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[/] [ao486/] [trunk/] [bochs486/] [memory/] [memory.h] - Blame information for rev 4

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/////////////////////////////////////////////////////////////////////////
// $Id: memory.h 11556 2012-12-02 19:59:23Z vruppert $
/////////////////////////////////////////////////////////////////////////
//
//  Copyright (C) 2001-2009  The Bochs Project
//
//  I/O memory handlers API Copyright (C) 2003 by Frank Cornelis
//
//  This library is free software; you can redistribute it and/or
//  modify it under the terms of the GNU Lesser General Public
//  License as published by the Free Software Foundation; either
//  version 2 of the License, or (at your option) any later version.
//
//  This library is distributed in the hope that it will be useful,
//  but WITHOUT ANY WARRANTY; without even the implied warranty of
//  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
//  Lesser General Public License for more details.
//
//  You should have received a copy of the GNU Lesser General Public
//  License along with this library; if not, write to the Free Software
//  Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301 USA
//
/////////////////////////////////////////////////////////////////////////
 
#ifndef BX_MEM_H
#  define BX_MEM_H 1
 
#if BX_USE_MEM_SMF
// if static member functions on, then there is only one memory
#  define BX_MEM_SMF  static
#  define BX_MEM_THIS BX_MEM(0)->
#else
#  define BX_MEM_SMF
#  define BX_MEM_THIS this->
#endif
 
class BX_CPU_C;
 
                                       // 512K BIOS ROM @0xfff80000
#define BIOSROMSZ ((Bit32u)(1 << 21))  //   2M BIOS ROM @0xffe00000, must be a power of 2
#define EXROMSIZE  (0x20000)           // ROMs 0xc0000-0xdffff (area 0xe0000-0xfffff=bios mapped)
#define BIOS_MASK (BIOSROMSZ-1)
#define EXROM_MASK (EXROMSIZE-1)
 
#define BIOS_MAP_LAST128K(addr) (((addr) | 0xfff00000) & BIOS_MASK)
 
enum memory_area_t {
  BX_MEM_AREA_C0000 = 0,
  BX_MEM_AREA_C4000,
  BX_MEM_AREA_C8000,
  BX_MEM_AREA_CC000,
  BX_MEM_AREA_D0000,
  BX_MEM_AREA_D4000,
  BX_MEM_AREA_D8000,
  BX_MEM_AREA_DC000,
  BX_MEM_AREA_E0000,
  BX_MEM_AREA_E4000,
  BX_MEM_AREA_E8000,
  BX_MEM_AREA_EC000,
  BX_MEM_AREA_F0000
};
 
typedef bx_bool (*memory_handler_t)(bx_phy_address addr, unsigned len, void *data, void *param);
// return a pointer to 4K region containing <addr> or NULL if direct access is not allowed
// same format as getHostMemAddr method
typedef Bit8u* (*memory_direct_access_handler_t)(bx_phy_address addr, unsigned rw, void *param);
 
struct memory_handler_struct {
  struct memory_handler_struct *next;
  void *param;
  bx_phy_address begin;
  bx_phy_address end;
  Bit16u bitmap;
  memory_handler_t read_handler;
  memory_handler_t write_handler;
  memory_direct_access_handler_t da_handler;
};
 
#define SMRAM_CODE  1
#define SMRAM_DATA  2
 
class BOCHSAPI BX_MEM_C : public logfunctions {
private:
  struct memory_handler_struct **memory_handlers;
  bx_bool pci_enabled;
  bx_bool bios_write_enabled;
  bx_bool smram_available;
  bx_bool smram_enable;
  bx_bool smram_restricted;
 
  Bit64u  len, allocated;  // could be > 4G
  Bit8u   *actual_vector;
  Bit8u   *vector;   // aligned correctly
  Bit8u  **blocks;
  Bit8u   *rom;      // 512k BIOS rom space + 128k expansion rom space
  Bit8u   *bogus;    // 4k for unexisting memory
  bx_bool rom_present[65];
  bx_bool memory_type[13][2];
 
  Bit32u used_blocks;
#if BX_LARGE_RAMFILE
  static Bit8u * const swapped_out; // NULL; // (NULL - sizeof(Bit8u));
  Bit32u  next_swapout_idx;
  FILE    *overflow_file;
 
  BX_MEM_SMF void   read_block(Bit32u block);
#endif
 
public:
  BX_MEM_C();
 ~BX_MEM_C();
 
  BX_MEM_SMF Bit8u*  get_vector(bx_phy_address addr);
  BX_MEM_SMF void    init_memory(Bit64u guest, Bit64u host);
  BX_MEM_SMF void    cleanup_memory(void);
 
  BX_MEM_SMF void    enable_smram(bx_bool enable, bx_bool restricted);
  BX_MEM_SMF void    disable_smram(void);
  BX_MEM_SMF bx_bool is_smram_accessible(void);
 
  BX_MEM_SMF void    set_bios_write(bx_bool enabled);
  BX_MEM_SMF void    set_memory_type(memory_area_t area, bx_bool rw, bx_bool dram);
 
  BX_MEM_SMF Bit8u*  getHostMemAddr(BX_CPU_C *cpu, bx_phy_address addr, unsigned rw);
 
  // Note: accesses should always be contained within a single page
  BX_MEM_SMF void    readPhysicalPage(BX_CPU_C *cpu, bx_phy_address addr,
                                      unsigned len, void *data);
  BX_MEM_SMF void    writePhysicalPage(BX_CPU_C *cpu, bx_phy_address addr,
                                       unsigned len, void *data);
 
  BX_MEM_SMF void    dmaReadPhysicalPage(bx_phy_address addr, unsigned len, Bit8u *data);
  BX_MEM_SMF void    dmaWritePhysicalPage(bx_phy_address addr, unsigned len, Bit8u *data);
 
  BX_MEM_SMF void    load_ROM(const char *path, bx_phy_address romaddress, Bit8u type);
  BX_MEM_SMF void    load_RAM(const char *path, bx_phy_address romaddress, Bit8u type);
 
#if (BX_DEBUGGER || BX_DISASM || BX_GDBSTUB)
  BX_MEM_SMF bx_bool dbg_fetch_mem(BX_CPU_C *cpu, bx_phy_address addr, unsigned len, Bit8u *buf);
#endif
#if (BX_DEBUGGER || BX_GDBSTUB)
  BX_MEM_SMF bx_bool dbg_set_mem(bx_phy_address addr, unsigned len, Bit8u *buf);
  BX_MEM_SMF bx_bool dbg_crc32(bx_phy_address addr1, bx_phy_address addr2, Bit32u *crc);
#endif
 
  BX_MEM_SMF bx_bool registerMemoryHandlers(void *param, memory_handler_t read_handler,
                  memory_handler_t write_handler, memory_direct_access_handler_t da_handler,
                  bx_phy_address begin_addr, bx_phy_address end_addr);
  BX_MEM_SMF BX_CPP_INLINE bx_bool registerMemoryHandlers(void *param, memory_handler_t read_handler,
                  memory_handler_t write_handler,
                  bx_phy_address begin_addr, bx_phy_address end_addr)
  {
     return registerMemoryHandlers(param, read_handler, write_handler, NULL, begin_addr, end_addr);
  }
  BX_MEM_SMF bx_bool unregisterMemoryHandlers(void *param, bx_phy_address begin_addr, bx_phy_address end_addr);
 
  BX_MEM_SMF Bit64u  get_memory_len(void);
  BX_MEM_SMF void allocate_block(Bit32u index);
  BX_MEM_SMF Bit8u* alloc_vector_aligned(Bit32u bytes, Bit32u alignment);
 
#if BX_SUPPORT_MONITOR_MWAIT
  BX_MEM_SMF bx_bool is_monitor(bx_phy_address begin_addr, unsigned len);
  BX_MEM_SMF void    check_monitor(bx_phy_address addr, unsigned len);
#endif
 
  void register_state(void);
 
  friend void ramfile_save_handler(void *devptr, FILE *fp);
  friend Bit64s memory_param_save_handler(void *devptr, bx_param_c *param);
  friend void memory_param_restore_handler(void *devptr, bx_param_c *param, Bit64s val);
};
 
BOCHSAPI extern BX_MEM_C bx_mem;
 
// must be power of two
#define BX_MEM_BLOCK_LEN (1024*1024) /* 1M blocks */
 
/*
BX_CPP_INLINE Bit8u* BX_MEM_C::get_vector(bx_phy_address addr)
{
  return (BX_MEM_THIS vector + addr);
}
*/
 
BX_CPP_INLINE Bit8u* BX_MEM_C::get_vector(bx_phy_address addr)
{
  Bit32u block = (Bit32u)(addr / BX_MEM_BLOCK_LEN);
#if (BX_LARGE_RAMFILE)
  if (!BX_MEM_THIS blocks[block] || (BX_MEM_THIS blocks[block] == BX_MEM_THIS swapped_out))
#else
  if (!BX_MEM_THIS blocks[block])
#endif
    allocate_block(block);
 
  return BX_MEM_THIS blocks[block] + (Bit32u)(addr & (BX_MEM_BLOCK_LEN-1));
}
 
BX_CPP_INLINE Bit64u BX_MEM_C::get_memory_len(void)
{
  return (BX_MEM_THIS len);
}
 
#endif

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[/] [ao486/] [trunk/] [bochs486/] [memory/] [memory.h] - Blame information for rev 4

Line No.	Rev	Author	Line
1	2	alfik	`/////////////////////////////////////////////////////////////////////////`
2			`// $Id: memory.h 11556 2012-12-02 19:59:23Z vruppert $`
3			`/////////////////////////////////////////////////////////////////////////`
4			`//`
5			`// Copyright (C) 2001-2009 The Bochs Project`
6			`//`
7			`// I/O memory handlers API Copyright (C) 2003 by Frank Cornelis`
8			`//`
9			`// This library is free software; you can redistribute it and/or`
10			`// modify it under the terms of the GNU Lesser General Public`
11			`// License as published by the Free Software Foundation; either`
12			`// version 2 of the License, or (at your option) any later version.`
13			`//`
14			`// This library is distributed in the hope that it will be useful,`
15			`// but WITHOUT ANY WARRANTY; without even the implied warranty of`
16			`// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU`
17			`// Lesser General Public License for more details.`
18			`//`
19			`// You should have received a copy of the GNU Lesser General Public`
20			`// License along with this library; if not, write to the Free Software`
21			`// Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA`
22			`//`
23			`/////////////////////////////////////////////////////////////////////////`
24
25			`#ifndef BX_MEM_H`
26			`# define BX_MEM_H 1`
27
28			`#if BX_USE_MEM_SMF`
29			`// if static member functions on, then there is only one memory`
30			`# define BX_MEM_SMF static`
31			`# define BX_MEM_THIS BX_MEM(0)->`
32			`#else`
33			`# define BX_MEM_SMF`
34			`# define BX_MEM_THIS this->`
35			`#endif`
36
37			`class BX_CPU_C;`
38
39			`// 512K BIOS ROM @0xfff80000`
40			`#define BIOSROMSZ ((Bit32u)(1 << 21)) // 2M BIOS ROM @0xffe00000, must be a power of 2`
41			`#define EXROMSIZE (0x20000) // ROMs 0xc0000-0xdffff (area 0xe0000-0xfffff=bios mapped)`
42			`#define BIOS_MASK (BIOSROMSZ-1)`
43			`#define EXROM_MASK (EXROMSIZE-1)`
44
45			`#define BIOS_MAP_LAST128K(addr) (((addr) \| 0xfff00000) & BIOS_MASK)`
46
47			`enum memory_area_t {`
48			`BX_MEM_AREA_C0000 = 0,`
49			`BX_MEM_AREA_C4000,`
50			`BX_MEM_AREA_C8000,`
51			`BX_MEM_AREA_CC000,`
52			`BX_MEM_AREA_D0000,`
53			`BX_MEM_AREA_D4000,`
54			`BX_MEM_AREA_D8000,`
55			`BX_MEM_AREA_DC000,`
56			`BX_MEM_AREA_E0000,`
57			`BX_MEM_AREA_E4000,`
58			`BX_MEM_AREA_E8000,`
59			`BX_MEM_AREA_EC000,`
60			`BX_MEM_AREA_F0000`
61			`};`
62
63			`typedef bx_bool (memory_handler_t)(bx_phy_address addr, unsigned len, void data, void *param);`
64			`// return a pointer to 4K region containing <addr> or NULL if direct access is not allowed`
65			`// same format as getHostMemAddr method`
66			`typedef Bit8u* (memory_direct_access_handler_t)(bx_phy_address addr, unsigned rw, void param);`
67
68			`struct memory_handler_struct {`
69			`struct memory_handler_struct *next;`
70			`void *param;`
71			`bx_phy_address begin;`
72			`bx_phy_address end;`
73			`Bit16u bitmap;`
74			`memory_handler_t read_handler;`
75			`memory_handler_t write_handler;`
76			`memory_direct_access_handler_t da_handler;`
77			`};`
78
79			`#define SMRAM_CODE 1`
80			`#define SMRAM_DATA 2`
81
82			`class BOCHSAPI BX_MEM_C : public logfunctions {`
83			`private:`
84			`struct memory_handler_struct **memory_handlers;`
85			`bx_bool pci_enabled;`
86			`bx_bool bios_write_enabled;`
87			`bx_bool smram_available;`
88			`bx_bool smram_enable;`
89			`bx_bool smram_restricted;`
90
91			`Bit64u len, allocated; // could be > 4G`
92			`Bit8u *actual_vector;`
93			`Bit8u *vector; // aligned correctly`
94			`Bit8u **blocks;`
95			`Bit8u *rom; // 512k BIOS rom space + 128k expansion rom space`
96			`Bit8u *bogus; // 4k for unexisting memory`
97			`bx_bool rom_present[65];`
98			`bx_bool memory_type[13][2];`
99
100			`Bit32u used_blocks;`
101			`#if BX_LARGE_RAMFILE`
102			`static Bit8u * const swapped_out; // NULL; // (NULL - sizeof(Bit8u));`
103			`Bit32u next_swapout_idx;`
104			`FILE *overflow_file;`
105
106			`BX_MEM_SMF void read_block(Bit32u block);`
107			`#endif`
108
109			`public:`
110			`BX_MEM_C();`
111			`~BX_MEM_C();`
112
113			`BX_MEM_SMF Bit8u* get_vector(bx_phy_address addr);`
114			`BX_MEM_SMF void init_memory(Bit64u guest, Bit64u host);`
115			`BX_MEM_SMF void cleanup_memory(void);`
116
117			`BX_MEM_SMF void enable_smram(bx_bool enable, bx_bool restricted);`
118			`BX_MEM_SMF void disable_smram(void);`
119			`BX_MEM_SMF bx_bool is_smram_accessible(void);`
120
121			`BX_MEM_SMF void set_bios_write(bx_bool enabled);`
122			`BX_MEM_SMF void set_memory_type(memory_area_t area, bx_bool rw, bx_bool dram);`
123
124			`BX_MEM_SMF Bit8u* getHostMemAddr(BX_CPU_C *cpu, bx_phy_address addr, unsigned rw);`
125
126			`// Note: accesses should always be contained within a single page`
127			`BX_MEM_SMF void readPhysicalPage(BX_CPU_C *cpu, bx_phy_address addr,`
128			`unsigned len, void *data);`
129			`BX_MEM_SMF void writePhysicalPage(BX_CPU_C *cpu, bx_phy_address addr,`
130			`unsigned len, void *data);`
131
132			`BX_MEM_SMF void dmaReadPhysicalPage(bx_phy_address addr, unsigned len, Bit8u *data);`
133			`BX_MEM_SMF void dmaWritePhysicalPage(bx_phy_address addr, unsigned len, Bit8u *data);`
134
135			`BX_MEM_SMF void load_ROM(const char *path, bx_phy_address romaddress, Bit8u type);`
136			`BX_MEM_SMF void load_RAM(const char *path, bx_phy_address romaddress, Bit8u type);`
137
138			`#if (BX_DEBUGGER \|\| BX_DISASM \|\| BX_GDBSTUB)`
139			`BX_MEM_SMF bx_bool dbg_fetch_mem(BX_CPU_C cpu, bx_phy_address addr, unsigned len, Bit8u buf);`
140			`#endif`
141			`#if (BX_DEBUGGER \|\| BX_GDBSTUB)`
142			`BX_MEM_SMF bx_bool dbg_set_mem(bx_phy_address addr, unsigned len, Bit8u *buf);`
143			`BX_MEM_SMF bx_bool dbg_crc32(bx_phy_address addr1, bx_phy_address addr2, Bit32u *crc);`
144			`#endif`
145
146			`BX_MEM_SMF bx_bool registerMemoryHandlers(void *param, memory_handler_t read_handler,`
147			`memory_handler_t write_handler, memory_direct_access_handler_t da_handler,`
148			`bx_phy_address begin_addr, bx_phy_address end_addr);`
149			`BX_MEM_SMF BX_CPP_INLINE bx_bool registerMemoryHandlers(void *param, memory_handler_t read_handler,`
150			`memory_handler_t write_handler,`
151			`bx_phy_address begin_addr, bx_phy_address end_addr)`
152			`{`
153			`return registerMemoryHandlers(param, read_handler, write_handler, NULL, begin_addr, end_addr);`
154			`}`
155			`BX_MEM_SMF bx_bool unregisterMemoryHandlers(void *param, bx_phy_address begin_addr, bx_phy_address end_addr);`
156
157			`BX_MEM_SMF Bit64u get_memory_len(void);`
158			`BX_MEM_SMF void allocate_block(Bit32u index);`
159			`BX_MEM_SMF Bit8u* alloc_vector_aligned(Bit32u bytes, Bit32u alignment);`
160
161			`#if BX_SUPPORT_MONITOR_MWAIT`
162			`BX_MEM_SMF bx_bool is_monitor(bx_phy_address begin_addr, unsigned len);`
163			`BX_MEM_SMF void check_monitor(bx_phy_address addr, unsigned len);`
164			`#endif`
165
166			`void register_state(void);`
167
168			`friend void ramfile_save_handler(void devptr, FILE fp);`
169			`friend Bit64s memory_param_save_handler(void devptr, bx_param_c param);`
170			`friend void memory_param_restore_handler(void devptr, bx_param_c param, Bit64s val);`
171			`};`
172
173			`BOCHSAPI extern BX_MEM_C bx_mem;`
174
175			`// must be power of two`
176			`#define BX_MEM_BLOCK_LEN (10241024) / 1M blocks */`
177
178			`/*`
179			`BX_CPP_INLINE Bit8u* BX_MEM_C::get_vector(bx_phy_address addr)`
180			`{`
181			`return (BX_MEM_THIS vector + addr);`
182			`}`
183			`*/`
184
185			`BX_CPP_INLINE Bit8u* BX_MEM_C::get_vector(bx_phy_address addr)`
186			`{`
187			`Bit32u block = (Bit32u)(addr / BX_MEM_BLOCK_LEN);`
188			`#if (BX_LARGE_RAMFILE)`
189			`if (!BX_MEM_THIS blocks[block] \|\| (BX_MEM_THIS blocks[block] == BX_MEM_THIS swapped_out))`
190			`#else`
191			`if (!BX_MEM_THIS blocks[block])`
192			`#endif`
193			`allocate_block(block);`
194
195			`return BX_MEM_THIS blocks[block] + (Bit32u)(addr & (BX_MEM_BLOCK_LEN-1));`
196			`}`
197
198			`BX_CPP_INLINE Bit64u BX_MEM_C::get_memory_len(void)`
199			`{`
200			`return (BX_MEM_THIS len);`
201			`}`
202
203			`#endif`