f822257511
BX_SUPPORT_APIC were used. To follow the pattern used by other names like this, I changed them all to BX_SUPPORT_APIC. Thanks to Tom Lindström for chasing this down!
475 lines
14 KiB
C++
475 lines
14 KiB
C++
// Copyright (C) 2001 MandrakeSoft S.A.
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//
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// MandrakeSoft S.A.
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// 43, rue d'Aboukir
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// 75002 Paris - France
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// http://www.linux-mandrake.com/
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// http://www.mandrakesoft.com/
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//
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// This library is free software; you can redistribute it and/or
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// modify it under the terms of the GNU Lesser General Public
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// License as published by the Free Software Foundation; either
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// version 2 of the License, or (at your option) any later version.
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//
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// This library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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// Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public
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// License along with this library; if not, write to the Free Software
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// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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#include "bochs.h"
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#define LOG_THIS BX_MEM_THIS
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#if BX_PROVIDE_CPU_MEMORY
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void
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BX_MEM_C::write_physical(BX_CPU_C *cpu, Bit32u addr, unsigned len, void *data)
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{
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Bit8u *data_ptr;
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Bit32u a20addr;
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a20addr = A20ADDR(addr);
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BX_INSTR_PHY_WRITE(a20addr, len);
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#if BX_DEBUGGER
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// (mch) Check for physical write break points, TODO
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// (bbd) Each breakpoint should have an associated CPU#, TODO
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for (int i = 0; i < num_write_watchpoints; i++)
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if (write_watchpoint[i] == a20addr) {
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BX_CPU(0)->break_point = BREAK_POINT_WRITE;
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break;
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}
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#endif
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if ( (a20addr + len) <= BX_MEM_THIS len ) {
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// all of data is within limits of physical memory
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if ( (a20addr & 0xfff80000) != 0x00080000 ) {
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if (len == 4) {
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if ((a20addr & 0x00000003) == 0) {
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// write 4byte data to aligned memory location
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Bit32u data32;
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data32 = * (Bit32u *) data;
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#ifdef BX_BIG_ENDIAN
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data32 = (data32 << 24) | (data32 >> 24) |
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((data32&0x00ff0000)>>8) | ((data32&0x0000ff00)<<8);
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#endif
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* ((Bit32u *) (&vector[a20addr])) = data32;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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return;
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}
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else {
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Bit32u data32;
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data32 = * (Bit32u *) data;
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* ((Bit8u *) (&vector[a20addr])) = data32; data32 >>= 8;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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* ((Bit8u *) (&vector[A20ADDR(addr+1)])) = data32; data32 >>= 8;
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* ((Bit8u *) (&vector[A20ADDR(addr+2)])) = data32; data32 >>= 8;
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* ((Bit8u *) (&vector[A20ADDR(addr+3)])) = data32;
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// worst case, last byte is in different page; possible extra dirty page
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BX_DBG_DIRTY_PAGE(A20ADDR(addr+3) >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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return;
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}
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}
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if (len == 2) {
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if ((a20addr & 0x00000001) == 0) {
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// write 2-byte data to aligned memory location
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Bit16u data16;
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data16 = * (Bit16u *) data;
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#ifdef BX_BIG_ENDIAN
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data16 = (data16 >> 8) | (data16 << 8);
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#endif
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* ((Bit16u *) (&vector[a20addr])) = data16;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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return;
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}
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else {
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Bit16u data16;
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data16 = * (Bit16u *) data;
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* ((Bit8u *) (&vector[a20addr])) = (Bit8u) data16;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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* ((Bit8u *) (&vector[A20ADDR(a20addr+1)])) = (data16 >> 8);
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BX_DBG_DIRTY_PAGE(A20ADDR(a20addr+1) >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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return;
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}
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}
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if (len == 1) {
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Bit8u data8;
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data8 = * (Bit8u *) data;
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* ((Bit8u *) (&vector[a20addr])) = data8;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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return;
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}
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// len == 3 case can just fall thru to special cases handling
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}
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#ifdef BX_LITTLE_ENDIAN
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data_ptr = (Bit8u *) data;
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#else // BX_BIG_ENDIAN
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data_ptr = (Bit8u *) data + (len - 1);
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#endif
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write_one:
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if ( (a20addr & 0xfff80000) != 0x00080000 ) {
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// addr *not* in range 00080000 .. 000FFFFF
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vector[a20addr] = *data_ptr;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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inc_one:
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if (len == 1) return;
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len--;
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addr++;
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a20addr = A20ADDR(addr);
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#ifdef BX_LITTLE_ENDIAN
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data_ptr++;
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#else // BX_BIG_ENDIAN
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data_ptr--;
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#endif
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goto write_one;
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}
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// addr in range 00080000 .. 000FFFFF
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if (a20addr <= 0x0009ffff) {
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// regular memory 80000 .. 9FFFF
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vector[a20addr] = *data_ptr;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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goto inc_one;
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}
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if (a20addr <= 0x000bffff) {
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// VGA memory A0000 .. BFFFF
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BX_VGA_MEM_WRITE(a20addr, *data_ptr);
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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BX_DBG_UCMEM_REPORT(a20addr, 1, BX_WRITE, *data_ptr); // obsolete
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goto inc_one;
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}
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// adapter ROM C0000 .. DFFFF
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// ROM BIOS memory E0000 .. FFFFF
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// (ignore write)
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//BX_INFO(("ROM lock %08x: len=%u",
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// (unsigned) a20addr, (unsigned) len));
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#if BX_PCI_SUPPORT == 0
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#if BX_SHADOW_RAM
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// Write it since its in shadow RAM
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vector[a20addr] = *data_ptr;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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#else
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// ignore write to ROM
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#endif
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#else
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// Write Based on 440fx Programming
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if (bx_options.i440FXSupport &&
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((a20addr >= 0xC0000) && (a20addr <= 0xFFFFF))) {
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switch (bx_devices.pci->wr_memType(a20addr & 0xFC000)) {
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case 0x0: // Writes to ShadowRAM
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// BX_INFO(("Writing to ShadowRAM %08x, len %u ! ", (unsigned) a20addr, (unsigned) len));
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vector[a20addr] = *data_ptr;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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goto inc_one;
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case 0x1: // Writes to ROM, Inhibit
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// bx_pci.s.i440fx.shadow[(a20addr - 0xc0000)] = *data_ptr;
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// BX_INFO(("Writing to ROM %08x, Data %02x ! ", (unsigned) a20addr, *data_ptr));
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goto inc_one;
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default:
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BX_PANIC(("write_physical: default case"));
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goto inc_one;
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}
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}
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#endif
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goto inc_one;
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}
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else {
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// some or all of data is outside limits of physical memory
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unsigned i;
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#ifdef BX_LITTLE_ENDIAN
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data_ptr = (Bit8u *) data;
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#else // BX_BIG_ENDIAN
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data_ptr = (Bit8u *) data + (len - 1);
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#endif
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#if BX_SUPPORT_APIC
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bx_generic_apic_c *local_apic = &cpu->local_apic;
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bx_generic_apic_c *ioapic = bx_devices.ioapic;
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if (local_apic->is_selected (a20addr, len)) {
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local_apic->write (a20addr, (Bit32u *)data, len);
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return;
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} else if (ioapic->is_selected (a20addr, len)) {
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ioapic->write (a20addr, (Bit32u *)data, len);
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return;
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}
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else
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#endif
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for (i = 0; i < len; i++) {
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if (a20addr < BX_MEM_THIS len) {
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vector[a20addr] = *data_ptr;
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BX_DBG_DIRTY_PAGE(a20addr >> 12);
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BX_DYN_DIRTY_PAGE(a20addr >> 12);
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}
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// otherwise ignore byte, since it overruns memory
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addr++;
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a20addr = A20ADDR(addr);
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#ifdef BX_LITTLE_ENDIAN
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data_ptr++;
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#else // BX_BIG_ENDIAN
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data_ptr--;
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#endif
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}
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return;
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}
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}
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void
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BX_MEM_C::read_physical(BX_CPU_C *cpu, Bit32u addr, unsigned len, void *data)
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{
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Bit8u *data_ptr;
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Bit32u a20addr;
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a20addr = A20ADDR(addr);
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BX_INSTR_PHY_READ(a20addr, len);
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#if BX_DEBUGGER
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// (mch) Check for physical read break points, TODO
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// (bbd) Each breakpoint should have an associated CPU#, TODO
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for (int i = 0; i < num_read_watchpoints; i++)
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if (read_watchpoint[i] == a20addr) {
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BX_CPU(0)->break_point = BREAK_POINT_READ;
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break;
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}
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#endif
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if ( (a20addr + len) <= BX_MEM_THIS len ) {
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// all of data is within limits of physical memory
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if ( (a20addr & 0xfff80000) != 0x00080000 ) {
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if (len == 4) {
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if ((a20addr & 0x00000003) == 0) {
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// read 4-byte data from aligned memory location
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Bit32u data32;
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data32 = * ((Bit32u *) (&vector[a20addr]));
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#ifdef BX_BIG_ENDIAN
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data32 = (data32 << 24) | (data32 >> 24) |
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((data32&0x00ff0000)>>8) | ((data32&0x0000ff00)<<8);
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#endif
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* (Bit32u *) data = data32;
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return;
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}
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else {
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Bit32u data32;
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data32 = * ((Bit8u *) (&vector[A20ADDR(addr+3)])); data32 <<= 8;
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data32 |= * ((Bit8u *) (&vector[A20ADDR(addr+2)])); data32 <<= 8;
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data32 |= * ((Bit8u *) (&vector[A20ADDR(addr+1)])); data32 <<= 8;
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data32 |= * ((Bit8u *) (&vector[a20addr]));
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* (Bit32u *) data = data32;
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return;
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}
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}
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if (len == 2) {
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if ((a20addr & 0x00000001) == 0) {
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// read 2-byte data from aligned memory location
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Bit16u data16;
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data16 = * ((Bit16u *) (&vector[a20addr]));
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#ifdef BX_BIG_ENDIAN
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data16 = (data16 >> 8) | (data16 << 8);
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#endif
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* (Bit16u *) data = data16;
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return;
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}
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else {
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Bit16u data16;
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data16 = * ((Bit8u *) (&vector[A20ADDR(addr+1)])); data16 <<= 8;
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data16 |= * ((Bit8u *) (&vector[a20addr]));
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* (Bit16u *) data = data16;
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return;
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}
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}
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if (len == 1) {
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Bit8u data8;
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data8 = * ((Bit8u *) (&vector[a20addr]));
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* (Bit8u *) data = data8;
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return;
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}
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// len == 3 case can just fall thru to special cases handling
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}
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#ifdef BX_LITTLE_ENDIAN
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data_ptr = (Bit8u *) data;
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#else // BX_BIG_ENDIAN
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data_ptr = (Bit8u *) data + (len - 1);
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#endif
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read_one:
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if ( (a20addr & 0xfff80000) != 0x00080000 ) {
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// addr *not* in range 00080000 .. 000FFFFF
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*data_ptr = vector[a20addr];
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inc_one:
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if (len == 1) return;
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len--;
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addr++;
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a20addr = A20ADDR(addr);
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#ifdef BX_LITTLE_ENDIAN
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data_ptr++;
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#else // BX_BIG_ENDIAN
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data_ptr--;
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#endif
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goto read_one;
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}
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// addr in range 00080000 .. 000FFFFF
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#if BX_PCI_SUPPORT == 0
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if ((a20addr <= 0x0009ffff) || (a20addr >= 0x000c0000) ) {
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// regular memory 80000 .. 9FFFF, C0000 .. F0000
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*data_ptr = vector[a20addr];
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goto inc_one;
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}
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// VGA memory A0000 .. BFFFF
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*data_ptr = BX_VGA_MEM_READ(a20addr);
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BX_DBG_UCMEM_REPORT(a20addr, 1, BX_READ, *data_ptr); // obsolete
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goto inc_one;
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#else // #if BX_PCI_SUPPORT == 0
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if (a20addr <= 0x0009ffff) {
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*data_ptr = vector[a20addr];
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goto inc_one;
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}
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if (a20addr <= 0x000BFFFF) {
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// VGA memory A0000 .. BFFFF
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*data_ptr = BX_VGA_MEM_READ(a20addr);
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BX_DBG_UCMEM_REPORT(a20addr, 1, BX_READ, *data_ptr);
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goto inc_one;
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}
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// a20addr in C0000 .. FFFFF
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if (!bx_options.i440FXSupport) {
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*data_ptr = vector[a20addr];
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goto inc_one;
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}
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else {
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switch (bx_devices.pci->rd_memType(a20addr & 0xFC000)) {
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case 0x0: // Read from ShadowRAM
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*data_ptr = vector[a20addr];
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BX_INFO(("Reading from ShadowRAM %08x, Data %02x ", (unsigned) a20addr, *data_ptr));
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goto inc_one;
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case 0x1: // Read from ROM
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*data_ptr = bx_pci.s.i440fx.shadow[(a20addr - 0xc0000)];
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//BX_INFO(("Reading from ROM %08x, Data %02x ", (unsigned) a20addr, *data_ptr));
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goto inc_one;
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default:
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BX_PANIC(("::read_physical: default case"));
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}
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}
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goto inc_one;
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#endif // #if BX_PCI_SUPPORT == 0
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}
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else {
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// some or all of data is outside limits of physical memory
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unsigned i;
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#ifdef BX_LITTLE_ENDIAN
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data_ptr = (Bit8u *) data;
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#else // BX_BIG_ENDIAN
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data_ptr = (Bit8u *) data + (len - 1);
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#endif
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#if BX_SUPPORT_APIC
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bx_generic_apic_c *local_apic = &cpu->local_apic;
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bx_generic_apic_c *ioapic = bx_devices.ioapic;
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if (local_apic->is_selected (addr, len)) {
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local_apic->read (addr, data, len);
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return;
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} else if (ioapic->is_selected (addr, len)) {
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ioapic->read (addr, data, len);
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return;
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}
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#endif
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for (i = 0; i < len; i++) {
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#if BX_PCI_SUPPORT == 0
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if (a20addr < BX_MEM_THIS len)
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*data_ptr = vector[a20addr];
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else
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*data_ptr = 0xff;
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#else // BX_PCI_SUPPORT == 0
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if (a20addr < BX_MEM_THIS len) {
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if ((a20addr >= 0x000C0000) && (a20addr <= 0x000FFFFF)) {
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if (!bx_options.i440FXSupport)
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*data_ptr = vector[a20addr];
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else {
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switch (bx_devices.pci->rd_memType(a20addr & 0xFC000)) {
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case 0x0: // Read from ROM
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*data_ptr = vector[a20addr];
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//BX_INFO(("Reading from ROM %08x, Data %02x ", (unsigned) a20addr, *data_ptr));
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break;
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case 0x1: // Read from Shadow RAM
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*data_ptr = bx_pci.s.i440fx.shadow[(a20addr - 0xc0000)];
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BX_INFO(("Reading from ShadowRAM %08x, Data %02x ", (unsigned) a20addr, *data_ptr));
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break;
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default:
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BX_PANIC(("read_physical: default case"));
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} // Switch
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}
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}
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else {
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*data_ptr = vector[a20addr];
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BX_INFO(("Reading from Norm %08x, Data %02x ", (unsigned) a20addr, *data_ptr));
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}
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}
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else
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*data_ptr = 0xff;
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#endif // BX_PCI_SUPPORT == 0
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addr++;
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a20addr = A20ADDR(addr);
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#ifdef BX_LITTLE_ENDIAN
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data_ptr++;
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#else // BX_BIG_ENDIAN
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data_ptr--;
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#endif
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}
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return;
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}
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}
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#endif // #if BX_PROVIDE_CPU_MEMORY
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