stand/hpcboot/memory.cpp

1.4  enami /*	$NetBSD: memory.cpp,v 1.4 2001/05/16 08:37:44 enami Exp $	*/
1.1    uch
1.1    uch /*-
1.1    uch  * Copyright (c) 2001 The NetBSD Foundation, Inc.
1.1    uch  * All rights reserved.
1.1    uch  *
1.1    uch  * This code is derived from software contributed to The NetBSD Foundation
1.1    uch  * by UCHIYAMA Yasushi.
1.1    uch  *
1.1    uch  * Redistribution and use in source and binary forms, with or without
1.1    uch  * modification, are permitted provided that the following conditions
1.1    uch  * are met:
1.1    uch  * 1. Redistributions of source code must retain the above copyright
1.1    uch  *    notice, this list of conditions and the following disclaimer.
1.1    uch  * 2. Redistributions in binary form must reproduce the above copyright
1.1    uch  *    notice, this list of conditions and the following disclaimer in the
1.1    uch  *    documentation and/or other materials provided with the distribution.
1.1    uch  * 3. All advertising materials mentioning features or use of this software
1.1    uch  *    must display the following acknowledgement:
1.1    uch  *        This product includes software developed by the NetBSD
1.1    uch  *        Foundation, Inc. and its contributors.
1.1    uch  * 4. Neither the name of The NetBSD Foundation nor the names of its
1.1    uch  *    contributors may be used to endorse or promote products derived
1.1    uch  *    from this software without specific prior written permission.
1.1    uch  *
1.1    uch  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.1    uch  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1    uch  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1    uch  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1    uch  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1    uch  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1    uch  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1    uch  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1    uch  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1    uch  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1    uch  * POSSIBILITY OF SUCH DAMAGE.
1.1    uch  */
1.1    uch
1.1    uch #include <memory.h>
1.1    uch #include <console.h>
1.1    uch
1.1    uch MemoryManager::MemoryManager(Console *&cons, size_t pagesize)
1.1    uch 	: _cons(cons)
1.1    uch {
1.1    uch 	_debug = FALSE;
1.1    uch 	_page_size =pagesize;
1.1    uch
1.1    uch 	int mask = _page_size;
1.1    uch 	for (_page_shift = 0; !(mask & 1); _page_shift++)
1.1    uch 		mask >>= 1;
1.1    uch
1.1    uch 	_page_per_region = WCE_REGION_SIZE / _page_size;
1.1    uch 	_nbank = 0;
1.1    uch 	DPRINTF((TEXT("Page size %dbyte %dpages/region\n"),
1.3    uch 	    _page_size , _page_per_region));
1.1    uch 	_addr_table_idx = 0;
1.1    uch 	_addr_table = 0;
1.1    uch 	_memory = 0;
1.1    uch }
1.1    uch
1.1    uch MemoryManager::~MemoryManager(void)
1.1    uch {
1.1    uch 	if (_memory)
1.1    uch 		VirtualFree(LPVOID(_memory), 0, MEM_RELEASE);
1.1    uch }
1.1    uch
1.1    uch void
1.1    uch MemoryManager::loadBank(paddr_t paddr, psize_t psize)
1.1    uch {
1.1    uch 	struct MemoryManager::bank *b = &_bank[_nbank++];
1.1    uch 	b->addr = paddr;
1.1    uch 	b->size = psize;
1.1    uch 	DPRINTF((TEXT("Bank#%d 0x%08x size 0x%08x\n"), _nbank - 1,
1.3    uch 	    b->addr, b->size));
1.1    uch }
1.1    uch
1.1    uch BOOL
1.1    uch MemoryManager::reservePage(vsize_t size, BOOL page_commit)
1.1    uch {
1.1    uch 	// My virtual memory space
1.1    uch 	vaddr_t vbase;
1.1    uch 	vsize_t vsize;
1.1    uch
1.1    uch 	int i, npage;
1.1    uch
1.1    uch 	if (size == 0)
1.1    uch 		return FALSE;
1.1    uch
1.1    uch   // reserve all virtual memory.
1.1    uch 	vsize = roundRegion(size);
1.1    uch 	npage = roundPage(size) / _page_size;
1.1    uch
1.1    uch 	size_t tabsz = sizeof(struct AddressTranslationTable) * npage;
1.1    uch 	_addr_table = static_cast <struct AddressTranslationTable *>
1.3    uch 	    (malloc(tabsz));
1.1    uch 	if (_addr_table == NULL) {
1.1    uch 		DPRINTF((TEXT("can't allocate memory for translation table.\n")));
1.1    uch 		return FALSE;
1.1    uch 	}
1.1    uch 	DPRINTF((TEXT("address translation table %d pages.(%d byte)\n"), npage,
1.3    uch 	    tabsz));
1.1    uch
1.1    uch 	if (page_commit)
1.1    uch 		vbase = vaddr_t(VirtualAlloc(0, vsize, MEM_RESERVE,
1.3    uch 		    PAGE_NOACCESS));
1.1    uch 	else
1.1    uch 		vbase = vaddr_t(VirtualAlloc(0, vsize, MEM_COMMIT,
1.3    uch 		    PAGE_READWRITE | PAGE_NOCACHE));
1.1    uch
1.1    uch 	if (vbase == 0) {
1.1    uch 		DPRINTF((TEXT("can't allocate memory\n")));
1.1    uch 		return FALSE;
1.1    uch 	}
1.1    uch 	_memory = vbase;
1.1    uch
1.1    uch   // find physical address of allocated page.
1.1    uch 	AddressTranslationTable *tab = _addr_table;
1.1    uch 	_naddr_table = 0;
1.1    uch 	for (i = 0; i < npage; i++) {
1.1    uch 		vaddr_t vaddr;
1.1    uch 		paddr_t paddr = ~0;
1.1    uch
1.1    uch 		if (page_commit)
1.1    uch 			// now map to physical page.
1.1    uch 			vaddr = vaddr_t(VirtualAlloc(
1.1    uch 				LPVOID(vbase + _page_size * i),
1.1    uch 				_page_size, MEM_COMMIT,
1.1    uch 				PAGE_READWRITE | PAGE_NOCACHE));
1.1    uch 		else
1.1    uch 			vaddr = vbase + _page_size * i;
1.1    uch
1.1    uch 		paddr = searchPage(vaddr);
1.1    uch
1.1    uch 		if (paddr == ~0) {
1.1    uch 			DPRINTF((TEXT("page#%d not found\n"), i));
1.1    uch 			break;
1.1    uch 		} else {
1.1    uch #ifdef MEMORY_MAP_DEBUG
1.1    uch 			DPRINTF((TEXT("page %d vaddr=0x%08x paddr=0x%08x\n"),
1.3    uch 			    _naddr_table, vaddr, paddr));
1.1    uch #endif
1.1    uch 			tab->vaddr = vaddr;
1.1    uch 			tab->paddr = paddr;
1.1    uch 			++tab;
1.1    uch 			++_naddr_table;
1.1    uch 		}
1.1    uch 	}
1.1    uch
1.1    uch #ifdef MEMORY_MAP_DEBUG
1.1    uch 	// dump virtual <-> physical address table
1.1    uch 	tab = _addr_table;
1.1    uch 	for (i = 0; i < _naddr_table;) {
1.1    uch 		for (int j = 0; j < 4; j++, i++, tab++)
1.1    uch 			DPRINTF((TEXT("%08x=%08x "), tab->vaddr, tab->paddr));
1.1    uch 		DPRINTF((TEXT("\n")));
1.1    uch 	}
1.1    uch #endif
1.1    uch 	DPRINTF((TEXT("allocated %d page. mapped %d page.\n"), npage,
1.3    uch 	    _naddr_table));
1.1    uch
1.1    uch 	return TRUE;
1.1    uch }
1.1    uch
1.1    uch BOOL
1.1    uch MemoryManager::getPage(vaddr_t &vaddr, paddr_t &paddr)
1.1    uch {
1.1    uch 	/* get plain page from the top */
1.4  enami 	if (_addr_table_idx >= _naddr_table ||
1.4  enami 	    _addr_table == NULL)
1.4  enami 		return FALSE;
1.4  enami
1.1    uch 	int idx = --_naddr_table;
1.1    uch
1.1    uch 	AddressTranslationTable *tab = &_addr_table[idx];
1.1    uch 	vaddr = tab->vaddr;
1.1    uch 	paddr = tab->paddr;
1.1    uch
1.1    uch 	return TRUE;
1.1    uch }
1.1    uch
1.1    uch BOOL
1.1    uch MemoryManager::getTaggedPage(vaddr_t &vaddr, paddr_t &paddr)
1.1    uch {
1.1    uch 	/* get tagged page from the bottom */
1.1    uch 	if (_addr_table_idx >= _naddr_table ||
1.1    uch 	    _addr_table == NULL) {
1.1    uch 		DPRINTF((TEXT("page insufficient.\n")));
1.1    uch 		return FALSE;
1.1    uch 	}
1.1    uch 	AddressTranslationTable *tab =
1.3    uch 	    &_addr_table[_addr_table_idx++];
1.1    uch 	vaddr = tab->vaddr;
1.1    uch 	paddr = tab->paddr;
1.1    uch
1.1    uch 	return TRUE;
1.1    uch }
1.1    uch
1.1    uch BOOL
1.1    uch MemoryManager::getTaggedPage(vaddr_t &v, paddr_t &p,
1.3    uch     struct PageTag **pvec, paddr_t &pvec_paddr)
1.1    uch {
1.1    uch 	if (!getTaggedPage(v, p))
1.1    uch 		return FALSE;
1.1    uch
1.1    uch 	*pvec =(struct PageTag *)v;
1.1    uch 	memset(*pvec, 0, sizeof(struct PageTag));
1.1    uch 	v += sizeof(struct PageTag);
1.1    uch 	pvec_paddr = p;
1.1    uch 	p += sizeof(struct PageTag);
1.1    uch
1.1    uch 	return TRUE;
1.1    uch }
1.1    uch
1.1    uch vaddr_t
1.1    uch MemoryManager::mapPhysicalPage(paddr_t paddr, psize_t size, u_int32_t flags)
1.1    uch {
1.1    uch 	paddr_t pstart = truncPage(paddr);
1.1    uch 	paddr_t pend = roundPage(paddr + size);
1.1    uch 	psize_t psize = pend - pstart;
1.1    uch
1.1    uch 	LPVOID p = VirtualAlloc(0, psize, MEM_RESERVE, PAGE_NOACCESS);
1.1    uch
1.1    uch 	int ok = VirtualCopy(p, LPVOID(pstart >> 8), psize,
1.3    uch 	    flags | PAGE_NOCACHE | PAGE_PHYSICAL);
1.1    uch 	if (!ok) {
1.1    uch 		DPRINTF((TEXT("can't map physical address 0x%08x\n"), paddr));
1.1    uch 		return ~0;
1.1    uch 	}
1.1    uch #if 0
1.1    uch 	DPRINTF((TEXT("start=0x%08x end=0x%08x size=0x%08x return=0x%08x\n"),
1.3    uch 	    pstart, pend, psize, vaddr_t(p) + vaddr_t(paddr - pstart)));
1.1    uch
1.1    uch #endif
1.1    uch
1.1    uch 	return vaddr_t(p) + vaddr_t(paddr - pstart);
1.1    uch }
1.1    uch
1.1    uch void
1.1    uch MemoryManager::unmapPhysicalPage(vaddr_t vaddr)
1.1    uch {
1.1    uch 	int ok = VirtualFree(LPVOID(truncPage(vaddr)), 0, MEM_RELEASE);
1.1    uch 	if (!ok)
1.1    uch 		DPRINTF((TEXT("can't release memory\n")));
1.1    uch }
1.1    uch
1.1    uch u_int32_t
1.1    uch MemoryManager::readPhysical4(paddr_t paddr)
1.1    uch {
1.1    uch 	vaddr_t v = mapPhysicalPage(paddr, 4, PAGE_READONLY);
1.1    uch 	u_int32_t val = *(u_int32_t *)v;
1.1    uch 	unmapPhysicalPage(v);
1.1    uch 	return val;
1.1    uch }
1.1    uch
1.1    uch //
1.1    uch //	Use LockPages()
1.1    uch //
1.1    uch MemoryManager_LockPages::MemoryManager_LockPages
1.1    uch (BOOL(*lock_pages)(LPVOID, DWORD, PDWORD, int),
1.3    uch     BOOL(*unlock_pages)(LPVOID, DWORD),
1.3    uch     Console *&cons, size_t pagesize, int shift)
1.1    uch 	:  MemoryManager(cons, pagesize)
1.1    uch {
1.1    uch 	_lock_pages	= lock_pages;
1.1    uch 	_unlock_pages	= unlock_pages;
1.1    uch 	_shift = shift;
1.1    uch 	DPRINTF((TEXT("use LockPages method.\n")));
1.1    uch }
1.1    uch
1.1    uch MemoryManager_LockPages::~MemoryManager_LockPages(void)
1.1    uch {
1.1    uch }
1.1    uch
1.1    uch paddr_t
1.1    uch MemoryManager_LockPages::searchPage(vaddr_t vaddr)
1.1    uch {
1.1    uch 	paddr_t paddr = ~0;
1.1    uch
1.1    uch 	if (!_lock_pages(LPVOID(vaddr), _page_size, PDWORD(&paddr), 1))
1.1    uch 		return paddr;
1.1    uch
1.1    uch 	if (!_unlock_pages(LPVOID(vaddr), _page_size)) {
1.1    uch 		DPRINTF((TEXT("can't unlock pages\n")));
1.1    uch 	}
1.1    uch
1.1    uch 	return(paddr >>(_page_shift - _shift)) << _page_shift;
1.1    uch }
1.1    uch
1.1    uch //
1.1    uch //	Use VirtualCopy()
1.1    uch //
1.1    uch MemoryManager_VirtualCopy::MemoryManager_VirtualCopy(Console *&cons,
1.3    uch     size_t pagesize)
1.1    uch 	: MemoryManager(cons, pagesize)
1.1    uch {
1.2    uch 	_search_guess = 0;
1.1    uch 	DPRINTF((TEXT("use VirtualCopy method.\n")));
1.1    uch }
1.1    uch
1.1    uch MemoryManager_VirtualCopy::~MemoryManager_VirtualCopy(void)
1.1    uch {
1.1    uch }
1.1    uch
1.1    uch paddr_t
1.1    uch MemoryManager_VirtualCopy::searchPage(vaddr_t vaddr)
1.1    uch {
1.1    uch 	paddr_t paddr = ~0;
1.1    uch 	int i;
1.1    uch
1.1    uch 	// search all D-RAM bank.
1.1    uch 	setMagic(vaddr);
1.2    uch  retry:
1.1    uch 	for (i = 0; i < _nbank; i++) {
1.1    uch 		paddr = searchBank(i);
1.1    uch 		if (paddr != ~0)
1.1    uch 			break;
1.1    uch 	}
1.2    uch 	if (_search_guess != 0 && paddr == ~0) {
1.2    uch 		_search_guess = 0;
1.2    uch 		goto retry;
1.2    uch 	}
1.2    uch
1.1    uch 	clearMagic();
1.1    uch
1.1    uch 	return paddr;
1.1    uch }
1.1    uch
1.1    uch paddr_t
1.1    uch MemoryManager_VirtualCopy::searchBank(int banknum)
1.1    uch {
1.1    uch 	LPVOID ref;
1.1    uch 	paddr_t paddr, pstart, pend, pfound = ~0;
1.2    uch 	paddr_t bstart, bend;
1.1    uch 	vaddr_t ofs;
1.1    uch
1.2    uch 	bstart = _bank[banknum].addr;
1.2    uch 	bend = _bank[banknum].addr + _bank[banknum].size;
1.2    uch
1.2    uch 	pstart = _search_guess ? _search_guess : bstart;
1.2    uch 	pend = bend;
1.2    uch
1.2    uch 	if (pstart < bstart || pstart >= pend)
1.2    uch 		return pfound;
1.1    uch
1.1    uch 	// reserve physical reference region
1.1    uch 	ref = VirtualAlloc(0, BLOCK_SIZE, MEM_RESERVE, PAGE_NOACCESS);
1.1    uch 	if (ref == 0) {
1.1    uch 		DPRINTF((TEXT("can't allocate virtual memory.\n")));
1.1    uch 		return pfound;
1.1    uch 	}
1.1    uch
1.1    uch 	for (paddr = pstart; paddr < pend; paddr += BLOCK_SIZE) {
1.1    uch 		if (!VirtualCopy(ref, LPVOID(paddr >> 8), BLOCK_SIZE,
1.3    uch 		    PAGE_READONLY | PAGE_NOCACHE | PAGE_PHYSICAL)) {
1.1    uch 			DPRINTF((TEXT("can't map physical addr 0x%08x(->0x%08x)\n"),
1.3    uch 			    ref, paddr));
1.1    uch 			goto release;
1.1    uch 		}
1.1    uch
1.1    uch 		// search magic in this region.
1.1    uch 		ofs = checkMagicRegion(vaddr_t(ref), BLOCK_SIZE, _page_size);
1.1    uch
1.1    uch 		// decommit reference region.
1.1    uch 		if (!VirtualFree(ref, BLOCK_SIZE, MEM_DECOMMIT)) {
1.1    uch 			DPRINTF((TEXT("can't decommit addr 0x%08x(->0x%08x)\n"),
1.3    uch 			    ref, paddr));
1.1    uch 			goto release;
1.1    uch 		}
1.1    uch
1.1    uch 		if (ofs != ~0) {
1.1    uch 			pfound = paddr + ofs;
1.2    uch 			_search_guess = paddr;
1.1    uch 			break;
1.1    uch 		}
1.1    uch 	}
1.1    uch  release:
1.1    uch 	if (!VirtualFree(ref, 0, MEM_RELEASE))
1.1    uch 		DPRINTF((TEXT("can't release memory\n")));
1.1    uch
1.1    uch 	return pfound;
1.1    uch }