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

 /* SPDX-License-Identifier: GPL-2.0-only */
 /*
  * Channel Subsystem tests
  *
  * Copyright (c) 2020 IBM Corp
  *
  * Authors:
  *  Pierre Morel <pmorel@linux.ibm.com>
  */

 #include <libcflat.h>
 #include <interrupt.h>
 #include <hardware.h>

 #include <asm/arch_def.h>
 #include <asm/page.h>

 #include <malloc_io.h>
 #include <css.h>

 #define DEFAULT_CU_TYPE		0x3832 /* virtio-ccw */
 static unsigned long cu_type = DEFAULT_CU_TYPE;

 static int test_device_sid;
 static struct senseid *senseid;
 struct ccw1 *ccw;

 char alignment_test_page[PAGE_SIZE] __attribute__((aligned(PAGE_SIZE)));

 static void test_enumerate(void)
 {
 	test_device_sid = css_enumerate();
 	if (test_device_sid & SCHID_ONE) {
 		report_pass("Schid of first I/O device: 0x%08x", test_device_sid);
 		return;
 	}
 	report_fail("No I/O device found");
 }

 static void test_enable(void)
 {
 	int cc;

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	cc = css_enable(test_device_sid, IO_SCH_ISC);

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

 /*
  * test_sense
  * Pre-requisites:
  * - We need the test device as the first recognized
  *   device by the enumeration.
  */
 static void test_sense(void)
 {
 	int ret;
 	int len;

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	ret = css_enable(test_device_sid, IO_SCH_ISC);
 	if (ret) {
 		report_fail("Could not enable the subchannel: %08x",
 			    test_device_sid);
 		return;
 	}

 	lowcore.io_int_param = 0;

 	senseid = alloc_io_mem(sizeof(*senseid), 0);
 	if (!senseid) {
 		report_fail("Allocation of senseid");
 		return;
 	}

 	ccw = ccw_alloc(CCW_CMD_SENSE_ID, senseid, sizeof(*senseid), CCW_F_SLI);
 	if (!ccw) {
 		report_fail("Allocation of CCW");
 		goto error_ccw;
 	}

 	ret = start_ccw1_chain(test_device_sid, ccw);
 	if (ret) {
 		report_fail("Starting CCW chain");
 		goto error;
 	}

 	if (wait_and_check_io_completion(test_device_sid) < 0)
 		goto error;

 	/* Test transfer completion */
 	report_prefix_push("ssch transfer completion");

 	ret = css_residual_count(test_device_sid);

 	if (ret < 0) {
 		report_info("no valid residual count");
 	} else if (ret != 0) {
 		len = sizeof(*senseid) - ret;
 		if (ret && len < CSS_SENSEID_COMMON_LEN) {
 			report_fail("transferred a too short length: %d", ret);
 			goto error;
 		} else if (ret && len)
 			report_info("transferred a shorter length: %d", len);
 	}

 	if (senseid->reserved != 0xff) {
 		report_fail("transferred garbage: 0x%02x", senseid->reserved);
 		goto error;
 	}

 	report_prefix_pop();

 	report_info("reserved 0x%02x cu_type 0x%04x cu_model 0x%02x dev_type 0x%04x dev_model 0x%02x",
 		    senseid->reserved, senseid->cu_type, senseid->cu_model,
 		    senseid->dev_type, senseid->dev_model);

 	report(senseid->cu_type == cu_type, "cu_type expected 0x%04x got 0x%04x",
 	       (uint16_t)cu_type, senseid->cu_type);

 error:
 	free_io_mem(ccw, sizeof(*ccw));
 error_ccw:
 	free_io_mem(senseid, sizeof(*senseid));
 }

 static void sense_id(void)
 {
 	assert(!start_ccw1_chain(test_device_sid, ccw));

 	assert(wait_and_check_io_completion(test_device_sid) >= 0);
 }

 static void css_init(void)
 {
 	assert(register_io_int_func(css_irq_io) == 0);
 	lowcore.io_int_param = 0;

 	report(get_chsc_scsc(), "Store Channel Characteristics");
 }

 static void test_schm(void)
 {
 	if (css_test_general_feature(CSSC_EXTENDED_MEASUREMENT_BLOCK))
 		report_info("Extended measurement block available");

 	/* bits 59-63 of MB address must be 0  if MBU is defined */
 	report_prefix_push("Unaligned operand");
 	expect_pgm_int();
 	schm((void *)0x01, SCHM_MBU);
 	check_pgm_int_code(PGM_INT_CODE_OPERAND);
 	report_prefix_pop();

 	/* bits 36-61 of register 1 (flags) must be 0 */
 	report_prefix_push("Bad flags");
 	expect_pgm_int();
 	schm(NULL, 0xfffffffc);
 	check_pgm_int_code(PGM_INT_CODE_OPERAND);
 	report_prefix_pop();

 	/* SCHM is a privilege operation */
 	report_prefix_push("Privilege");
 	enter_pstate();
 	expect_pgm_int();
 	schm(NULL, SCHM_MBU);
 	check_pgm_int_code(PGM_INT_CODE_PRIVILEGED_OPERATION);
 	report_prefix_pop();

 	/* Normal operation */
 	report_prefix_push("Normal operation");
 	schm(NULL, SCHM_MBU);
 	report_pass("SCHM call without address");
 	report_prefix_pop();
 }

 #define SCHM_UPDATE_CNT 10
 static bool start_measuring(uint64_t mbo, uint16_t mbi, bool fmt1)
 {
 	int i;

 	senseid = alloc_io_mem(sizeof(*senseid), 0);
 	assert(senseid);

 	ccw = ccw_alloc(CCW_CMD_SENSE_ID, senseid, sizeof(*senseid), CCW_F_SLI);
 	assert(ccw);

 	if (!css_enable_mb(test_device_sid, mbo, mbi, PMCW_MBUE, fmt1)) {
 		report_abort("Enabling measurement block failed");
 		return false;
 	}

 	for (i = 0; i < SCHM_UPDATE_CNT; i++)
 		sense_id();

 	free_io_mem(ccw, sizeof(*ccw));
 	free_io_mem(senseid, sizeof(*senseid));

 	return true;
 }

 /*
  * test_schm_fmt0:
  * With measurement block format 0 a memory space is shared
  * by all subchannels, each subchannel can provide an index
  * for the measurement block facility to store the measurements.
  */
 static void test_schm_fmt0(void)
 {
 	struct measurement_block_format0 *mb0;
 	int shared_mb_size = 2 * sizeof(struct measurement_block_format0);

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	/* Allocate zeroed Measurement block */
 	mb0 = alloc_io_mem(shared_mb_size, 0);
 	if (!mb0) {
 		report_abort("measurement_block_format0 allocation failed");
 		return;
 	}

 	schm(NULL, 0); /* Stop any previous measurement */
 	schm(mb0, SCHM_MBU);

 	/* Expect success */
 	report_prefix_push("Valid MB address and index 0");
 	report(start_measuring(0, 0, false) &&
 	       mb0->ssch_rsch_count == SCHM_UPDATE_CNT,
 	       "SSCH measured %d", mb0->ssch_rsch_count);
 	report_prefix_pop();

 	/* Clear the measurement block for the next test */
 	memset(mb0, 0, shared_mb_size);

 	/* Expect success */
 	report_prefix_push("Valid MB address and index 1");
 	if (start_measuring(0, 1, false))
 		report(mb0[1].ssch_rsch_count == SCHM_UPDATE_CNT,
 		       "SSCH measured %d", mb0[1].ssch_rsch_count);
 	report_prefix_pop();

 	/* Stop the measurement */
 	css_disable_mb(test_device_sid);
 	schm(NULL, 0);

 	free_io_mem(mb0, shared_mb_size);
 }

 static void msch_with_wrong_fmt1_mbo(unsigned int schid, uint64_t mb)
 {
 	struct pmcw *pmcw = &schib.pmcw;
 	int cc;

 	/* Read the SCHIB for this subchannel */
 	cc = stsch(schid, &schib);
 	if (cc) {
 		report_fail("stsch: sch %08x failed with cc=%d", schid, cc);
 		return;
 	}

 	/* Update the SCHIB to enable the measurement block */
 	pmcw->flags |= PMCW_MBUE;
 	pmcw->flags2 |= PMCW_MBF1;
 	schib.mbo = mb;

 	/* Tell the CSS we want to modify the subchannel */
 	expect_pgm_int();
 	cc = msch(schid, &schib);
 	check_pgm_int_code(PGM_INT_CODE_OPERAND);
 }

 /*
  * test_schm_fmt1:
  * With measurement block format 1 the measurement block is
  * dedicated to a subchannel.
  */
 static void test_schm_fmt1(void)
 {
 	struct measurement_block_format1 *mb1;

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	if (!css_test_general_feature(CSSC_EXTENDED_MEASUREMENT_BLOCK)) {
 		report_skip("Extended measurement block not available");
 		return;
 	}

 	/* Allocate zeroed Measurement block */
 	mb1 = alloc_io_mem(sizeof(struct measurement_block_format1), 0);
 	if (!mb1) {
 		report_abort("measurement_block_format1 allocation failed");
 		return;
 	}

 	schm(NULL, 0); /* Stop any previous measurement */
 	schm(0, SCHM_MBU);

 	/* Expect error for non aligned MB */
 	report_prefix_push("Unaligned MB origin");
 	msch_with_wrong_fmt1_mbo(test_device_sid, (uint64_t)mb1 + 1);
 	report_prefix_pop();

 	/* Clear the measurement block for the next test */
 	memset(mb1, 0, sizeof(*mb1));

 	/* Expect success */
 	report_prefix_push("Valid MB origin");
 	if (start_measuring((u64)mb1, 0, true))
 		report(mb1->ssch_rsch_count == SCHM_UPDATE_CNT,
 		       "SSCH measured %d", mb1->ssch_rsch_count);
 	report_prefix_pop();

 	/* Stop the measurement */
 	css_disable_mb(test_device_sid);
 	schm(NULL, 0);

 	free_io_mem(mb1, sizeof(struct measurement_block_format1));
 }

 static void test_msch(void)
 {
 	int invalid_pmcw_flags[] = {0, 1, 6, 7};
 	struct schib test_schib;
 	uint16_t old_pmcw_flags;
 	const int align_to = 4;
 	int invalid_flag;
 	int cc;

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	cc = stsch(test_device_sid, &schib);
 	if (cc) {
 		report_fail("stsch: sch %08x failed with cc=%d", test_device_sid, cc);
 		return;
 	}

 	report_prefix_push("Unaligned");
 	for (int i = 1; i < align_to; i *= 2) {
 		report_prefix_pushf("%d", i);

 		expect_pgm_int();
 		msch(test_device_sid, (struct schib *)(alignment_test_page + i));
 		check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

 		report_prefix_pop();
 	}
 	report_prefix_pop();

 	report_prefix_push("Invalid SCHIB");
 	old_pmcw_flags = schib.pmcw.flags;
 	for (int i = 0; i < ARRAY_SIZE(invalid_pmcw_flags); i++) {
 		invalid_flag = invalid_pmcw_flags[i];

 		report_prefix_pushf("PMCW flag bit %d set", invalid_flag);

 		schib.pmcw.flags = old_pmcw_flags | BIT(15 - invalid_flag);
 		expect_pgm_int();
 		msch(test_device_sid, &schib);
 		check_pgm_int_code(PGM_INT_CODE_OPERAND);

 		cc = stsch(test_device_sid, &test_schib);
 		report(!cc, "STSCH succeeded");
 		report(!(test_schib.pmcw.flags & BIT(15 - invalid_flag)), "Clear on STSCH");

 		report_prefix_pop();
 	}
 	report_prefix_pop();

 	schib.pmcw.flags = old_pmcw_flags;
 }

 static void check_stcrw_no_crw_available(void)
 {
 	uint32_t crw = 0xfeedc0fe;
 	int cc;

 	report_prefix_push("No CRW available");
 	cc = stcrw(&crw);
 	report(cc == 1, "cc == 1");
 	report(!crw, "stored zeroes in crw");
 	report_prefix_pop();
 }

 static int check_stcrw_crw_available(void)
 {
 	const uint32_t magic = 0xfeedc0fe;
 	uint32_t crw = magic;
 	int cc;

 	report_prefix_push("CRW available");
 	cc = stcrw(&crw);
 	report(!cc, "cc is zero");
 	report(crw != magic, "stored crw");
 	report_prefix_pop();

 	return crw;
 }

 static uint32_t crw_get_rsc(uint32_t crw)
 {
 	const int rsc_begin = 4;
 	const int rsc_end = 8;

 	return (crw & GENMASK(31 - rsc_begin, 31 - rsc_end)) >> 24;
 }

 #define CRW_RSC_CHP 4
 static void test_stcrw(void)
 {
 	const int align_to = 4;
 	int res;
 	uint32_t crw;

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	report_prefix_push("Unaligned");
 	for (int i = 1; i < align_to; i *= 2) {
 		report_prefix_pushf("%d", i);

 		expect_pgm_int();
 		stcrw((uint32_t *)(alignment_test_page + i));
 		check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

 		report_prefix_pop();
 	}
 	report_prefix_pop();

 	report_prefix_push("No CRW available initally");
 	check_stcrw_no_crw_available();
 	report_prefix_pop();

 	res = css_generate_crw(test_device_sid);
 	if (res) {
 		report_skip("Couldn't generate CRW");
 		report_prefix_pop();
 		return;
 	}

 	crw = check_stcrw_crw_available();

 	report_prefix_push("CRW available");
 	report(crw_get_rsc(crw) == CRW_RSC_CHP, "CRW has Channel Path RSC");
 	report_prefix_pop();

 	report_prefix_push("No more CRWs pending");
 	check_stcrw_no_crw_available();
 	report_prefix_pop();
 }

 static void test_ssch(void)
 {
 	const int align_to = 4;
 	struct orb orb;

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	report_prefix_push("Unaligned");
 	for (int i = 1; i < align_to; i *= 2) {
 		report_prefix_pushf("%d", i);

 		expect_pgm_int();
 		ssch(test_device_sid, (struct orb *)(alignment_test_page + i));
 		check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

 		report_prefix_pop();
 	}
 	report_prefix_pop();

 	report_prefix_push("Invalid ORB");

 	memset(&orb, 0xff, sizeof(orb));
 	expect_pgm_int();
 	ssch(test_device_sid, &orb);
 	check_pgm_int_code(PGM_INT_CODE_OPERAND);

 	report_prefix_pop();
 }

 static void test_stsch(void)
 {
 	const int align_to = 4;
 	struct schib schib;
 	int cc;

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	report_prefix_push("Unaligned");
 	for (int i = 1; i < align_to; i *= 2) {
 		report_prefix_pushf("%d", i);

 		expect_pgm_int();
 		stsch(test_device_sid, (struct schib *)(alignment_test_page + i));
 		check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

 		report_prefix_pop();
 	}
 	report_prefix_pop();

 	report_prefix_push("Invalid subchannel number");
 	cc = stsch(0x0001ffff, &schib);
 	report(cc == 3, "Channel not operational");
 	report_prefix_pop();

 	/*
 	 * No matter if multiple-subchannel-set facility is installed, bit 47
 	 * always needs to be 1.
 	 */
 	report_prefix_push("Bit 47 in SID is zero");
 	expect_pgm_int();
 	stsch(0x0000ffff, &schib);
 	check_pgm_int_code(PGM_INT_CODE_OPERAND);
 	report_prefix_pop();
 }

 /*
  * According to architecture MSCH does ignore bit 5 of the second word
  * but STSCH will store bit 5 as zero.
  */
 static void test_pmcw_bit5(void)
 {
 	int cc;
 	uint16_t old_pmcw_flags;

 	cc = stsch(test_device_sid, &schib);
 	if (cc) {
 		report_fail("stsch: sch %08x failed with cc=%d", test_device_sid, cc);
 		return;
 	}
 	old_pmcw_flags = schib.pmcw.flags;

 	report_prefix_push("Bit 5 set");

 	schib.pmcw.flags = old_pmcw_flags | BIT(15 - 5);
 	cc = msch(test_device_sid, &schib);
 	report(!cc, "MSCH cc == 0");

 	cc = stsch(test_device_sid, &schib);
 	report(!cc, "STSCH cc == 0");
 	report(!(schib.pmcw.flags & BIT(15 - 5)), "STSCH PMCW Bit 5 is clear");

 	report_prefix_pop();

 	report_prefix_push("Bit 5 clear");

 	schib.pmcw.flags = old_pmcw_flags & ~BIT(15 - 5);
 	cc = msch(test_device_sid, &schib);
 	report(!cc, "MSCH cc == 0");

 	cc = stsch(test_device_sid, &schib);
 	report(!cc, "STSCH cc == 0");
 	report(!(schib.pmcw.flags & BIT(15 - 5)), "STSCH PMCW Bit 5 is clear");

 	report_prefix_pop();
 }

 static void test_tsch(void)
 {
 	const int align_to = 4;
 	struct irb irb;
 	int cc;

 	if (!test_device_sid) {
 		report_skip("No device");
 		return;
 	}

 	report_prefix_push("Unaligned");
 	for (int i = 1; i < align_to; i *= 2) {
 		report_prefix_pushf("%d", i);

 		expect_pgm_int();
 		tsch(test_device_sid, (struct irb *)(alignment_test_page + i));
 		check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

 		report_prefix_pop();
 	}
 	report_prefix_pop();

 	report_prefix_push("Invalid subchannel number");
 	cc = tsch(0x0001ffff, &irb);
 	report(cc == 3, "Channel not operational");
 	report_prefix_pop();

 	report_prefix_push("Bit 47 in SID is zero");
 	expect_pgm_int();
 	tsch(0x0000ffff, &irb);
 	check_pgm_int_code(PGM_INT_CODE_OPERAND);
 	report_prefix_pop();
 }

 static struct {
 	const char *name;
 	void (*func)(void);
 } tests[] = {
 	/* The css_init test is needed to initialize the CSS Characteristics */
 	{ "initialize CSS (chsc)", css_init },
 	{ "enumerate (stsch)", test_enumerate },
 	{ "enable (msch)", test_enable },
 	{ "sense (ssch/tsch)", test_sense },
 	{ "measurement block (schm)", test_schm },
 	{ "measurement block format0", test_schm_fmt0 },
 	{ "measurement block format1", test_schm_fmt1 },
 	{ "msch", test_msch },
 	{ "stcrw", test_stcrw },
 	{ "ssch", test_ssch },
 	{ "stsch", test_stsch },
 	{ "pmcw bit 5 ignored", test_pmcw_bit5 },
 	{ "tsch", test_tsch },
 	{ NULL, NULL }
 };

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

 	report_prefix_push("Channel Subsystem");

 	/* There's no guarantee where our devices are without qemu */
 	if (!host_is_qemu()) {
 		report_skip("Not running under QEMU");
 		goto done;
 	}

 	enable_io_isc(0x80 >> IO_SCH_ISC);
 	for (i = 0; tests[i].name; i++) {
 		report_prefix_push(tests[i].name);
 		tests[i].func();
 		report_prefix_pop();
 	}

 done:
 	report_prefix_pop();
 	return report_summary();
 }
	/* SPDX-License-Identifier: GPL-2.0-only */
	/*
	* Channel Subsystem tests
	*
	* Copyright (c) 2020 IBM Corp
	*
	* Authors:
	* Pierre Morel <pmorel@linux.ibm.com>
	*/

	#include <libcflat.h>
	#include <interrupt.h>
	#include <hardware.h>

	#include <asm/arch_def.h>
	#include <asm/page.h>

	#include <malloc_io.h>
	#include <css.h>

	#define DEFAULT_CU_TYPE 0x3832 /* virtio-ccw */
	static unsigned long cu_type = DEFAULT_CU_TYPE;

	static int test_device_sid;
	static struct senseid *senseid;
	struct ccw1 *ccw;

	char alignment_test_page[PAGE_SIZE] __attribute__((aligned(PAGE_SIZE)));

	static void test_enumerate(void)
	{
	test_device_sid = css_enumerate();
	if (test_device_sid & SCHID_ONE) {
	report_pass("Schid of first I/O device: 0x%08x", test_device_sid);
	return;
	}
	report_fail("No I/O device found");
	}

	static void test_enable(void)
	{
	int cc;

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	cc = css_enable(test_device_sid, IO_SCH_ISC);

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

	/*
	* test_sense
	* Pre-requisites:
	* - We need the test device as the first recognized
	* device by the enumeration.
	*/
	static void test_sense(void)
	{
	int ret;
	int len;

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	ret = css_enable(test_device_sid, IO_SCH_ISC);
	if (ret) {
	report_fail("Could not enable the subchannel: %08x",
	test_device_sid);
	return;
	}

	lowcore.io_int_param = 0;

	senseid = alloc_io_mem(sizeof(*senseid), 0);
	if (!senseid) {
	report_fail("Allocation of senseid");
	return;
	}

	ccw = ccw_alloc(CCW_CMD_SENSE_ID, senseid, sizeof(*senseid), CCW_F_SLI);
	if (!ccw) {
	report_fail("Allocation of CCW");
	goto error_ccw;
	}

	ret = start_ccw1_chain(test_device_sid, ccw);
	if (ret) {
	report_fail("Starting CCW chain");
	goto error;
	}

	if (wait_and_check_io_completion(test_device_sid) < 0)
	goto error;

	/* Test transfer completion */
	report_prefix_push("ssch transfer completion");

	ret = css_residual_count(test_device_sid);

	if (ret < 0) {
	report_info("no valid residual count");
	} else if (ret != 0) {
	len = sizeof(*senseid) - ret;
	if (ret && len < CSS_SENSEID_COMMON_LEN) {
	report_fail("transferred a too short length: %d", ret);
	goto error;
	} else if (ret && len)
	report_info("transferred a shorter length: %d", len);
	}

	if (senseid->reserved != 0xff) {
	report_fail("transferred garbage: 0x%02x", senseid->reserved);
	goto error;
	}

	report_prefix_pop();

	report_info("reserved 0x%02x cu_type 0x%04x cu_model 0x%02x dev_type 0x%04x dev_model 0x%02x",
	senseid->reserved, senseid->cu_type, senseid->cu_model,
	senseid->dev_type, senseid->dev_model);

	report(senseid->cu_type == cu_type, "cu_type expected 0x%04x got 0x%04x",
	(uint16_t)cu_type, senseid->cu_type);

	error:
	free_io_mem(ccw, sizeof(*ccw));
	error_ccw:
	free_io_mem(senseid, sizeof(*senseid));
	}

	static void sense_id(void)
	{
	assert(!start_ccw1_chain(test_device_sid, ccw));

	assert(wait_and_check_io_completion(test_device_sid) >= 0);
	}

	static void css_init(void)
	{
	assert(register_io_int_func(css_irq_io) == 0);
	lowcore.io_int_param = 0;

	report(get_chsc_scsc(), "Store Channel Characteristics");
	}

	static void test_schm(void)
	{
	if (css_test_general_feature(CSSC_EXTENDED_MEASUREMENT_BLOCK))
	report_info("Extended measurement block available");

	/* bits 59-63 of MB address must be 0 if MBU is defined */
	report_prefix_push("Unaligned operand");
	expect_pgm_int();
	schm((void *)0x01, SCHM_MBU);
	check_pgm_int_code(PGM_INT_CODE_OPERAND);
	report_prefix_pop();

	/* bits 36-61 of register 1 (flags) must be 0 */
	report_prefix_push("Bad flags");
	expect_pgm_int();
	schm(NULL, 0xfffffffc);
	check_pgm_int_code(PGM_INT_CODE_OPERAND);
	report_prefix_pop();

	/* SCHM is a privilege operation */
	report_prefix_push("Privilege");
	enter_pstate();
	expect_pgm_int();
	schm(NULL, SCHM_MBU);
	check_pgm_int_code(PGM_INT_CODE_PRIVILEGED_OPERATION);
	report_prefix_pop();

	/* Normal operation */
	report_prefix_push("Normal operation");
	schm(NULL, SCHM_MBU);
	report_pass("SCHM call without address");
	report_prefix_pop();
	}

	#define SCHM_UPDATE_CNT 10
	static bool start_measuring(uint64_t mbo, uint16_t mbi, bool fmt1)
	{
	int i;

	senseid = alloc_io_mem(sizeof(*senseid), 0);
	assert(senseid);

	ccw = ccw_alloc(CCW_CMD_SENSE_ID, senseid, sizeof(*senseid), CCW_F_SLI);
	assert(ccw);

	if (!css_enable_mb(test_device_sid, mbo, mbi, PMCW_MBUE, fmt1)) {
	report_abort("Enabling measurement block failed");
	return false;
	}

	for (i = 0; i < SCHM_UPDATE_CNT; i++)
	sense_id();

	free_io_mem(ccw, sizeof(*ccw));
	free_io_mem(senseid, sizeof(*senseid));

	return true;
	}

	/*
	* test_schm_fmt0:
	* With measurement block format 0 a memory space is shared
	* by all subchannels, each subchannel can provide an index
	* for the measurement block facility to store the measurements.
	*/
	static void test_schm_fmt0(void)
	{
	struct measurement_block_format0 *mb0;
	int shared_mb_size = 2 * sizeof(struct measurement_block_format0);

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	/* Allocate zeroed Measurement block */
	mb0 = alloc_io_mem(shared_mb_size, 0);
	if (!mb0) {
	report_abort("measurement_block_format0 allocation failed");
	return;
	}

	schm(NULL, 0); /* Stop any previous measurement */
	schm(mb0, SCHM_MBU);

	/* Expect success */
	report_prefix_push("Valid MB address and index 0");
	report(start_measuring(0, 0, false) &&
	mb0->ssch_rsch_count == SCHM_UPDATE_CNT,
	"SSCH measured %d", mb0->ssch_rsch_count);
	report_prefix_pop();

	/* Clear the measurement block for the next test */
	memset(mb0, 0, shared_mb_size);

	/* Expect success */
	report_prefix_push("Valid MB address and index 1");
	if (start_measuring(0, 1, false))
	report(mb0[1].ssch_rsch_count == SCHM_UPDATE_CNT,
	"SSCH measured %d", mb0[1].ssch_rsch_count);
	report_prefix_pop();

	/* Stop the measurement */
	css_disable_mb(test_device_sid);
	schm(NULL, 0);

	free_io_mem(mb0, shared_mb_size);
	}

	static void msch_with_wrong_fmt1_mbo(unsigned int schid, uint64_t mb)
	{
	struct pmcw *pmcw = &schib.pmcw;
	int cc;

	/* Read the SCHIB for this subchannel */
	cc = stsch(schid, &schib);
	if (cc) {
	report_fail("stsch: sch %08x failed with cc=%d", schid, cc);
	return;
	}

	/* Update the SCHIB to enable the measurement block */
	pmcw->flags \|= PMCW_MBUE;
	pmcw->flags2 \|= PMCW_MBF1;
	schib.mbo = mb;

	/* Tell the CSS we want to modify the subchannel */
	expect_pgm_int();
	cc = msch(schid, &schib);
	check_pgm_int_code(PGM_INT_CODE_OPERAND);
	}

	/*
	* test_schm_fmt1:
	* With measurement block format 1 the measurement block is
	* dedicated to a subchannel.
	*/
	static void test_schm_fmt1(void)
	{
	struct measurement_block_format1 *mb1;

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	if (!css_test_general_feature(CSSC_EXTENDED_MEASUREMENT_BLOCK)) {
	report_skip("Extended measurement block not available");
	return;
	}

	/* Allocate zeroed Measurement block */
	mb1 = alloc_io_mem(sizeof(struct measurement_block_format1), 0);
	if (!mb1) {
	report_abort("measurement_block_format1 allocation failed");
	return;
	}

	schm(NULL, 0); /* Stop any previous measurement */
	schm(0, SCHM_MBU);

	/* Expect error for non aligned MB */
	report_prefix_push("Unaligned MB origin");
	msch_with_wrong_fmt1_mbo(test_device_sid, (uint64_t)mb1 + 1);
	report_prefix_pop();

	/* Clear the measurement block for the next test */
	memset(mb1, 0, sizeof(*mb1));

	/* Expect success */
	report_prefix_push("Valid MB origin");
	if (start_measuring((u64)mb1, 0, true))
	report(mb1->ssch_rsch_count == SCHM_UPDATE_CNT,
	"SSCH measured %d", mb1->ssch_rsch_count);
	report_prefix_pop();

	/* Stop the measurement */
	css_disable_mb(test_device_sid);
	schm(NULL, 0);

	free_io_mem(mb1, sizeof(struct measurement_block_format1));
	}

	static void test_msch(void)
	{
	int invalid_pmcw_flags[] = {0, 1, 6, 7};
	struct schib test_schib;
	uint16_t old_pmcw_flags;
	const int align_to = 4;
	int invalid_flag;
	int cc;

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	cc = stsch(test_device_sid, &schib);
	if (cc) {
	report_fail("stsch: sch %08x failed with cc=%d", test_device_sid, cc);
	return;
	}

	report_prefix_push("Unaligned");
	for (int i = 1; i < align_to; i *= 2) {
	report_prefix_pushf("%d", i);

	expect_pgm_int();
	msch(test_device_sid, (struct schib *)(alignment_test_page + i));
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

	report_prefix_pop();
	}
	report_prefix_pop();

	report_prefix_push("Invalid SCHIB");
	old_pmcw_flags = schib.pmcw.flags;
	for (int i = 0; i < ARRAY_SIZE(invalid_pmcw_flags); i++) {
	invalid_flag = invalid_pmcw_flags[i];

	report_prefix_pushf("PMCW flag bit %d set", invalid_flag);

	schib.pmcw.flags = old_pmcw_flags \| BIT(15 - invalid_flag);
	expect_pgm_int();
	msch(test_device_sid, &schib);
	check_pgm_int_code(PGM_INT_CODE_OPERAND);

	cc = stsch(test_device_sid, &test_schib);
	report(!cc, "STSCH succeeded");
	report(!(test_schib.pmcw.flags & BIT(15 - invalid_flag)), "Clear on STSCH");

	report_prefix_pop();
	}
	report_prefix_pop();

	schib.pmcw.flags = old_pmcw_flags;
	}

	static void check_stcrw_no_crw_available(void)
	{
	uint32_t crw = 0xfeedc0fe;
	int cc;

	report_prefix_push("No CRW available");
	cc = stcrw(&crw);
	report(cc == 1, "cc == 1");
	report(!crw, "stored zeroes in crw");
	report_prefix_pop();
	}

	static int check_stcrw_crw_available(void)
	{
	const uint32_t magic = 0xfeedc0fe;
	uint32_t crw = magic;
	int cc;

	report_prefix_push("CRW available");
	cc = stcrw(&crw);
	report(!cc, "cc is zero");
	report(crw != magic, "stored crw");
	report_prefix_pop();

	return crw;
	}

	static uint32_t crw_get_rsc(uint32_t crw)
	{
	const int rsc_begin = 4;
	const int rsc_end = 8;

	return (crw & GENMASK(31 - rsc_begin, 31 - rsc_end)) >> 24;
	}

	#define CRW_RSC_CHP 4
	static void test_stcrw(void)
	{
	const int align_to = 4;
	int res;
	uint32_t crw;

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	report_prefix_push("Unaligned");
	for (int i = 1; i < align_to; i *= 2) {
	report_prefix_pushf("%d", i);

	expect_pgm_int();
	stcrw((uint32_t *)(alignment_test_page + i));
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

	report_prefix_pop();
	}
	report_prefix_pop();

	report_prefix_push("No CRW available initally");
	check_stcrw_no_crw_available();
	report_prefix_pop();

	res = css_generate_crw(test_device_sid);
	if (res) {
	report_skip("Couldn't generate CRW");
	report_prefix_pop();
	return;
	}

	crw = check_stcrw_crw_available();

	report_prefix_push("CRW available");
	report(crw_get_rsc(crw) == CRW_RSC_CHP, "CRW has Channel Path RSC");
	report_prefix_pop();

	report_prefix_push("No more CRWs pending");
	check_stcrw_no_crw_available();
	report_prefix_pop();
	}

	static void test_ssch(void)
	{
	const int align_to = 4;
	struct orb orb;

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	report_prefix_push("Unaligned");
	for (int i = 1; i < align_to; i *= 2) {
	report_prefix_pushf("%d", i);

	expect_pgm_int();
	ssch(test_device_sid, (struct orb *)(alignment_test_page + i));
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

	report_prefix_pop();
	}
	report_prefix_pop();

	report_prefix_push("Invalid ORB");

	memset(&orb, 0xff, sizeof(orb));
	expect_pgm_int();
	ssch(test_device_sid, &orb);
	check_pgm_int_code(PGM_INT_CODE_OPERAND);

	report_prefix_pop();
	}

	static void test_stsch(void)
	{
	const int align_to = 4;
	struct schib schib;
	int cc;

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	report_prefix_push("Unaligned");
	for (int i = 1; i < align_to; i *= 2) {
	report_prefix_pushf("%d", i);

	expect_pgm_int();
	stsch(test_device_sid, (struct schib *)(alignment_test_page + i));
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

	report_prefix_pop();
	}
	report_prefix_pop();

	report_prefix_push("Invalid subchannel number");
	cc = stsch(0x0001ffff, &schib);
	report(cc == 3, "Channel not operational");
	report_prefix_pop();

	/*
	* No matter if multiple-subchannel-set facility is installed, bit 47
	* always needs to be 1.
	*/
	report_prefix_push("Bit 47 in SID is zero");
	expect_pgm_int();
	stsch(0x0000ffff, &schib);
	check_pgm_int_code(PGM_INT_CODE_OPERAND);
	report_prefix_pop();
	}

	/*
	* According to architecture MSCH does ignore bit 5 of the second word
	* but STSCH will store bit 5 as zero.
	*/
	static void test_pmcw_bit5(void)
	{
	int cc;
	uint16_t old_pmcw_flags;

	cc = stsch(test_device_sid, &schib);
	if (cc) {
	report_fail("stsch: sch %08x failed with cc=%d", test_device_sid, cc);
	return;
	}
	old_pmcw_flags = schib.pmcw.flags;

	report_prefix_push("Bit 5 set");

	schib.pmcw.flags = old_pmcw_flags \| BIT(15 - 5);
	cc = msch(test_device_sid, &schib);
	report(!cc, "MSCH cc == 0");

	cc = stsch(test_device_sid, &schib);
	report(!cc, "STSCH cc == 0");
	report(!(schib.pmcw.flags & BIT(15 - 5)), "STSCH PMCW Bit 5 is clear");

	report_prefix_pop();

	report_prefix_push("Bit 5 clear");

	schib.pmcw.flags = old_pmcw_flags & ~BIT(15 - 5);
	cc = msch(test_device_sid, &schib);
	report(!cc, "MSCH cc == 0");

	cc = stsch(test_device_sid, &schib);
	report(!cc, "STSCH cc == 0");
	report(!(schib.pmcw.flags & BIT(15 - 5)), "STSCH PMCW Bit 5 is clear");

	report_prefix_pop();
	}

	static void test_tsch(void)
	{
	const int align_to = 4;
	struct irb irb;
	int cc;

	if (!test_device_sid) {
	report_skip("No device");
	return;
	}

	report_prefix_push("Unaligned");
	for (int i = 1; i < align_to; i *= 2) {
	report_prefix_pushf("%d", i);

	expect_pgm_int();
	tsch(test_device_sid, (struct irb *)(alignment_test_page + i));
	check_pgm_int_code(PGM_INT_CODE_SPECIFICATION);

	report_prefix_pop();
	}
	report_prefix_pop();

	report_prefix_push("Invalid subchannel number");
	cc = tsch(0x0001ffff, &irb);
	report(cc == 3, "Channel not operational");
	report_prefix_pop();

	report_prefix_push("Bit 47 in SID is zero");
	expect_pgm_int();
	tsch(0x0000ffff, &irb);
	check_pgm_int_code(PGM_INT_CODE_OPERAND);
	report_prefix_pop();
	}

	static struct {
	const char *name;
	void (*func)(void);
	} tests[] = {
	/* The css_init test is needed to initialize the CSS Characteristics */
	{ "initialize CSS (chsc)", css_init },
	{ "enumerate (stsch)", test_enumerate },
	{ "enable (msch)", test_enable },
	{ "sense (ssch/tsch)", test_sense },
	{ "measurement block (schm)", test_schm },
	{ "measurement block format0", test_schm_fmt0 },
	{ "measurement block format1", test_schm_fmt1 },
	{ "msch", test_msch },
	{ "stcrw", test_stcrw },
	{ "ssch", test_ssch },
	{ "stsch", test_stsch },
	{ "pmcw bit 5 ignored", test_pmcw_bit5 },
	{ "tsch", test_tsch },
	{ NULL, NULL }
	};

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

	report_prefix_push("Channel Subsystem");

	/* There's no guarantee where our devices are without qemu */
	if (!host_is_qemu()) {
	report_skip("Not running under QEMU");
	goto done;
	}

	enable_io_isc(0x80 >> IO_SCH_ISC);
	for (i = 0; tests[i].name; i++) {
	report_prefix_push(tests[i].name);
	tests[i].func();
	report_prefix_pop();
	}

	done:
	report_prefix_pop();
	return report_summary();
	}