1 
2 /*---------------------------------------------------------------*/
3 /*--- begin                                libvex_guest_arm.h ---*/
4 /*---------------------------------------------------------------*/
5 
6 /*
7    This file is part of Valgrind, a dynamic binary instrumentation
8    framework.
9 
10    Copyright (C) 2004-2013 OpenWorks LLP
11       info@open-works.net
12 
13    This program is free software; you can redistribute it and/or
14    modify it under the terms of the GNU General Public License as
15    published by the Free Software Foundation; either version 2 of the
16    License, or (at your option) any later version.
17 
18    This program is distributed in the hope that it will be useful, but
19    WITHOUT ANY WARRANTY; without even the implied warranty of
20    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
21    General Public License for more details.
22 
23    You should have received a copy of the GNU General Public License
24    along with this program; if not, write to the Free Software
25    Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
26    02110-1301, USA.
27 
28    The GNU General Public License is contained in the file COPYING.
29 */
30 
31 #ifndef __LIBVEX_PUB_GUEST_ARM_H
32 #define __LIBVEX_PUB_GUEST_ARM_H
33 
34 #include "libvex_basictypes.h"
35 
36 
37 /*---------------------------------------------------------------*/
38 /*--- Vex's representation of the ARM CPU state.              ---*/
39 /*---------------------------------------------------------------*/
40 
41 typedef
42    struct {
43       /* 0 */
44       /* Event check fail addr and counter. */
45       UInt host_EvC_FAILADDR; /* 0 */
46       UInt host_EvC_COUNTER;  /* 4 */
47       UInt guest_R0;
48       UInt guest_R1;
49       UInt guest_R2;
50       UInt guest_R3;
51       UInt guest_R4;
52       UInt guest_R5;
53       UInt guest_R6;
54       UInt guest_R7;
55       UInt guest_R8;
56       UInt guest_R9;
57       UInt guest_R10;
58       UInt guest_R11;
59       UInt guest_R12;
60       UInt guest_R13;     /* stack pointer */
61       UInt guest_R14;     /* link register */
62       UInt guest_R15T;
63       /* program counter[31:1] ++ [T], encoding both the current
64          instruction address and the ARM vs Thumb state of the
65          machine.  T==1 is Thumb, T==0 is ARM.  Hence values of the
66          form X--(31)--X1 denote a Thumb instruction at location
67          X--(31)--X0, values of the form X--(30)--X00 denote an ARM
68          instruction at precisely that address, and values of the form
69          X--(30)--10 are invalid since they would imply an ARM
70          instruction at a non-4-aligned address. */
71 
72       /* 4-word thunk used to calculate N(sign) Z(zero) C(carry,
73          unsigned overflow) and V(signed overflow) flags. */
74       /* 72 */
75       UInt guest_CC_OP;
76       UInt guest_CC_DEP1;
77       UInt guest_CC_DEP2;
78       UInt guest_CC_NDEP;
79 
80       /* A 32-bit value which is used to compute the APSR.Q (sticky
81          saturation) flag, when necessary.  If the value stored here
82          is zero, APSR.Q is currently zero.  If it is any other value,
83          APSR.Q is currently one. */
84       UInt guest_QFLAG32;
85 
86       /* 32-bit values to represent APSR.GE0 .. GE3.  Same
87          zero-vs-nonzero scheme as for QFLAG32. */
88       UInt guest_GEFLAG0;
89       UInt guest_GEFLAG1;
90       UInt guest_GEFLAG2;
91       UInt guest_GEFLAG3;
92 
93       /* Various pseudo-regs mandated by Vex or Valgrind. */
94       /* Emulation notes */
95       UInt guest_EMNOTE;
96 
97       /* For clinval/clflush: record start and length of area */
98       UInt guest_CMSTART;
99       UInt guest_CMLEN;
100 
101       /* Used to record the unredirected guest address at the start of
102          a translation whose start has been redirected.  By reading
103          this pseudo-register shortly afterwards, the translation can
104          find out what the corresponding no-redirection address was.
105          Note, this is only set for wrap-style redirects, not for
106          replace-style ones. */
107       UInt guest_NRADDR;
108 
109       /* Needed for Darwin (but mandated for all guest architectures):
110          program counter at the last syscall insn (int 0x80/81/82,
111          sysenter, syscall, svc).  Used when backing up to restart a
112          syscall that has been interrupted by a signal. */
113       /* 124 */
114       UInt guest_IP_AT_SYSCALL;
115 
116       /* VFP state.  D0 .. D15 must be 8-aligned. */
117       /* 128 */
118       ULong guest_D0;
119       ULong guest_D1;
120       ULong guest_D2;
121       ULong guest_D3;
122       ULong guest_D4;
123       ULong guest_D5;
124       ULong guest_D6;
125       ULong guest_D7;
126       ULong guest_D8;
127       ULong guest_D9;
128       ULong guest_D10;
129       ULong guest_D11;
130       ULong guest_D12;
131       ULong guest_D13;
132       ULong guest_D14;
133       ULong guest_D15;
134       ULong guest_D16;
135       ULong guest_D17;
136       ULong guest_D18;
137       ULong guest_D19;
138       ULong guest_D20;
139       ULong guest_D21;
140       ULong guest_D22;
141       ULong guest_D23;
142       ULong guest_D24;
143       ULong guest_D25;
144       ULong guest_D26;
145       ULong guest_D27;
146       ULong guest_D28;
147       ULong guest_D29;
148       ULong guest_D30;
149       ULong guest_D31;
150       UInt  guest_FPSCR;
151 
152       /* Not a town in Cornwall, but instead the TPIDRURO, on of the
153          Thread ID registers present in CP15 (the system control
154          coprocessor), register set "c13", register 3 (the User
155          Read-only Thread ID Register).  arm-linux apparently uses it
156          to hold the TLS pointer for the thread.  It's read-only in
157          user space.  On Linux it is set in user space by various
158          thread-related syscalls. */
159       UInt guest_TPIDRURO;
160 
161       /* Representation of the Thumb IT state.  ITSTATE is a 32-bit
162          value with 4 8-bit lanes.  [7:0] pertain to the next insn to
163          execute, [15:8] for the one after that, etc.  The per-insn
164          update to ITSTATE is to unsignedly shift it right 8 bits,
165          hence introducing a zero byte for the furthest ahead
166          instruction.  As per the next para, a zero byte denotes the
167          condition ALWAYS.
168 
169          Each byte lane has one of the two following formats:
170 
171          cccc 0001  for an insn which is part of an IT block.  cccc is
172                     the guarding condition (standard ARM condition
173                     code) XORd with 0xE, so as to cause 'cccc == 0'
174                     to encode the condition ALWAYS.
175 
176          0000 0000  for an insn which is not part of an IT block.
177 
178          If the bottom 4 bits are zero then the top 4 must be too.
179 
180          Given the byte lane for an instruction, the guarding
181          condition for the instruction is (((lane >> 4) & 0xF) ^ 0xE).
182          This is not as stupid as it sounds, because the front end
183          elides the shift.  And the am-I-in-an-IT-block check is
184          (lane != 0).
185 
186          In the case where (by whatever means) we know at JIT time
187          that an instruction is not in an IT block, we can prefix its
188          IR with assignments ITSTATE = 0 and hence have iropt fold out
189          the testing code.
190 
191          The condition "is outside or last in IT block" corresponds
192          to the top 24 bits of ITSTATE being zero.
193       */
194       UInt guest_ITSTATE;
195 
196       /* Padding to make it have an 16-aligned size */
197       UInt padding1;
198    }
199    VexGuestARMState;
200 
201 
202 /*---------------------------------------------------------------*/
203 /*--- Utility functions for ARM guest stuff.                  ---*/
204 /*---------------------------------------------------------------*/
205 
206 /* ALL THE FOLLOWING ARE VISIBLE TO LIBRARY CLIENT */
207 
208 /* Initialise all guest ARM state. */
209 
210 extern
211 void LibVEX_GuestARM_initialise ( /*OUT*/VexGuestARMState* vex_state );
212 
213 /* Calculate the ARM flag state from the saved data. */
214 
215 extern
216 UInt LibVEX_GuestARM_get_cpsr ( /*IN*/const VexGuestARMState* vex_state );
217 
218 
219 #endif /* ndef __LIBVEX_PUB_GUEST_ARM_H */
220 
221 
222 /*---------------------------------------------------------------*/
223 /*---                                      libvex_guest_arm.h ---*/
224 /*---------------------------------------------------------------*/
225