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

 /* SPDX-License-Identifier: GPL-2.0-only */
 /*
  * EPSW Interception Tests
  *
  * Copyright IBM Corp. 2022
  *
  * Authors:
  *  Nico Boehr <nrb@linux.ibm.com>
  */
 #include <libcflat.h>
 #include <css.h>
 #include <hardware.h>

 static uint32_t zero_out_cc_from_epsw_op1(uint32_t epsw_op1)
 {
 	return epsw_op1 & ~GENMASK(31 - 18, 31 - 20);
 }

 static void generate_crw(void)
 {
 	int test_device_sid = css_enumerate();
 	int cc, ret;

 	if (!(test_device_sid & SCHID_ONE)) {
 		report_fail("No I/O device found");
 		return;
 	}

 	cc = css_enable(test_device_sid, IO_SCH_ISC);
 	report(cc == 0, "Enable subchannel %08x", test_device_sid);

 	ret = css_generate_crw(test_device_sid);
 	if (ret)
 		report_fail("Couldn't generate CRW");
 }

 static void test_epsw(void)
 {
 	const uint64_t MAGIC1 = 0x1234567890abcdefUL;
 	const uint64_t MAGIC2 = 0xcafedeadbeeffaceUL;

 	uint64_t op1 = MAGIC1;
 	uint64_t op2 = MAGIC2;
 	uint32_t prev_epsw_op1;

 	/*
 	 * having machine check interrupts masked and pending CRW ensures
 	 * EPSW is intercepted under KVM
 	 */
 	generate_crw();

 	report_prefix_push("both operands given");
 	asm volatile(
 		"epsw %0, %1\n"
 		: "+&d" (op1), "+&a" (op2));
 	report(upper_32_bits(op1) == upper_32_bits(MAGIC1) &&
 	       upper_32_bits(op2) == upper_32_bits(MAGIC2),
 	       "upper 32 bits unmodified");
 	report(lower_32_bits(op1) != lower_32_bits(MAGIC1) &&
 	       lower_32_bits(op2) != lower_32_bits(MAGIC2),
 	       "lower 32 bits modified");
 	prev_epsw_op1 = zero_out_cc_from_epsw_op1(lower_32_bits(op1));
 	report_prefix_pop();

 	report_prefix_push("second operand 0");
 	op1 = MAGIC1;
 	op2 = MAGIC2;
 	asm volatile(
 		"	lgr 0,%[op2]\n"
 		"	epsw %[op1], 0\n"
 		"	lgr %[op2],0\n"
 		: [op2] "+&d" (op2), [op1] "+&a" (op1)
 		:
 		: "0");
 	report(upper_32_bits(op1) == upper_32_bits(MAGIC1),
 	       "upper 32 bits of first operand unmodified");
 	report(zero_out_cc_from_epsw_op1(lower_32_bits(op1)) == prev_epsw_op1,
 	       "first operand matches previous reading");
 	report(op2 == MAGIC2, "r0 unmodified");
 	report_prefix_pop();

 	report_prefix_push("both operands 0");
 	op1 = MAGIC1;
 	asm volatile(
 		"	lgr 0,%[op1]\n"
 		"	epsw 0, 0\n"
 		"	lgr %[op1],0\n"
 		: [op1] "+&d" (op1)
 		:
 		: "0");
 	report(upper_32_bits(op1) == upper_32_bits(MAGIC1),
 	       "upper 32 bits of first operand unmodified");
 	report(zero_out_cc_from_epsw_op1(lower_32_bits(op1)) == prev_epsw_op1,
 	       "first operand matches previous reading");
 	report_prefix_pop();
 }

 int main(int argc, char **argv)
 {
 	report_prefix_push("epsw");

 	if (!host_is_kvm() && !host_is_tcg()) {
 		report_skip("Not running under QEMU");
 		goto done;
 	}

 	test_epsw();

 done:
 	report_prefix_pop();

 	return report_summary();
 }
	/* SPDX-License-Identifier: GPL-2.0-only */
	/*
	* EPSW Interception Tests
	*
	* Copyright IBM Corp. 2022
	*
	* Authors:
	* Nico Boehr <nrb@linux.ibm.com>
	*/
	#include <libcflat.h>
	#include <css.h>
	#include <hardware.h>

	static uint32_t zero_out_cc_from_epsw_op1(uint32_t epsw_op1)
	{
	return epsw_op1 & ~GENMASK(31 - 18, 31 - 20);
	}

	static void generate_crw(void)
	{
	int test_device_sid = css_enumerate();
	int cc, ret;

	if (!(test_device_sid & SCHID_ONE)) {
	report_fail("No I/O device found");
	return;
	}

	cc = css_enable(test_device_sid, IO_SCH_ISC);
	report(cc == 0, "Enable subchannel %08x", test_device_sid);

	ret = css_generate_crw(test_device_sid);
	if (ret)
	report_fail("Couldn't generate CRW");
	}

	static void test_epsw(void)
	{
	const uint64_t MAGIC1 = 0x1234567890abcdefUL;
	const uint64_t MAGIC2 = 0xcafedeadbeeffaceUL;

	uint64_t op1 = MAGIC1;
	uint64_t op2 = MAGIC2;
	uint32_t prev_epsw_op1;

	/*
	* having machine check interrupts masked and pending CRW ensures
	* EPSW is intercepted under KVM
	*/
	generate_crw();

	report_prefix_push("both operands given");
	asm volatile(
	"epsw %0, %1\n"
	: "+&d" (op1), "+&a" (op2));
	report(upper_32_bits(op1) == upper_32_bits(MAGIC1) &&
	upper_32_bits(op2) == upper_32_bits(MAGIC2),
	"upper 32 bits unmodified");
	report(lower_32_bits(op1) != lower_32_bits(MAGIC1) &&
	lower_32_bits(op2) != lower_32_bits(MAGIC2),
	"lower 32 bits modified");
	prev_epsw_op1 = zero_out_cc_from_epsw_op1(lower_32_bits(op1));
	report_prefix_pop();

	report_prefix_push("second operand 0");
	op1 = MAGIC1;
	op2 = MAGIC2;
	asm volatile(
	" lgr 0,%[op2]\n"
	" epsw %[op1], 0\n"
	" lgr %[op2],0\n"
	: [op2] "+&d" (op2), [op1] "+&a" (op1)
	:
	: "0");
	report(upper_32_bits(op1) == upper_32_bits(MAGIC1),
	"upper 32 bits of first operand unmodified");
	report(zero_out_cc_from_epsw_op1(lower_32_bits(op1)) == prev_epsw_op1,
	"first operand matches previous reading");
	report(op2 == MAGIC2, "r0 unmodified");
	report_prefix_pop();

	report_prefix_push("both operands 0");
	op1 = MAGIC1;
	asm volatile(
	" lgr 0,%[op1]\n"
	" epsw 0, 0\n"
	" lgr %[op1],0\n"
	: [op1] "+&d" (op1)
	:
	: "0");
	report(upper_32_bits(op1) == upper_32_bits(MAGIC1),
	"upper 32 bits of first operand unmodified");
	report(zero_out_cc_from_epsw_op1(lower_32_bits(op1)) == prev_epsw_op1,
	"first operand matches previous reading");
	report_prefix_pop();
	}

	int main(int argc, char **argv)
	{
	report_prefix_push("epsw");

	if (!host_is_kvm() && !host_is_tcg()) {
	report_skip("Not running under QEMU");
	goto done;
	}

	test_epsw();

	done:
	report_prefix_pop();

	return report_summary();
	}