sys/uvm/t_uvm_physseg_load.c

1.2  cherry /* $NetBSD: t_uvm_physseg_load.c,v 1.2 2016/12/22 08:15:20 cherry Exp $ */
1.1  cherry
1.1  cherry /*-
1.1  cherry  * Copyright (c) 2015, 2016 The NetBSD Foundation, Inc.
1.1  cherry  * All rights reserved.
1.1  cherry  *
1.1  cherry  * This code is derived from software contributed to The NetBSD Foundation
1.1  cherry  * by Santhosh N. Raju <santhosh.raju (at) gmail.com> and
1.1  cherry  * by Cherry G. Mathew
1.1  cherry  *
1.1  cherry  * Redistribution and use in source and binary forms, with or without
1.1  cherry  * modification, are permitted provided that the following conditions
1.1  cherry  * are met:
1.1  cherry  * 1. Redistributions of source code must retain the above copyright
1.1  cherry  *    notice, this list of conditions and the following disclaimer.
1.1  cherry  * 2. Redistributions in binary form must reproduce the above copyright
1.1  cherry  *    notice, this list of conditions and the following disclaimer in the
1.1  cherry  *    documentation and/or other materials provided with the distribution.
1.1  cherry  *
1.1  cherry  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.1  cherry  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  cherry  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  cherry  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1  cherry  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  cherry  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  cherry  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  cherry  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  cherry  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  cherry  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  cherry  * POSSIBILITY OF SUCH DAMAGE.
1.1  cherry  */
1.1  cherry
1.1  cherry #include <sys/cdefs.h>
1.2  cherry __RCSID("$NetBSD: t_uvm_physseg_load.c,v 1.2 2016/12/22 08:15:20 cherry Exp $");
1.2  cherry
1.2  cherry /*
1.2  cherry  * If this line is commented out tests related touvm_physseg_get_pmseg()
1.2  cherry  * wont run.
1.2  cherry  *
1.2  cherry  * Have a look at machine/uvm_physseg.h for more details.
1.2  cherry  */
1.2  cherry #define __HAVE_PMAP_PHYSSEG
1.2  cherry
1.2  cherry /*
1.2  cherry  * This is a dummy struct used for testing purposes
1.2  cherry  *
1.2  cherry  * In reality this struct would exist in the MD part of the code residing in
1.2  cherry  * machines/vmparam.h
1.2  cherry  */
1.2  cherry
1.2  cherry #ifdef __HAVE_PMAP_PHYSSEG
1.2  cherry struct pmap_physseg {
1.2  cherry 	int dummy_variable;		/* Dummy variable use for testing */
1.2  cherry };
1.2  cherry #endif
1.1  cherry
1.1  cherry /* Testing API - assumes userland */
1.1  cherry /* Provide Kernel API equivalents */
1.1  cherry #include <assert.h>
1.1  cherry #include <stdbool.h>
1.1  cherry #include <string.h> /* memset(3) et. al */
1.1  cherry #include <stdio.h> /* printf(3) */
1.1  cherry #include <stdlib.h> /* malloc(3) */
1.1  cherry #include <stdarg.h>
1.1  cherry #include <stddef.h>
1.1  cherry #include <time.h>
1.1  cherry
1.1  cherry #define	PRIxPADDR	"lx"
1.1  cherry #define	PRIxPSIZE	"lx"
1.1  cherry #define	PRIuPSIZE	"lu"
1.1  cherry #define	PRIxVADDR	"lx"
1.1  cherry #define	PRIxVSIZE	"lx"
1.1  cherry #define	PRIuVSIZE	"lu"
1.1  cherry
1.1  cherry #define UVM_HOTPLUG /* Enable hotplug with rbtree. */
1.1  cherry #define PMAP_STEAL_MEMORY
1.1  cherry #define DEBUG /* Enable debug functionality. */
1.1  cherry
1.1  cherry typedef unsigned long vaddr_t;
1.1  cherry typedef unsigned long paddr_t;
1.1  cherry typedef unsigned long psize_t;
1.1  cherry typedef unsigned long vsize_t;
1.1  cherry
1.2  cherry #include <uvm/uvm_physseg.h>
1.1  cherry #include <uvm/uvm_page.h>
1.1  cherry
1.1  cherry #ifndef DIAGNOSTIC
1.1  cherry #define	KASSERTMSG(e, msg, ...)	/* NOTHING */
1.1  cherry #define	KASSERT(e)		/* NOTHING */
1.1  cherry #else
1.1  cherry #define	KASSERT(a)		assert(a)
1.1  cherry #define KASSERTMSG(exp, ...)    printf(__VA_ARGS__); assert((exp))
1.1  cherry #endif
1.1  cherry
1.1  cherry #define VM_PHYSSEG_STRAT VM_PSTRAT_BSEARCH
1.1  cherry
1.1  cherry #define VM_NFREELIST            4
1.1  cherry #define VM_FREELIST_DEFAULT     0
1.1  cherry #define VM_FREELIST_FIRST16     3
1.1  cherry #define VM_FREELIST_FIRST1G     2
1.1  cherry #define VM_FREELIST_FIRST4G     1
1.1  cherry
1.1  cherry /*
1.1  cherry  * Used in tests when Array implementation is tested
1.1  cherry  */
1.1  cherry #if !defined(VM_PHYSSEG_MAX)
1.1  cherry #define VM_PHYSSEG_MAX          32
1.1  cherry #endif
1.1  cherry
1.1  cherry #define PAGE_SIZE               4096
1.1  cherry #define PAGE_SHIFT              12
1.1  cherry #define atop(x)         (((paddr_t)(x)) >> PAGE_SHIFT)
1.1  cherry
1.1  cherry #define	mutex_enter(l)
1.1  cherry #define	mutex_exit(l)
1.1  cherry
1.1  cherry #define	_SYS_KMEM_H_ /* Disallow the real kmem API (see below) */
1.1  cherry /* free(p) XXX: pgs management need more thought */
1.1  cherry #define kmem_alloc(size, flags) malloc(size)
1.1  cherry #define kmem_zalloc(size, flags) malloc(size)
1.1  cherry #define kmem_free(p, size) free(p)
1.1  cherry
1.1  cherry psize_t physmem;
1.1  cherry
1.1  cherry struct uvmexp uvmexp;        /* decl */
1.1  cherry
1.1  cherry /*
1.1  cherry  * uvm structure borrowed from uvm.h
1.1  cherry  *
1.1  cherry  * Remember this is a dummy structure used within the ATF Tests and
1.1  cherry  * uses only necessary fields from the original uvm struct.
1.1  cherry  * See uvm/uvm.h for the full struct.
1.1  cherry  */
1.1  cherry
1.1  cherry struct uvm {
1.1  cherry 	/* vm_page related parameters */
1.1  cherry
1.1  cherry 	bool page_init_done;		/* TRUE if uvm_page_init() finished */
1.1  cherry } uvm;
1.1  cherry
1.1  cherry static void
1.1  cherry panic(const char *fmt, ...)
1.1  cherry {
1.1  cherry 	va_list ap;
1.1  cherry
1.1  cherry 	va_start(ap, fmt);
1.1  cherry 	vprintf(fmt, ap);
1.1  cherry 	printf("\n");
1.1  cherry 	va_end(ap);
1.1  cherry 	KASSERT(false);
1.1  cherry
1.1  cherry 	/*NOTREACHED*/
1.1  cherry }
1.1  cherry
1.1  cherry static void
1.1  cherry uvm_pagefree(struct vm_page *pg)
1.1  cherry {
1.1  cherry 	return;
1.1  cherry }
1.1  cherry
1.1  cherry #if defined(UVM_HOTPLUG)
1.1  cherry static void
1.1  cherry uvmpdpol_reinit(void)
1.1  cherry {
1.1  cherry 	return;
1.1  cherry }
1.1  cherry #endif /* UVM_HOTPLUG */
1.1  cherry
1.1  cherry /* end - Provide Kernel API equivalents */
1.1  cherry
1.1  cherry #include "uvm/uvm_physseg.c"
1.1  cherry
1.1  cherry #include <atf-c.h>
1.1  cherry
1.1  cherry #define ONE_MEGABYTE 1024 * 1024
1.1  cherry
1.1  cherry /* Sample Page Frame Numbers */
1.1  cherry #define VALID_START_PFN_1 atop(0)
1.1  cherry #define VALID_END_PFN_1 atop(ONE_MEGABYTE)
1.1  cherry #define VALID_AVAIL_START_PFN_1 atop(0)
1.1  cherry #define VALID_AVAIL_END_PFN_1 atop(ONE_MEGABYTE)
1.1  cherry
1.1  cherry #define VALID_START_PFN_2 atop(ONE_MEGABYTE + 1)
1.1  cherry #define VALID_END_PFN_2 atop(ONE_MEGABYTE * 2)
1.1  cherry #define VALID_AVAIL_START_PFN_2 atop(ONE_MEGABYTE + 1)
1.1  cherry #define VALID_AVAIL_END_PFN_2 atop(ONE_MEGABYTE * 2)
1.1  cherry
1.1  cherry #define VALID_START_PFN_3 atop((ONE_MEGABYTE * 2) + 1)
1.1  cherry #define VALID_END_PFN_3 atop(ONE_MEGABYTE * 3)
1.1  cherry #define VALID_AVAIL_START_PFN_3 atop((ONE_MEGABYTE * 2) + 1)
1.1  cherry #define VALID_AVAIL_END_PFN_3 atop(ONE_MEGABYTE * 3)
1.1  cherry
1.1  cherry #define VALID_START_PFN_4 atop(ONE_MEGABYTE + 1)
1.1  cherry #define VALID_END_PFN_4 atop(ONE_MEGABYTE * 128)
1.1  cherry #define VALID_AVAIL_START_PFN_4 atop(ONE_MEGABYTE + 1)
1.1  cherry #define VALID_AVAIL_END_PFN_4 atop(ONE_MEGABYTE * 128)
1.1  cherry
1.1  cherry #define VALID_START_PFN_5 atop(ONE_MEGABYTE + 1)
1.1  cherry #define VALID_END_PFN_5 atop(ONE_MEGABYTE * 256)
1.1  cherry #define VALID_AVAIL_START_PFN_5 atop(ONE_MEGABYTE + 1)
1.1  cherry #define VALID_AVAIL_END_PFN_5 atop(ONE_MEGABYTE * 256)
1.1  cherry
1.1  cherry /*
1.1  cherry  * Total number of pages (of 4K size each) should be 256 for 1MB of memory.
1.1  cherry  */
1.1  cherry #define PAGE_COUNT_1M      256
1.1  cherry
1.1  cherry /*
1.1  cherry  * The number of Page Frames to allot per segment
1.1  cherry  */
1.1  cherry #define PF_STEP 8
1.1  cherry
1.1  cherry /*
1.1  cherry  * A debug fucntion to print the content of upm.
1.1  cherry  */
1.1  cherry 	static inline void
1.1  cherry 	uvm_physseg_dump_seg(uvm_physseg_t upm)
1.1  cherry 	{
1.1  cherry #if defined(DEBUG)
1.1  cherry 		printf("%s: seg->start == %ld\n", __func__,
1.1  cherry 		    uvm_physseg_get_start(upm));
1.1  cherry 		printf("%s: seg->end == %ld\n", __func__,
1.1  cherry 		    uvm_physseg_get_end(upm));
1.1  cherry 		printf("%s: seg->avail_start == %ld\n", __func__,
1.1  cherry 		    uvm_physseg_get_avail_start(upm));
1.1  cherry 		printf("%s: seg->avail_end == %ld\n", __func__,
1.1  cherry 		    uvm_physseg_get_avail_end(upm));
1.1  cherry
1.1  cherry 		printf("====\n\n");
1.1  cherry #else
1.1  cherry 		return;
1.1  cherry #endif /* DEBUG */
1.1  cherry 	}
1.1  cherry
1.1  cherry /*
1.1  cherry  * Private accessor that gets the value of vm_physmem.nentries
1.1  cherry  */
1.1  cherry static int
1.1  cherry uvm_physseg_get_entries(void)
1.1  cherry {
1.1  cherry #if defined(UVM_HOTPLUG)
1.1  cherry 	return uvm_physseg_graph.nentries;
1.1  cherry #else
1.1  cherry 	return vm_nphysmem;
1.1  cherry #endif /* UVM_HOTPLUG */
1.1  cherry }
1.1  cherry
1.1  cherry /*
1.1  cherry  * Note: This function replicates verbatim what happens in
1.1  cherry  * uvm_page.c:uvm_page_init().
1.1  cherry  *
1.1  cherry  * Please track any changes that happen there.
1.1  cherry  */
1.1  cherry static void
1.1  cherry uvm_page_init_fake(struct vm_page *pagearray, psize_t pagecount)
1.1  cherry {
1.1  cherry 	uvm_physseg_t bank;
1.1  cherry 	size_t n;
1.1  cherry
1.1  cherry 	for (bank = uvm_physseg_get_first(),
1.1  cherry 		 uvm_physseg_seg_chomp_slab(bank, pagearray, pagecount);
1.2  cherry 	     uvm_physseg_valid_p(bank);
1.1  cherry 	     bank = uvm_physseg_get_next(bank)) {
1.1  cherry
1.1  cherry 		n = uvm_physseg_get_end(bank) - uvm_physseg_get_start(bank);
1.1  cherry 		uvm_physseg_seg_alloc_from_slab(bank, n);
1.1  cherry 		uvm_physseg_init_seg(bank, pagearray);
1.1  cherry
1.1  cherry 		/* set up page array pointers */
1.1  cherry 		pagearray += n;
1.1  cherry 		pagecount -= n;
1.1  cherry 	}
1.1  cherry
1.1  cherry 	uvm.page_init_done = true;
1.1  cherry }
1.1  cherry
1.1  cherry /*
1.1  cherry  * PHYS_TO_VM_PAGE: find vm_page for a PA.   used by MI code to get vm_pages
1.1  cherry  * back from an I/O mapping (ugh!).   used in some MD code as well.
1.1  cherry  */
1.1  cherry static struct vm_page *
1.1  cherry uvm_phys_to_vm_page(paddr_t pa)
1.1  cherry {
1.1  cherry 	paddr_t pf = atop(pa);
1.1  cherry 	paddr_t off;
1.1  cherry 	uvm_physseg_t psi;
1.1  cherry
1.1  cherry 	psi = uvm_physseg_find(pf, &off);
1.1  cherry 	if (psi != UVM_PHYSSEG_TYPE_INVALID)
1.1  cherry 		return uvm_physseg_get_pg(psi, off);
1.1  cherry 	return(NULL);
1.1  cherry }
1.1  cherry
1.1  cherry //static paddr_t
1.1  cherry //uvm_vm_page_to_phys(const struct vm_page *pg)
1.1  cherry //{
1.1  cherry //
1.1  cherry //	return pg->phys_addr;
1.1  cherry //}
1.1  cherry
1.1  cherry /*
1.1  cherry  * XXX: To do, write control test cases for uvm_vm_page_to_phys().
1.1  cherry  */
1.1  cherry
1.1  cherry /* #define VM_PAGE_TO_PHYS(entry)  uvm_vm_page_to_phys(entry) */
1.1  cherry
1.1  cherry #define PHYS_TO_VM_PAGE(pa)     uvm_phys_to_vm_page(pa)
1.1  cherry
1.1  cherry /*
1.1  cherry  * Test Fixture SetUp().
1.1  cherry  */
1.1  cherry static void
1.1  cherry setup(void)
1.1  cherry {
1.1  cherry 	/* Prerequisites for running certain calls in uvm_physseg */
1.1  cherry 	uvmexp.pagesize = PAGE_SIZE;
1.1  cherry 	uvmexp.npages = 0;
1.1  cherry 	uvm.page_init_done = false;
1.1  cherry 	uvm_physseg_init();
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_100);
1.1  cherry ATF_TC_HEAD(uvm_physseg_100, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    100 calls, VM_PHYSSEG_MAX is 32.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_100, tc)
1.1  cherry {
1.1  cherry 	paddr_t pa;
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	for(paddr_t i = VALID_START_PFN_1;
1.1  cherry 	    i < VALID_END_PFN_1; i += PF_STEP) {
1.1  cherry 		uvm_page_physload(i, i + PF_STEP, i, i + PF_STEP,
1.1  cherry 		    VM_FREELIST_DEFAULT);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(VM_PHYSSEG_MAX, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(int i = 0; i < 100; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_1);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_1K);
1.1  cherry ATF_TC_HEAD(uvm_physseg_1K, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    1000 calls, VM_PHYSSEG_MAX is 32.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_1K, tc)
1.1  cherry {
1.1  cherry 	paddr_t pa;
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	for(paddr_t i = VALID_START_PFN_1;
1.1  cherry 	    i < VALID_END_PFN_1; i += PF_STEP) {
1.1  cherry 		uvm_page_physload(i, i + PF_STEP, i, i + PF_STEP,
1.1  cherry 		    VM_FREELIST_DEFAULT);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(VM_PHYSSEG_MAX, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(int i = 0; i < 1000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_1);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_10K);
1.1  cherry ATF_TC_HEAD(uvm_physseg_10K, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    10,000 calls, VM_PHYSSEG_MAX is 32.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_10K, tc)
1.1  cherry {
1.1  cherry 	paddr_t pa;
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	for(paddr_t i = VALID_START_PFN_1;
1.1  cherry 	    i < VALID_END_PFN_1; i += PF_STEP) {
1.1  cherry 		uvm_page_physload(i, i + PF_STEP, i, i + PF_STEP,
1.1  cherry 		    VM_FREELIST_DEFAULT);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(VM_PHYSSEG_MAX, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(int i = 0; i < 10000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_1);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_100K);
1.1  cherry ATF_TC_HEAD(uvm_physseg_100K, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    100,000 calls, VM_PHYSSEG_MAX is 32.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_100K, tc)
1.1  cherry {
1.1  cherry 	paddr_t pa;
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	for(paddr_t i = VALID_START_PFN_1;
1.1  cherry 	    i < VALID_END_PFN_1; i += PF_STEP) {
1.1  cherry 		uvm_page_physload(i, i + PF_STEP, i, i + PF_STEP,
1.1  cherry 		    VM_FREELIST_DEFAULT);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(VM_PHYSSEG_MAX, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(int i = 0; i < 100000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_1);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_1M);
1.1  cherry ATF_TC_HEAD(uvm_physseg_1M, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    1,000,000 calls, VM_PHYSSEG_MAX is 32.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_1M, tc)
1.1  cherry {
1.1  cherry 	paddr_t pa;
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	for(paddr_t i = VALID_START_PFN_1;
1.1  cherry 	    i < VALID_END_PFN_1; i += PF_STEP) {
1.1  cherry 		uvm_page_physload(i, i + PF_STEP, i, i + PF_STEP,
1.1  cherry 		    VM_FREELIST_DEFAULT);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(VM_PHYSSEG_MAX, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(int i = 0; i < 1000000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_1);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_10M);
1.1  cherry ATF_TC_HEAD(uvm_physseg_10M, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    10,000,000 calls, VM_PHYSSEG_MAX is 32.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_10M, tc)
1.1  cherry {
1.1  cherry 	paddr_t pa;
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	for(paddr_t i = VALID_START_PFN_1;
1.1  cherry 	    i < VALID_END_PFN_1; i += PF_STEP) {
1.1  cherry 		uvm_page_physload(i, i + PF_STEP, i, i + PF_STEP,
1.1  cherry 		    VM_FREELIST_DEFAULT);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(VM_PHYSSEG_MAX, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(int i = 0; i < 10000000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_1);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_100M);
1.1  cherry ATF_TC_HEAD(uvm_physseg_100M, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    100,000,000 calls, VM_PHYSSEG_MAX is 32.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_100M, tc)
1.1  cherry {
1.1  cherry 	paddr_t pa;
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	for(paddr_t i = VALID_START_PFN_1;
1.1  cherry 	    i < VALID_END_PFN_1; i += PF_STEP) {
1.1  cherry 		uvm_page_physload(i, i + PF_STEP, i, i + PF_STEP,
1.1  cherry 		    VM_FREELIST_DEFAULT);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(VM_PHYSSEG_MAX, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(int i = 0; i < 100000000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_1);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_1MB);
1.1  cherry ATF_TC_HEAD(uvm_physseg_1MB, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    10,000,000 calls, VM_PHYSSEG_MAX is 32 on 1 MB Segment.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_1MB, t)
1.1  cherry {
1.1  cherry 	paddr_t pa = 0;
1.1  cherry
1.1  cherry 	paddr_t pf = 0;
1.1  cherry
1.1  cherry 	psize_t pf_chunk_size = 0;
1.1  cherry
1.1  cherry 	psize_t npages1 = (VALID_END_PFN_1 - VALID_START_PFN_1);
1.1  cherry
1.1  cherry 	psize_t npages2 = (VALID_END_PFN_2 - VALID_START_PFN_2);
1.1  cherry
1.1  cherry 	struct vm_page *slab = malloc(sizeof(struct vm_page) *
1.1  cherry 	    (npages1 + npages2));
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	/* We start with zero segments */
1.1  cherry 	ATF_REQUIRE_EQ(true, uvm_physseg_plug(VALID_START_PFN_1, npages1, NULL));
1.1  cherry 	ATF_REQUIRE_EQ(1, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	/* Post boot: Fake all segments and pages accounted for. */
1.1  cherry 	uvm_page_init_fake(slab, npages1 + npages2);
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(true, uvm_physseg_plug(VALID_START_PFN_2, npages2, NULL));
1.1  cherry 	ATF_REQUIRE_EQ(2, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(pf = VALID_START_PFN_2; pf < VALID_END_PFN_2; pf += PF_STEP) {
1.1  cherry 		pf_chunk_size = (psize_t) random() % (psize_t) (PF_STEP - 1) + 1;
1.1  cherry 		uvm_physseg_unplug(pf, pf_chunk_size);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	for(int i = 0; i < 10000000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_2);
1.1  cherry 		if(pa < ctob(VALID_START_PFN_2))
1.1  cherry 			pa += ctob(VALID_START_PFN_2);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_64MB);
1.1  cherry ATF_TC_HEAD(uvm_physseg_64MB, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    10,000,000 calls, VM_PHYSSEG_MAX is 32 on 64 MB Segment.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_64MB, t)
1.1  cherry {
1.1  cherry 	paddr_t pa = 0;
1.1  cherry
1.1  cherry 	paddr_t pf = 0;
1.1  cherry
1.1  cherry 	psize_t pf_chunk_size = 0;
1.1  cherry
1.1  cherry 	psize_t npages1 = (VALID_END_PFN_1 - VALID_START_PFN_1);
1.1  cherry
1.1  cherry 	psize_t npages2 = (VALID_END_PFN_3 - VALID_START_PFN_3);
1.1  cherry
1.1  cherry 	struct vm_page *slab = malloc(sizeof(struct vm_page)  *
1.1  cherry 	    (npages1 + npages2));
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	/* We start with zero segments */
1.1  cherry 	ATF_REQUIRE_EQ(true, uvm_physseg_plug(VALID_START_PFN_1, npages1, NULL));
1.1  cherry 	ATF_REQUIRE_EQ(1, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	/* Post boot: Fake all segments and pages accounted for. */
1.1  cherry 	uvm_page_init_fake(slab, npages1 + npages2);
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(true, uvm_physseg_plug(VALID_START_PFN_3, npages2, NULL));
1.1  cherry 	ATF_REQUIRE_EQ(2, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(pf = VALID_START_PFN_3; pf < VALID_END_PFN_3; pf += PF_STEP) {
1.1  cherry 		pf_chunk_size = (psize_t) random() % (psize_t) (PF_STEP - 1) + 1;
1.1  cherry 		uvm_physseg_unplug(pf, pf_chunk_size);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	for(int i = 0; i < 10000000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_3);
1.1  cherry 		if(pa < ctob(VALID_START_PFN_3))
1.1  cherry 			pa += ctob(VALID_START_PFN_3);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_128MB);
1.1  cherry ATF_TC_HEAD(uvm_physseg_128MB, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    10,000,000 calls, VM_PHYSSEG_MAX is 32 on 128 MB Segment.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_128MB, t)
1.1  cherry {
1.1  cherry 	paddr_t pa = 0;
1.1  cherry
1.1  cherry 	paddr_t pf = 0;
1.1  cherry
1.1  cherry 	psize_t pf_chunk_size = 0;
1.1  cherry
1.1  cherry 	psize_t npages1 = (VALID_END_PFN_1 - VALID_START_PFN_1);
1.1  cherry
1.1  cherry 	psize_t npages2 = (VALID_END_PFN_4 - VALID_START_PFN_4);
1.1  cherry
1.1  cherry 	struct vm_page *slab = malloc(sizeof(struct vm_page)
1.1  cherry 	    * (npages1 + npages2));
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	/* We start with zero segments */
1.1  cherry 	ATF_REQUIRE_EQ(true, uvm_physseg_plug(VALID_START_PFN_1, npages1, NULL));
1.1  cherry 	ATF_REQUIRE_EQ(1, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	/* Post boot: Fake all segments and pages accounted for. */
1.1  cherry 	uvm_page_init_fake(slab, npages1 + npages2);
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(true, uvm_physseg_plug(VALID_START_PFN_2, npages2, NULL));
1.1  cherry 	ATF_REQUIRE_EQ(2, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(pf = VALID_START_PFN_4; pf < VALID_END_PFN_4; pf += PF_STEP) {
1.1  cherry 		pf_chunk_size = (psize_t) random() % (psize_t) (PF_STEP - 1) + 1;
1.1  cherry 		uvm_physseg_unplug(pf, pf_chunk_size);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	for(int i = 0; i < 10000000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_4);
1.1  cherry 		if(pa < ctob(VALID_START_PFN_4))
1.1  cherry 			pa += ctob(VALID_START_PFN_4);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TC(uvm_physseg_256MB);
1.1  cherry ATF_TC_HEAD(uvm_physseg_256MB, tc)
1.1  cherry {
1.1  cherry 	atf_tc_set_md_var(tc, "descr", "Load test uvm_phys_to_vm_page() with \
1.1  cherry 	    10,000,000 calls, VM_PHYSSEG_MAX is 32 on 256 MB Segment.");
1.1  cherry }
1.1  cherry ATF_TC_BODY(uvm_physseg_256MB, t)
1.1  cherry {
1.1  cherry 	paddr_t pa = 0;
1.1  cherry
1.1  cherry 	paddr_t pf = 0;
1.1  cherry
1.1  cherry 	psize_t pf_chunk_size = 0;
1.1  cherry
1.1  cherry 	psize_t npages1 = (VALID_END_PFN_1 - VALID_START_PFN_1);
1.1  cherry
1.1  cherry 	psize_t npages2 = (VALID_END_PFN_5 - VALID_START_PFN_5);
1.1  cherry
1.1  cherry 	struct vm_page *slab = malloc(sizeof(struct vm_page)  * (npages1 + npages2));
1.1  cherry
1.1  cherry 	setup();
1.1  cherry
1.1  cherry 	/* We start with zero segments */
1.1  cherry 	ATF_REQUIRE_EQ(true, uvm_physseg_plug(VALID_START_PFN_1, npages1, NULL));
1.1  cherry 	ATF_REQUIRE_EQ(1, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	/* Post boot: Fake all segments and pages accounted for. */
1.1  cherry 	uvm_page_init_fake(slab, npages1 + npages2);
1.1  cherry
1.1  cherry 	ATF_REQUIRE_EQ(true, uvm_physseg_plug(VALID_START_PFN_2, npages2, NULL));
1.1  cherry 	ATF_REQUIRE_EQ(2, uvm_physseg_get_entries());
1.1  cherry
1.1  cherry 	srandom((unsigned)time(NULL));
1.1  cherry 	for(pf = VALID_START_PFN_5; pf < VALID_END_PFN_5; pf += PF_STEP) {
1.1  cherry 		pf_chunk_size = (psize_t) random() % (psize_t) (PF_STEP - 1) + 1;
1.1  cherry 		uvm_physseg_unplug(pf, pf_chunk_size);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	for(int i = 0; i < 10000000; i++) {
1.1  cherry 		pa = (paddr_t) random() % (paddr_t) ctob(VALID_END_PFN_5);
1.1  cherry 		if(pa < ctob(VALID_END_PFN_5))
1.1  cherry 			pa += ctob(VALID_START_PFN_5);
1.1  cherry 		PHYS_TO_VM_PAGE(pa);
1.1  cherry 	}
1.1  cherry
1.1  cherry 	ATF_CHECK_EQ(true, true);
1.1  cherry }
1.1  cherry
1.1  cherry ATF_TP_ADD_TCS(tp)
1.1  cherry {
1.1  cherry 	/* Fixed memory size tests. */
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_100);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_1K);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_10K);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_100K);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_1M);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_10M);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_100M);
1.1  cherry
1.1  cherry #if defined(UVM_HOTPLUG)
1.1  cherry 	/* Variable memory size tests. */
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_1MB);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_64MB);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_128MB);
1.1  cherry 	ATF_TP_ADD_TC(tp, uvm_physseg_256MB);
1.1  cherry #endif /* UVM_HOTPLUG */
1.1  cherry
1.1  cherry 	return atf_no_error();
1.1  cherry }