VirtualBox

source: vbox/trunk/src/VBox/VMM/Docs-RawMode.cpp@ 98910

Last change on this file since 98910 was 98103, checked in by vboxsync, 2 years ago

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1/* $Id: Docs-RawMode.cpp 98103 2023-01-17 14:15:46Z vboxsync $ */
2/** @file
3 * This file contains the documentation of the raw-mode execution.
4 */
5
6/*
7 * Copyright (C) 2006-2023 Oracle and/or its affiliates.
8 *
9 * This file is part of VirtualBox base platform packages, as
10 * available from https://www.virtualbox.org.
11 *
12 * This program is free software; you can redistribute it and/or
13 * modify it under the terms of the GNU General Public License
14 * as published by the Free Software Foundation, in version 3 of the
15 * License.
16 *
17 * This program is distributed in the hope that it will be useful, but
18 * WITHOUT ANY WARRANTY; without even the implied warranty of
19 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
20 * General Public License for more details.
21 *
22 * You should have received a copy of the GNU General Public License
23 * along with this program; if not, see <https://www.gnu.org/licenses>.
24 *
25 * SPDX-License-Identifier: GPL-3.0-only
26 */
27
28
29
30/** @page pg_raw Raw-mode Code Execution
31 *
32 * VirtualBox 0.0 thru 6.0 implemented a mode of guest code execution that
33 * allowed executing mostly raw guest code directly the host CPU but without any
34 * support from VT-x or AMD-V. It was implemented for AMD64, AMD-V and VT-x
35 * were available (former) or even specified (latter two). This mode was
36 * removed in 6.1 (code ripped out) as it was mostly unused by that point and
37 * not worth the effort of maintaining.
38 *
39 * A future VirtualBox version may reintroduce a new kind of raw-mode for
40 * emulating non-x86 architectures, making use of the host MMU to efficiently
41 * emulate the target MMU. This is just a wild idea at this point.
42 *
43 *
44 * @section sec_old_rawmode Old Raw-mode
45 *
46 * Running guest code unmodified on the host CPU is reasonably unproblematic for
47 * ring-3 code when it runs without IOPL=3. There will be some information
48 * leaks thru CPUID, a bunch of 286 area unprivileged instructions revealing
49 * privileged information (like SGDT, SIDT, SLDT, STR, SMSW), and hypervisor
50 * selectors can probably be identified using VERR, VERW and such instructions.
51 * However, it generally works fine for half friendly software when the CPUID
52 * difference between the target and host isn't too big.
53 *
54 * Kernel code can be executed on the host CPU too, however it needs to be
55 * pushed up a ring (guest ring-0 to ring-1, guest ring-1 to ring2) to let the
56 * hypervisor (VMMRC.rc) be in charge of ring-0. Ring compression causes
57 * issues when CS or SS are pushed and inspected by the guest, since the values
58 * will have bit 0 set whereas the guest expects that bit to be cleared. In
59 * addition there are problematic instructions like POPF and IRET that the guest
60 * code uses to restore/modify EFLAGS.IF state, however the CPU just silently
61 * ignores EFLAGS.IF when it isn't running in ring-0 (or with an appropriate
62 * IOPL), which causes major headache. The SIDT, SGDT, STR, SLDT and SMSW
63 * instructions also causes problems since they will return information about
64 * the hypervisor rather than the guest state and cannot be trapped.
65 *
66 * So, guest kernel code needed to be scanned (by CSAM) and problematic
67 * instructions or sequences patched or recompiled (by PATM).
68 *
69 * The raw-mode execution operates in a slightly modified guest memory context,
70 * so memory accesses can be done directly without any checking or masking. The
71 * modification was to insert the hypervisor in an unused portion of the the
72 * page tables, making it float around and require it to be relocated when the
73 * guest mapped code into the area it was occupying.
74 *
75 * The old raw-mode code was 32-bit only because its inception predates the
76 * availability of the AMD64 architecture and the promise of AMD-V and VT-x made
77 * it unnecessary to do a 64-bit version of the mode. (A long-mode port of the
78 * raw-mode execution hypvisor could in theory have been used for both 32-bit
79 * and 64-bit guest, making the relocating unnecessary for 32-bit guests,
80 * however v8086 mode does not work when the CPU is operating in long-mode made
81 * it a little less attractive.)
82 *
83 *
84 * @section sec_rawmode_v2 Raw-mode v2
85 *
86 * The vision for the reinvention of raw-mode execution is to put it inside
87 * VT-x/AMD-V and run non-native instruction sets via a recompiler.
88 *
89 * The main motivation is TLB emulation using the host MMU. An added benefit is
90 * would be that the non-native instruction sets would be add-ons put on top of
91 * the existing x86/AMD64 virtualization product and therefore not require a
92 * complete separate product build.
93 *
94 *
95 * Outline:
96 *
97 * - Plug-in based, so the target architecture specific stuff is mostly in
98 * separate modules (ring-3, ring-0 (optional) and raw-mode images).
99 *
100 * - Only 64-bit mode code (no problem since VirtualBox requires a 64-bit host
101 * since 6.0). So, not reintroducing structure alignment pain from old RC.
102 *
103 * - Map the RC-hypervisor modules as ROM, using the shadowing feature for the
104 * data sections.
105 *
106 * - Use MMIO2-like regions for all the memory that the RC-hypervisor needs,
107 * all shared with the associated host side plug-in components.
108 *
109 * - The ROM and MMIO2 regions does not directly end up in the saved state, the
110 * state is instead saved by the ring-3 architecture module.
111 *
112 * - Device access thru MMIO mappings could be done transparently thru to the
113 * x86/AMD64 core VMM. It would however be possible to reintroduce the RC
114 * side device handling, as that will not be removed in the old-RC cleanup.
115 *
116 * - Virtual memory managed by the RC-hypervisor, optionally with help of the
117 * ring-3 and/or ring-0 architecture modules.
118 *
119 * - The mapping of the RC modules and memory will probably have to runtime
120 * relocatable again, like it was in the old RC. Though initially and for
121 * 32-bit target architectures, we will probably use a fixed mapping.
122 *
123 * - Memory accesses must unfortunately be range checked before being issued,
124 * in order to prevent the guest code from accessing the hypervisor. The
125 * recompiled code must be able to run, modify state, call ROM code, update
126 * statistics and such, so we cannot use page table stuff protect the
127 * hypervisor code & data. (If long mode implement segment limits, we
128 * could've used that, but it doesn't.)
129 *
130 * - The RC-hypervisor will make hypercalls to communicate with the ring-0 and
131 * ring-3 host code.
132 *
133 * - The host side should be able to dig out the current guest state from
134 * information (think AMD64 unwinding) stored in translation blocks.
135 *
136 * - Non-atomic state updates outside TBs could be flagged so the host know
137 * how to roll the back.
138 *
139 * - SMP must be taken into account early on.
140 *
141 * - As must existing IEM-based recompiler ideas, preferrably sharing code
142 * (basically compiling IEM targetting the other architecture).
143 *
144 * The actual implementation will depend a lot on which architectures are
145 * targeted and how they can be mapped onto AMD64/x86. It is possible that
146 * there are some significan roadblocks preventing us from using the host MMU
147 * efficiently even. AMD64 is for instance rather low on virtual address space
148 * compared to several other 64-bit architectures, which means we'll generate a
149 * lot of \#GPs when the guest tries to access spaced reserved on AMD64. The
150 * proposed 5-level page tables will help with this, of course, but that need to
151 * get into silicon and into user computers for it to be really helpful.
152 *
153 * One thing that helps a lot is that we don't have to consider 32-bit x86 any
154 * more, meaning that the recompiler only need to generate 64-bit code and can
155 * assume having 15-16 GPRs at its disposal.
156 *
157 */
158
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