __test_cpacf_mod_bit(unsigned int opcode)
	{
	report_prefix_push("mod bit");
	expect_pgm_int();
	__test_cpacf(opcode, CPACF_DECRYPT, 2, 4, 6);
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
	report_prefix_pop();
	}

	static inline void __test_cpacf_invalid_func(unsigned int opcode)
	{
	report_prefix_push("invalid subfunction");
	expect_pgm_int();
	/* 127 is unassigned for now. We don't simply use any, as HW
	* might simply mask valid codes in query but they might still work */
	if (cpacf_query_func(opcode, 127)) {
	report_skip("127 not invalid");
	} else {
	__test_cpacf(opcode, 127, 2, 4, 6);
	}
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);
	report_prefix_pop();
	}

	static inline void __test_cpacf_invalid_parm(unsigned int opcode)
	{
	report_prefix_push("invalid parm address");
	expect_pgm_int();
	__cpacf_query(opcode, (void *) -1);
	check_pgm_int_code(PGM_INT_CODE_ADDRESSING);
	report_prefix_pop();
	}

	static inline void __test_cpacf_protected_parm(unsigned int opcode)
	{
	report_prefix_push("protected parm address");
	expect_pgm_int();
	low_prot_enable();
	__cpacf_query(opcode, (void *) 8);
	low_prot_disable();
	check_pgm_int_code(PGM_INT_CODE_PROTECTION);
	report_prefix_pop();
	}

	static inline void __test_basic_cpacf_opcode(unsigned int opcode)
	{
	bool mod_bit_allowed = false;

	if (!__cpacf_check_opcode(opcode)) {
	report_skip("not available");
	return;
	}
	report("query indicated in query", cpacf_query_func(opcode, 0));

	switch (opcode) {
	case CPACF_KMCTR:
	__test_cpacf_r3_odd(opcode);
	__test_cpacf_r3_null(opcode);
	/* FALL THROUGH */
	case CPACF_PRNO:
	case CPACF_KMF:
	case CPACF_KMC:
	case CPACF_KMO:
	case CPACF_KM:
	__test_cpacf_r1_odd(opcode);
	__test_cpacf_r1_null(opcode);
	mod_bit_allowed = true;
	/* FALL THROUGH */
	case CPACF_KMAC:
	case CPACF_KIMD:
	case CPACF_KLMD:
	__test_cpacf_r2_odd(opcode);
	__test_cpacf_r2_null(opcode);
	break;
	}
	if (!mod_bit_allowed)
	__test_cpacf_mod_bit(opcode);
	__test_cpacf_invalid_func(opcode);
	__test_cpacf_invalid_parm(opcode);
	__test_cpacf_protected_parm(opcode);
	}

	/* COMPUTE MESSAGE AUTHENTICATION CODE */
	static void test_kmac(void)
	{
	__test_basic_cpacf_opcode(CPACF_KMAC);
	}

	/* CIPHER MESSAGE */
	static void test_km(void)
	{
	__test_basic_cpacf_opcode(CPACF_KM);
	}
	/* CIPHER MESSAGE WITH CHAINING */
	static void test_kmc(void)
	{
	__test_basic_cpacf_opcode(CPACF_KMC);
	}

	/* COMPUTE INTERMEDIATE MESSAGE DIGEST */
	static void test_kimd(void)
	{
	__test_basic_cpacf_opcode(CPACF_KIMD);
	}

	/* COMPUTE LAST MESSAGE DIGEST */
	static void test_klmd(void)
	{
	__test_basic_cpacf_opcode(CPACF_KLMD);
	}

	/* PERFORM CRYPTOGRAPHIC KEY MANAGEMENT OPERATION */
	static void test_pckmo(void)
	{
	__test_basic_cpacf_opcode(CPACF_PCKMO);
	}

	/* CIPHER MESSAGE WITH CIPHER FEEDBACK */
	static void test_kmf(void)
	{
	__test_basic_cpacf_opcode(CPACF_KMF);
	}

	/* PERFORM CRYPTOGRAPHIC KEY MANAGEMENT OPERATION */
	static void test_kmo(void)
	{
	__test_basic_cpacf_opcode(CPACF_KMO);
	}

	/* PERFORM CRYPTOGRAPHIC COMPUTATION */
	static void test_pcc(void)
	{
	__test_basic_cpacf_opcode(CPACF_PCC);
	}

	/* CIPHER MESSAGE WITH COUNTER */
	static void test_kmctr(void)
	{
	__test_basic_cpacf_opcode(CPACF_KMCTR);
	}

	/* PERFORM RANDOM NUMBER OPERATION (formerly PPNO) */
	static void test_prno(void)
	{
	__test_basic_cpacf_opcode(CPACF_PRNO);
	}

	static struct {
	const char *name;
	void (*func)(void);
	} tests[] = {
	{ "spm/ipm", test_spm_ipm },
	{ "kmac", test_kmac },
	{ "km", test_km },
	{ "kmc", test_kmc },
	{ "kimd", test_kimd },
	{ "klmd", test_klmd },
	{ "pckmo", test_pckmo },
	{ "kmf", test_kmf },
	{ "kmo", test_kmo },
	{ "pcc", test_pcc },
	{ "kmctr", test_kmctr },
	{ "prno", test_prno },
	{ NULL, NULL }
	};

	int main(int argc, char**argv)
	{
	int i;

	report_prefix_push("emulator");
	for (i = 0; tests[i].name; i++) {
	report_prefix_push(tests[i].name);
	tests[i].func();
	report_prefix_pop();
	}
	report_prefix_pop();

	return report_summary();
	}