diff options
author | Mikael Starvik <mikael.starvik@axis.com> | 2005-07-27 14:44:44 -0400 |
---|---|---|
committer | Linus Torvalds <torvalds@g5.osdl.org> | 2005-07-27 19:26:01 -0400 |
commit | 51533b615e605d86154ec1b4e585c8ca1b0b15b7 (patch) | |
tree | 4a6d7d8494d2017632d83624fb71b36031e0e7e5 /arch/cris/arch-v32/kernel/kgdb.c | |
parent | 5d01e6ce785884a5db5792cd2e5bb36fa82fe23c (diff) |
[PATCH] CRIS update: new subarchitecture v32
New CRIS sub architecture named v32.
From: Dave Jones <davej@redhat.com>
Fix swapped kmalloc args
Signed-off-by: Mikael Starvik <starvik@axis.com>
Signed-off-by: Dave Jones <davej@redhat.com>
Signed-off-by: Andrew Morton <akpm@osdl.org>
Signed-off-by: Linus Torvalds <torvalds@osdl.org>
Diffstat (limited to 'arch/cris/arch-v32/kernel/kgdb.c')
-rw-r--r-- | arch/cris/arch-v32/kernel/kgdb.c | 1660 |
1 files changed, 1660 insertions, 0 deletions
diff --git a/arch/cris/arch-v32/kernel/kgdb.c b/arch/cris/arch-v32/kernel/kgdb.c new file mode 100644 index 000000000000..480e56348be2 --- /dev/null +++ b/arch/cris/arch-v32/kernel/kgdb.c | |||
@@ -0,0 +1,1660 @@ | |||
1 | /* | ||
2 | * arch/cris/arch-v32/kernel/kgdb.c | ||
3 | * | ||
4 | * CRIS v32 version by Orjan Friberg, Axis Communications AB. | ||
5 | * | ||
6 | * S390 version | ||
7 | * Copyright (C) 1999 IBM Deutschland Entwicklung GmbH, IBM Corporation | ||
8 | * Author(s): Denis Joseph Barrow (djbarrow@de.ibm.com,barrow_dj@yahoo.com), | ||
9 | * | ||
10 | * Originally written by Glenn Engel, Lake Stevens Instrument Division | ||
11 | * | ||
12 | * Contributed by HP Systems | ||
13 | * | ||
14 | * Modified for SPARC by Stu Grossman, Cygnus Support. | ||
15 | * | ||
16 | * Modified for Linux/MIPS (and MIPS in general) by Andreas Busse | ||
17 | * Send complaints, suggestions etc. to <andy@waldorf-gmbh.de> | ||
18 | * | ||
19 | * Copyright (C) 1995 Andreas Busse | ||
20 | */ | ||
21 | |||
22 | /* FIXME: Check the documentation. */ | ||
23 | |||
24 | /* | ||
25 | * kgdb usage notes: | ||
26 | * ----------------- | ||
27 | * | ||
28 | * If you select CONFIG_ETRAX_KGDB in the configuration, the kernel will be | ||
29 | * built with different gcc flags: "-g" is added to get debug infos, and | ||
30 | * "-fomit-frame-pointer" is omitted to make debugging easier. Since the | ||
31 | * resulting kernel will be quite big (approx. > 7 MB), it will be stripped | ||
32 | * before compresion. Such a kernel will behave just as usually, except if | ||
33 | * given a "debug=<device>" command line option. (Only serial devices are | ||
34 | * allowed for <device>, i.e. no printers or the like; possible values are | ||
35 | * machine depedend and are the same as for the usual debug device, the one | ||
36 | * for logging kernel messages.) If that option is given and the device can be | ||
37 | * initialized, the kernel will connect to the remote gdb in trap_init(). The | ||
38 | * serial parameters are fixed to 8N1 and 115200 bps, for easyness of | ||
39 | * implementation. | ||
40 | * | ||
41 | * To start a debugging session, start that gdb with the debugging kernel | ||
42 | * image (the one with the symbols, vmlinux.debug) named on the command line. | ||
43 | * This file will be used by gdb to get symbol and debugging infos about the | ||
44 | * kernel. Next, select remote debug mode by | ||
45 | * target remote <device> | ||
46 | * where <device> is the name of the serial device over which the debugged | ||
47 | * machine is connected. Maybe you have to adjust the baud rate by | ||
48 | * set remotebaud <rate> | ||
49 | * or also other parameters with stty: | ||
50 | * shell stty ... </dev/... | ||
51 | * If the kernel to debug has already booted, it waited for gdb and now | ||
52 | * connects, and you'll see a breakpoint being reported. If the kernel isn't | ||
53 | * running yet, start it now. The order of gdb and the kernel doesn't matter. | ||
54 | * Another thing worth knowing about in the getting-started phase is how to | ||
55 | * debug the remote protocol itself. This is activated with | ||
56 | * set remotedebug 1 | ||
57 | * gdb will then print out each packet sent or received. You'll also get some | ||
58 | * messages about the gdb stub on the console of the debugged machine. | ||
59 | * | ||
60 | * If all that works, you can use lots of the usual debugging techniques on | ||
61 | * the kernel, e.g. inspecting and changing variables/memory, setting | ||
62 | * breakpoints, single stepping and so on. It's also possible to interrupt the | ||
63 | * debugged kernel by pressing C-c in gdb. Have fun! :-) | ||
64 | * | ||
65 | * The gdb stub is entered (and thus the remote gdb gets control) in the | ||
66 | * following situations: | ||
67 | * | ||
68 | * - If breakpoint() is called. This is just after kgdb initialization, or if | ||
69 | * a breakpoint() call has been put somewhere into the kernel source. | ||
70 | * (Breakpoints can of course also be set the usual way in gdb.) | ||
71 | * In eLinux, we call breakpoint() in init/main.c after IRQ initialization. | ||
72 | * | ||
73 | * - If there is a kernel exception, i.e. bad_super_trap() or die_if_kernel() | ||
74 | * are entered. All the CPU exceptions are mapped to (more or less..., see | ||
75 | * the hard_trap_info array below) appropriate signal, which are reported | ||
76 | * to gdb. die_if_kernel() is usually called after some kind of access | ||
77 | * error and thus is reported as SIGSEGV. | ||
78 | * | ||
79 | * - When panic() is called. This is reported as SIGABRT. | ||
80 | * | ||
81 | * - If C-c is received over the serial line, which is treated as | ||
82 | * SIGINT. | ||
83 | * | ||
84 | * Of course, all these signals are just faked for gdb, since there is no | ||
85 | * signal concept as such for the kernel. It also isn't possible --obviously-- | ||
86 | * to set signal handlers from inside gdb, or restart the kernel with a | ||
87 | * signal. | ||
88 | * | ||
89 | * Current limitations: | ||
90 | * | ||
91 | * - While the kernel is stopped, interrupts are disabled for safety reasons | ||
92 | * (i.e., variables not changing magically or the like). But this also | ||
93 | * means that the clock isn't running anymore, and that interrupts from the | ||
94 | * hardware may get lost/not be served in time. This can cause some device | ||
95 | * errors... | ||
96 | * | ||
97 | * - When single-stepping, only one instruction of the current thread is | ||
98 | * executed, but interrupts are allowed for that time and will be serviced | ||
99 | * if pending. Be prepared for that. | ||
100 | * | ||
101 | * - All debugging happens in kernel virtual address space. There's no way to | ||
102 | * access physical memory not mapped in kernel space, or to access user | ||
103 | * space. A way to work around this is using get_user_long & Co. in gdb | ||
104 | * expressions, but only for the current process. | ||
105 | * | ||
106 | * - Interrupting the kernel only works if interrupts are currently allowed, | ||
107 | * and the interrupt of the serial line isn't blocked by some other means | ||
108 | * (IPL too high, disabled, ...) | ||
109 | * | ||
110 | * - The gdb stub is currently not reentrant, i.e. errors that happen therein | ||
111 | * (e.g. accessing invalid memory) may not be caught correctly. This could | ||
112 | * be removed in future by introducing a stack of struct registers. | ||
113 | * | ||
114 | */ | ||
115 | |||
116 | /* | ||
117 | * To enable debugger support, two things need to happen. One, a | ||
118 | * call to kgdb_init() is necessary in order to allow any breakpoints | ||
119 | * or error conditions to be properly intercepted and reported to gdb. | ||
120 | * Two, a breakpoint needs to be generated to begin communication. This | ||
121 | * is most easily accomplished by a call to breakpoint(). | ||
122 | * | ||
123 | * The following gdb commands are supported: | ||
124 | * | ||
125 | * command function Return value | ||
126 | * | ||
127 | * g return the value of the CPU registers hex data or ENN | ||
128 | * G set the value of the CPU registers OK or ENN | ||
129 | * | ||
130 | * mAA..AA,LLLL Read LLLL bytes at address AA..AA hex data or ENN | ||
131 | * MAA..AA,LLLL: Write LLLL bytes at address AA.AA OK or ENN | ||
132 | * | ||
133 | * c Resume at current address SNN ( signal NN) | ||
134 | * cAA..AA Continue at address AA..AA SNN | ||
135 | * | ||
136 | * s Step one instruction SNN | ||
137 | * sAA..AA Step one instruction from AA..AA SNN | ||
138 | * | ||
139 | * k kill | ||
140 | * | ||
141 | * ? What was the last sigval ? SNN (signal NN) | ||
142 | * | ||
143 | * bBB..BB Set baud rate to BB..BB OK or BNN, then sets | ||
144 | * baud rate | ||
145 | * | ||
146 | * All commands and responses are sent with a packet which includes a | ||
147 | * checksum. A packet consists of | ||
148 | * | ||
149 | * $<packet info>#<checksum>. | ||
150 | * | ||
151 | * where | ||
152 | * <packet info> :: <characters representing the command or response> | ||
153 | * <checksum> :: < two hex digits computed as modulo 256 sum of <packetinfo>> | ||
154 | * | ||
155 | * When a packet is received, it is first acknowledged with either '+' or '-'. | ||
156 | * '+' indicates a successful transfer. '-' indicates a failed transfer. | ||
157 | * | ||
158 | * Example: | ||
159 | * | ||
160 | * Host: Reply: | ||
161 | * $m0,10#2a +$00010203040506070809101112131415#42 | ||
162 | * | ||
163 | */ | ||
164 | |||
165 | |||
166 | #include <linux/string.h> | ||
167 | #include <linux/signal.h> | ||
168 | #include <linux/kernel.h> | ||
169 | #include <linux/delay.h> | ||
170 | #include <linux/linkage.h> | ||
171 | #include <linux/reboot.h> | ||
172 | |||
173 | #include <asm/setup.h> | ||
174 | #include <asm/ptrace.h> | ||
175 | |||
176 | #include <asm/irq.h> | ||
177 | #include <asm/arch/hwregs/reg_map.h> | ||
178 | #include <asm/arch/hwregs/reg_rdwr.h> | ||
179 | #include <asm/arch/hwregs/intr_vect_defs.h> | ||
180 | #include <asm/arch/hwregs/ser_defs.h> | ||
181 | |||
182 | /* From entry.S. */ | ||
183 | extern void gdb_handle_exception(void); | ||
184 | /* From kgdb_asm.S. */ | ||
185 | extern void kgdb_handle_exception(void); | ||
186 | |||
187 | static int kgdb_started = 0; | ||
188 | |||
189 | /********************************* Register image ****************************/ | ||
190 | |||
191 | typedef | ||
192 | struct register_image | ||
193 | { | ||
194 | /* Offset */ | ||
195 | unsigned int r0; /* 0x00 */ | ||
196 | unsigned int r1; /* 0x04 */ | ||
197 | unsigned int r2; /* 0x08 */ | ||
198 | unsigned int r3; /* 0x0C */ | ||
199 | unsigned int r4; /* 0x10 */ | ||
200 | unsigned int r5; /* 0x14 */ | ||
201 | unsigned int r6; /* 0x18 */ | ||
202 | unsigned int r7; /* 0x1C */ | ||
203 | unsigned int r8; /* 0x20; Frame pointer (if any) */ | ||
204 | unsigned int r9; /* 0x24 */ | ||
205 | unsigned int r10; /* 0x28 */ | ||
206 | unsigned int r11; /* 0x2C */ | ||
207 | unsigned int r12; /* 0x30 */ | ||
208 | unsigned int r13; /* 0x34 */ | ||
209 | unsigned int sp; /* 0x38; R14, Stack pointer */ | ||
210 | unsigned int acr; /* 0x3C; R15, Address calculation register. */ | ||
211 | |||
212 | unsigned char bz; /* 0x40; P0, 8-bit zero register */ | ||
213 | unsigned char vr; /* 0x41; P1, Version register (8-bit) */ | ||
214 | unsigned int pid; /* 0x42; P2, Process ID */ | ||
215 | unsigned char srs; /* 0x46; P3, Support register select (8-bit) */ | ||
216 | unsigned short wz; /* 0x47; P4, 16-bit zero register */ | ||
217 | unsigned int exs; /* 0x49; P5, Exception status */ | ||
218 | unsigned int eda; /* 0x4D; P6, Exception data address */ | ||
219 | unsigned int mof; /* 0x51; P7, Multiply overflow register */ | ||
220 | unsigned int dz; /* 0x55; P8, 32-bit zero register */ | ||
221 | unsigned int ebp; /* 0x59; P9, Exception base pointer */ | ||
222 | unsigned int erp; /* 0x5D; P10, Exception return pointer. Contains the PC we are interested in. */ | ||
223 | unsigned int srp; /* 0x61; P11, Subroutine return pointer */ | ||
224 | unsigned int nrp; /* 0x65; P12, NMI return pointer */ | ||
225 | unsigned int ccs; /* 0x69; P13, Condition code stack */ | ||
226 | unsigned int usp; /* 0x6D; P14, User mode stack pointer */ | ||
227 | unsigned int spc; /* 0x71; P15, Single step PC */ | ||
228 | unsigned int pc; /* 0x75; Pseudo register (for the most part set to ERP). */ | ||
229 | |||
230 | } registers; | ||
231 | |||
232 | typedef | ||
233 | struct bp_register_image | ||
234 | { | ||
235 | /* Support register bank 0. */ | ||
236 | unsigned int s0_0; | ||
237 | unsigned int s1_0; | ||
238 | unsigned int s2_0; | ||
239 | unsigned int s3_0; | ||
240 | unsigned int s4_0; | ||
241 | unsigned int s5_0; | ||
242 | unsigned int s6_0; | ||
243 | unsigned int s7_0; | ||
244 | unsigned int s8_0; | ||
245 | unsigned int s9_0; | ||
246 | unsigned int s10_0; | ||
247 | unsigned int s11_0; | ||
248 | unsigned int s12_0; | ||
249 | unsigned int s13_0; | ||
250 | unsigned int s14_0; | ||
251 | unsigned int s15_0; | ||
252 | |||
253 | /* Support register bank 1. */ | ||
254 | unsigned int s0_1; | ||
255 | unsigned int s1_1; | ||
256 | unsigned int s2_1; | ||
257 | unsigned int s3_1; | ||
258 | unsigned int s4_1; | ||
259 | unsigned int s5_1; | ||
260 | unsigned int s6_1; | ||
261 | unsigned int s7_1; | ||
262 | unsigned int s8_1; | ||
263 | unsigned int s9_1; | ||
264 | unsigned int s10_1; | ||
265 | unsigned int s11_1; | ||
266 | unsigned int s12_1; | ||
267 | unsigned int s13_1; | ||
268 | unsigned int s14_1; | ||
269 | unsigned int s15_1; | ||
270 | |||
271 | /* Support register bank 2. */ | ||
272 | unsigned int s0_2; | ||
273 | unsigned int s1_2; | ||
274 | unsigned int s2_2; | ||
275 | unsigned int s3_2; | ||
276 | unsigned int s4_2; | ||
277 | unsigned int s5_2; | ||
278 | unsigned int s6_2; | ||
279 | unsigned int s7_2; | ||
280 | unsigned int s8_2; | ||
281 | unsigned int s9_2; | ||
282 | unsigned int s10_2; | ||
283 | unsigned int s11_2; | ||
284 | unsigned int s12_2; | ||
285 | unsigned int s13_2; | ||
286 | unsigned int s14_2; | ||
287 | unsigned int s15_2; | ||
288 | |||
289 | /* Support register bank 3. */ | ||
290 | unsigned int s0_3; /* BP_CTRL */ | ||
291 | unsigned int s1_3; /* BP_I0_START */ | ||
292 | unsigned int s2_3; /* BP_I0_END */ | ||
293 | unsigned int s3_3; /* BP_D0_START */ | ||
294 | unsigned int s4_3; /* BP_D0_END */ | ||
295 | unsigned int s5_3; /* BP_D1_START */ | ||
296 | unsigned int s6_3; /* BP_D1_END */ | ||
297 | unsigned int s7_3; /* BP_D2_START */ | ||
298 | unsigned int s8_3; /* BP_D2_END */ | ||
299 | unsigned int s9_3; /* BP_D3_START */ | ||
300 | unsigned int s10_3; /* BP_D3_END */ | ||
301 | unsigned int s11_3; /* BP_D4_START */ | ||
302 | unsigned int s12_3; /* BP_D4_END */ | ||
303 | unsigned int s13_3; /* BP_D5_START */ | ||
304 | unsigned int s14_3; /* BP_D5_END */ | ||
305 | unsigned int s15_3; /* BP_RESERVED */ | ||
306 | |||
307 | } support_registers; | ||
308 | |||
309 | enum register_name | ||
310 | { | ||
311 | R0, R1, R2, R3, | ||
312 | R4, R5, R6, R7, | ||
313 | R8, R9, R10, R11, | ||
314 | R12, R13, SP, ACR, | ||
315 | |||
316 | BZ, VR, PID, SRS, | ||
317 | WZ, EXS, EDA, MOF, | ||
318 | DZ, EBP, ERP, SRP, | ||
319 | NRP, CCS, USP, SPC, | ||
320 | PC, | ||
321 | |||
322 | S0, S1, S2, S3, | ||
323 | S4, S5, S6, S7, | ||
324 | S8, S9, S10, S11, | ||
325 | S12, S13, S14, S15 | ||
326 | |||
327 | }; | ||
328 | |||
329 | /* The register sizes of the registers in register_name. An unimplemented register | ||
330 | is designated by size 0 in this array. */ | ||
331 | static int register_size[] = | ||
332 | { | ||
333 | 4, 4, 4, 4, | ||
334 | 4, 4, 4, 4, | ||
335 | 4, 4, 4, 4, | ||
336 | 4, 4, 4, 4, | ||
337 | |||
338 | 1, 1, 4, 1, | ||
339 | 2, 4, 4, 4, | ||
340 | 4, 4, 4, 4, | ||
341 | 4, 4, 4, 4, | ||
342 | |||
343 | 4, | ||
344 | |||
345 | 4, 4, 4, 4, | ||
346 | 4, 4, 4, 4, | ||
347 | 4, 4, 4, 4, | ||
348 | 4, 4, 4 | ||
349 | |||
350 | }; | ||
351 | |||
352 | /* Contains the register image of the kernel. | ||
353 | (Global so that they can be reached from assembler code.) */ | ||
354 | registers reg; | ||
355 | support_registers sreg; | ||
356 | |||
357 | /************** Prototypes for local library functions ***********************/ | ||
358 | |||
359 | /* Copy of strcpy from libc. */ | ||
360 | static char *gdb_cris_strcpy(char *s1, const char *s2); | ||
361 | |||
362 | /* Copy of strlen from libc. */ | ||
363 | static int gdb_cris_strlen(const char *s); | ||
364 | |||
365 | /* Copy of memchr from libc. */ | ||
366 | static void *gdb_cris_memchr(const void *s, int c, int n); | ||
367 | |||
368 | /* Copy of strtol from libc. Does only support base 16. */ | ||
369 | static int gdb_cris_strtol(const char *s, char **endptr, int base); | ||
370 | |||
371 | /********************** Prototypes for local functions. **********************/ | ||
372 | |||
373 | /* Write a value to a specified register regno in the register image | ||
374 | of the current thread. */ | ||
375 | static int write_register(int regno, char *val); | ||
376 | |||
377 | /* Read a value from a specified register in the register image. Returns the | ||
378 | status of the read operation. The register value is returned in valptr. */ | ||
379 | static int read_register(char regno, unsigned int *valptr); | ||
380 | |||
381 | /* Serial port, reads one character. ETRAX 100 specific. from debugport.c */ | ||
382 | int getDebugChar(void); | ||
383 | |||
384 | #ifdef CONFIG_ETRAXFS_SIM | ||
385 | int getDebugChar(void) | ||
386 | { | ||
387 | return socketread(); | ||
388 | } | ||
389 | #endif | ||
390 | |||
391 | /* Serial port, writes one character. ETRAX 100 specific. from debugport.c */ | ||
392 | void putDebugChar(int val); | ||
393 | |||
394 | #ifdef CONFIG_ETRAXFS_SIM | ||
395 | void putDebugChar(int val) | ||
396 | { | ||
397 | socketwrite((char *)&val, 1); | ||
398 | } | ||
399 | #endif | ||
400 | |||
401 | /* Returns the character equivalent of a nibble, bit 7, 6, 5, and 4 of a byte, | ||
402 | represented by int x. */ | ||
403 | static char highhex(int x); | ||
404 | |||
405 | /* Returns the character equivalent of a nibble, bit 3, 2, 1, and 0 of a byte, | ||
406 | represented by int x. */ | ||
407 | static char lowhex(int x); | ||
408 | |||
409 | /* Returns the integer equivalent of a hexadecimal character. */ | ||
410 | static int hex(char ch); | ||
411 | |||
412 | /* Convert the memory, pointed to by mem into hexadecimal representation. | ||
413 | Put the result in buf, and return a pointer to the last character | ||
414 | in buf (null). */ | ||
415 | static char *mem2hex(char *buf, unsigned char *mem, int count); | ||
416 | |||
417 | /* Convert the array, in hexadecimal representation, pointed to by buf into | ||
418 | binary representation. Put the result in mem, and return a pointer to | ||
419 | the character after the last byte written. */ | ||
420 | static unsigned char *hex2mem(unsigned char *mem, char *buf, int count); | ||
421 | |||
422 | /* Put the content of the array, in binary representation, pointed to by buf | ||
423 | into memory pointed to by mem, and return a pointer to | ||
424 | the character after the last byte written. */ | ||
425 | static unsigned char *bin2mem(unsigned char *mem, unsigned char *buf, int count); | ||
426 | |||
427 | /* Await the sequence $<data>#<checksum> and store <data> in the array buffer | ||
428 | returned. */ | ||
429 | static void getpacket(char *buffer); | ||
430 | |||
431 | /* Send $<data>#<checksum> from the <data> in the array buffer. */ | ||
432 | static void putpacket(char *buffer); | ||
433 | |||
434 | /* Build and send a response packet in order to inform the host the | ||
435 | stub is stopped. */ | ||
436 | static void stub_is_stopped(int sigval); | ||
437 | |||
438 | /* All expected commands are sent from remote.c. Send a response according | ||
439 | to the description in remote.c. Not static since it needs to be reached | ||
440 | from assembler code. */ | ||
441 | void handle_exception(int sigval); | ||
442 | |||
443 | /* Performs a complete re-start from scratch. ETRAX specific. */ | ||
444 | static void kill_restart(void); | ||
445 | |||
446 | /******************** Prototypes for global functions. ***********************/ | ||
447 | |||
448 | /* The string str is prepended with the GDB printout token and sent. */ | ||
449 | void putDebugString(const unsigned char *str, int len); | ||
450 | |||
451 | /* A static breakpoint to be used at startup. */ | ||
452 | void breakpoint(void); | ||
453 | |||
454 | /* Avoid warning as the internal_stack is not used in the C-code. */ | ||
455 | #define USEDVAR(name) { if (name) { ; } } | ||
456 | #define USEDFUN(name) { void (*pf)(void) = (void *)name; USEDVAR(pf) } | ||
457 | |||
458 | /********************************** Packet I/O ******************************/ | ||
459 | /* BUFMAX defines the maximum number of characters in | ||
460 | inbound/outbound buffers */ | ||
461 | /* FIXME: How do we know it's enough? */ | ||
462 | #define BUFMAX 512 | ||
463 | |||
464 | /* Run-length encoding maximum length. Send 64 at most. */ | ||
465 | #define RUNLENMAX 64 | ||
466 | |||
467 | /* Definition of all valid hexadecimal characters */ | ||
468 | static const char hexchars[] = "0123456789abcdef"; | ||
469 | |||
470 | /* The inbound/outbound buffers used in packet I/O */ | ||
471 | static char input_buffer[BUFMAX]; | ||
472 | static char output_buffer[BUFMAX]; | ||
473 | |||
474 | /* Error and warning messages. */ | ||
475 | enum error_type | ||
476 | { | ||
477 | SUCCESS, E01, E02, E03, E04, E05, E06, | ||
478 | }; | ||
479 | |||
480 | static char *error_message[] = | ||
481 | { | ||
482 | "", | ||
483 | "E01 Set current or general thread - H[c,g] - internal error.", | ||
484 | "E02 Change register content - P - cannot change read-only register.", | ||
485 | "E03 Thread is not alive.", /* T, not used. */ | ||
486 | "E04 The command is not supported - [s,C,S,!,R,d,r] - internal error.", | ||
487 | "E05 Change register content - P - the register is not implemented..", | ||
488 | "E06 Change memory content - M - internal error.", | ||
489 | }; | ||
490 | |||
491 | /********************************** Breakpoint *******************************/ | ||
492 | /* Use an internal stack in the breakpoint and interrupt response routines. | ||
493 | FIXME: How do we know the size of this stack is enough? | ||
494 | Global so it can be reached from assembler code. */ | ||
495 | #define INTERNAL_STACK_SIZE 1024 | ||
496 | char internal_stack[INTERNAL_STACK_SIZE]; | ||
497 | |||
498 | /* Due to the breakpoint return pointer, a state variable is needed to keep | ||
499 | track of whether it is a static (compiled) or dynamic (gdb-invoked) | ||
500 | breakpoint to be handled. A static breakpoint uses the content of register | ||
501 | ERP as it is whereas a dynamic breakpoint requires subtraction with 2 | ||
502 | in order to execute the instruction. The first breakpoint is static; all | ||
503 | following are assumed to be dynamic. */ | ||
504 | static int dynamic_bp = 0; | ||
505 | |||
506 | /********************************* String library ****************************/ | ||
507 | /* Single-step over library functions creates trap loops. */ | ||
508 | |||
509 | /* Copy char s2[] to s1[]. */ | ||
510 | static char* | ||
511 | gdb_cris_strcpy(char *s1, const char *s2) | ||
512 | { | ||
513 | char *s = s1; | ||
514 | |||
515 | for (s = s1; (*s++ = *s2++) != '\0'; ) | ||
516 | ; | ||
517 | return s1; | ||
518 | } | ||
519 | |||
520 | /* Find length of s[]. */ | ||
521 | static int | ||
522 | gdb_cris_strlen(const char *s) | ||
523 | { | ||
524 | const char *sc; | ||
525 | |||
526 | for (sc = s; *sc != '\0'; sc++) | ||
527 | ; | ||
528 | return (sc - s); | ||
529 | } | ||
530 | |||
531 | /* Find first occurrence of c in s[n]. */ | ||
532 | static void* | ||
533 | gdb_cris_memchr(const void *s, int c, int n) | ||
534 | { | ||
535 | const unsigned char uc = c; | ||
536 | const unsigned char *su; | ||
537 | |||
538 | for (su = s; 0 < n; ++su, --n) | ||
539 | if (*su == uc) | ||
540 | return (void *)su; | ||
541 | return NULL; | ||
542 | } | ||
543 | /******************************* Standard library ****************************/ | ||
544 | /* Single-step over library functions creates trap loops. */ | ||
545 | /* Convert string to long. */ | ||
546 | static int | ||
547 | gdb_cris_strtol(const char *s, char **endptr, int base) | ||
548 | { | ||
549 | char *s1; | ||
550 | char *sd; | ||
551 | int x = 0; | ||
552 | |||
553 | for (s1 = (char*)s; (sd = gdb_cris_memchr(hexchars, *s1, base)) != NULL; ++s1) | ||
554 | x = x * base + (sd - hexchars); | ||
555 | |||
556 | if (endptr) { | ||
557 | /* Unconverted suffix is stored in endptr unless endptr is NULL. */ | ||
558 | *endptr = s1; | ||
559 | } | ||
560 | |||
561 | return x; | ||
562 | } | ||
563 | |||
564 | /********************************* Register image ****************************/ | ||
565 | |||
566 | /* Write a value to a specified register in the register image of the current | ||
567 | thread. Returns status code SUCCESS, E02 or E05. */ | ||
568 | static int | ||
569 | write_register(int regno, char *val) | ||
570 | { | ||
571 | int status = SUCCESS; | ||
572 | |||
573 | if (regno >= R0 && regno <= ACR) { | ||
574 | /* Consecutive 32-bit registers. */ | ||
575 | hex2mem((unsigned char *)®.r0 + (regno - R0) * sizeof(unsigned int), | ||
576 | val, sizeof(unsigned int)); | ||
577 | |||
578 | } else if (regno == BZ || regno == VR || regno == WZ || regno == DZ) { | ||
579 | /* Read-only registers. */ | ||
580 | status = E02; | ||
581 | |||
582 | } else if (regno == PID) { | ||
583 | /* 32-bit register. (Even though we already checked SRS and WZ, we cannot | ||
584 | combine this with the EXS - SPC write since SRS and WZ have different size.) */ | ||
585 | hex2mem((unsigned char *)®.pid, val, sizeof(unsigned int)); | ||
586 | |||
587 | } else if (regno == SRS) { | ||
588 | /* 8-bit register. */ | ||
589 | hex2mem((unsigned char *)®.srs, val, sizeof(unsigned char)); | ||
590 | |||
591 | } else if (regno >= EXS && regno <= SPC) { | ||
592 | /* Consecutive 32-bit registers. */ | ||
593 | hex2mem((unsigned char *)®.exs + (regno - EXS) * sizeof(unsigned int), | ||
594 | val, sizeof(unsigned int)); | ||
595 | |||
596 | } else if (regno == PC) { | ||
597 | /* Pseudo-register. Treat as read-only. */ | ||
598 | status = E02; | ||
599 | |||
600 | } else if (regno >= S0 && regno <= S15) { | ||
601 | /* 32-bit registers. */ | ||
602 | hex2mem((unsigned char *)&sreg.s0_0 + (reg.srs * 16 * sizeof(unsigned int)) + (regno - S0) * sizeof(unsigned int), val, sizeof(unsigned int)); | ||
603 | } else { | ||
604 | /* Non-existing register. */ | ||
605 | status = E05; | ||
606 | } | ||
607 | return status; | ||
608 | } | ||
609 | |||
610 | /* Read a value from a specified register in the register image. Returns the | ||
611 | value in the register or -1 for non-implemented registers. */ | ||
612 | static int | ||
613 | read_register(char regno, unsigned int *valptr) | ||
614 | { | ||
615 | int status = SUCCESS; | ||
616 | |||
617 | /* We read the zero registers from the register struct (instead of just returning 0) | ||
618 | to catch errors. */ | ||
619 | |||
620 | if (regno >= R0 && regno <= ACR) { | ||
621 | /* Consecutive 32-bit registers. */ | ||
622 | *valptr = *(unsigned int *)((char *)®.r0 + (regno - R0) * sizeof(unsigned int)); | ||
623 | |||
624 | } else if (regno == BZ || regno == VR) { | ||
625 | /* Consecutive 8-bit registers. */ | ||
626 | *valptr = (unsigned int)(*(unsigned char *) | ||
627 | ((char *)®.bz + (regno - BZ) * sizeof(char))); | ||
628 | |||
629 | } else if (regno == PID) { | ||
630 | /* 32-bit register. */ | ||
631 | *valptr = *(unsigned int *)((char *)®.pid); | ||
632 | |||
633 | } else if (regno == SRS) { | ||
634 | /* 8-bit register. */ | ||
635 | *valptr = (unsigned int)(*(unsigned char *)((char *)®.srs)); | ||
636 | |||
637 | } else if (regno == WZ) { | ||
638 | /* 16-bit register. */ | ||
639 | *valptr = (unsigned int)(*(unsigned short *)(char *)®.wz); | ||
640 | |||
641 | } else if (regno >= EXS && regno <= PC) { | ||
642 | /* Consecutive 32-bit registers. */ | ||
643 | *valptr = *(unsigned int *)((char *)®.exs + (regno - EXS) * sizeof(unsigned int)); | ||
644 | |||
645 | } else if (regno >= S0 && regno <= S15) { | ||
646 | /* Consecutive 32-bit registers, located elsewhere. */ | ||
647 | *valptr = *(unsigned int *)((char *)&sreg.s0_0 + (reg.srs * 16 * sizeof(unsigned int)) + (regno - S0) * sizeof(unsigned int)); | ||
648 | |||
649 | } else { | ||
650 | /* Non-existing register. */ | ||
651 | status = E05; | ||
652 | } | ||
653 | return status; | ||
654 | |||
655 | } | ||
656 | |||
657 | /********************************** Packet I/O ******************************/ | ||
658 | /* Returns the character equivalent of a nibble, bit 7, 6, 5, and 4 of a byte, | ||
659 | represented by int x. */ | ||
660 | static inline char | ||
661 | highhex(int x) | ||
662 | { | ||
663 | return hexchars[(x >> 4) & 0xf]; | ||
664 | } | ||
665 | |||
666 | /* Returns the character equivalent of a nibble, bit 3, 2, 1, and 0 of a byte, | ||
667 | represented by int x. */ | ||
668 | static inline char | ||
669 | lowhex(int x) | ||
670 | { | ||
671 | return hexchars[x & 0xf]; | ||
672 | } | ||
673 | |||
674 | /* Returns the integer equivalent of a hexadecimal character. */ | ||
675 | static int | ||
676 | hex(char ch) | ||
677 | { | ||
678 | if ((ch >= 'a') && (ch <= 'f')) | ||
679 | return (ch - 'a' + 10); | ||
680 | if ((ch >= '0') && (ch <= '9')) | ||
681 | return (ch - '0'); | ||
682 | if ((ch >= 'A') && (ch <= 'F')) | ||
683 | return (ch - 'A' + 10); | ||
684 | return -1; | ||
685 | } | ||
686 | |||
687 | /* Convert the memory, pointed to by mem into hexadecimal representation. | ||
688 | Put the result in buf, and return a pointer to the last character | ||
689 | in buf (null). */ | ||
690 | |||
691 | static char * | ||
692 | mem2hex(char *buf, unsigned char *mem, int count) | ||
693 | { | ||
694 | int i; | ||
695 | int ch; | ||
696 | |||
697 | if (mem == NULL) { | ||
698 | /* Invalid address, caught by 'm' packet handler. */ | ||
699 | for (i = 0; i < count; i++) { | ||
700 | *buf++ = '0'; | ||
701 | *buf++ = '0'; | ||
702 | } | ||
703 | } else { | ||
704 | /* Valid mem address. */ | ||
705 | for (i = 0; i < count; i++) { | ||
706 | ch = *mem++; | ||
707 | *buf++ = highhex (ch); | ||
708 | *buf++ = lowhex (ch); | ||
709 | } | ||
710 | } | ||
711 | /* Terminate properly. */ | ||
712 | *buf = '\0'; | ||
713 | return buf; | ||
714 | } | ||
715 | |||
716 | /* Same as mem2hex, but puts it in network byte order. */ | ||
717 | static char * | ||
718 | mem2hex_nbo(char *buf, unsigned char *mem, int count) | ||
719 | { | ||
720 | int i; | ||
721 | int ch; | ||
722 | |||
723 | mem += count - 1; | ||
724 | for (i = 0; i < count; i++) { | ||
725 | ch = *mem--; | ||
726 | *buf++ = highhex (ch); | ||
727 | *buf++ = lowhex (ch); | ||
728 | } | ||
729 | |||
730 | /* Terminate properly. */ | ||
731 | *buf = '\0'; | ||
732 | return buf; | ||
733 | } | ||
734 | |||
735 | /* Convert the array, in hexadecimal representation, pointed to by buf into | ||
736 | binary representation. Put the result in mem, and return a pointer to | ||
737 | the character after the last byte written. */ | ||
738 | static unsigned char* | ||
739 | hex2mem(unsigned char *mem, char *buf, int count) | ||
740 | { | ||
741 | int i; | ||
742 | unsigned char ch; | ||
743 | for (i = 0; i < count; i++) { | ||
744 | ch = hex (*buf++) << 4; | ||
745 | ch = ch + hex (*buf++); | ||
746 | *mem++ = ch; | ||
747 | } | ||
748 | return mem; | ||
749 | } | ||
750 | |||
751 | /* Put the content of the array, in binary representation, pointed to by buf | ||
752 | into memory pointed to by mem, and return a pointer to the character after | ||
753 | the last byte written. | ||
754 | Gdb will escape $, #, and the escape char (0x7d). */ | ||
755 | static unsigned char* | ||
756 | bin2mem(unsigned char *mem, unsigned char *buf, int count) | ||
757 | { | ||
758 | int i; | ||
759 | unsigned char *next; | ||
760 | for (i = 0; i < count; i++) { | ||
761 | /* Check for any escaped characters. Be paranoid and | ||
762 | only unescape chars that should be escaped. */ | ||
763 | if (*buf == 0x7d) { | ||
764 | next = buf + 1; | ||
765 | if (*next == 0x3 || *next == 0x4 || *next == 0x5D) { | ||
766 | /* #, $, ESC */ | ||
767 | buf++; | ||
768 | *buf += 0x20; | ||
769 | } | ||
770 | } | ||
771 | *mem++ = *buf++; | ||
772 | } | ||
773 | return mem; | ||
774 | } | ||
775 | |||
776 | /* Await the sequence $<data>#<checksum> and store <data> in the array buffer | ||
777 | returned. */ | ||
778 | static void | ||
779 | getpacket(char *buffer) | ||
780 | { | ||
781 | unsigned char checksum; | ||
782 | unsigned char xmitcsum; | ||
783 | int i; | ||
784 | int count; | ||
785 | char ch; | ||
786 | |||
787 | do { | ||
788 | while((ch = getDebugChar ()) != '$') | ||
789 | /* Wait for the start character $ and ignore all other characters */; | ||
790 | checksum = 0; | ||
791 | xmitcsum = -1; | ||
792 | count = 0; | ||
793 | /* Read until a # or the end of the buffer is reached */ | ||
794 | while (count < BUFMAX) { | ||
795 | ch = getDebugChar(); | ||
796 | if (ch == '#') | ||
797 | break; | ||
798 | checksum = checksum + ch; | ||
799 | buffer[count] = ch; | ||
800 | count = count + 1; | ||
801 | } | ||
802 | |||
803 | if (count >= BUFMAX) | ||
804 | continue; | ||
805 | |||
806 | buffer[count] = 0; | ||
807 | |||
808 | if (ch == '#') { | ||
809 | xmitcsum = hex(getDebugChar()) << 4; | ||
810 | xmitcsum += hex(getDebugChar()); | ||
811 | if (checksum != xmitcsum) { | ||
812 | /* Wrong checksum */ | ||
813 | putDebugChar('-'); | ||
814 | } else { | ||
815 | /* Correct checksum */ | ||
816 | putDebugChar('+'); | ||
817 | /* If sequence characters are received, reply with them */ | ||
818 | if (buffer[2] == ':') { | ||
819 | putDebugChar(buffer[0]); | ||
820 | putDebugChar(buffer[1]); | ||
821 | /* Remove the sequence characters from the buffer */ | ||
822 | count = gdb_cris_strlen(buffer); | ||
823 | for (i = 3; i <= count; i++) | ||
824 | buffer[i - 3] = buffer[i]; | ||
825 | } | ||
826 | } | ||
827 | } | ||
828 | } while (checksum != xmitcsum); | ||
829 | } | ||
830 | |||
831 | /* Send $<data>#<checksum> from the <data> in the array buffer. */ | ||
832 | |||
833 | static void | ||
834 | putpacket(char *buffer) | ||
835 | { | ||
836 | int checksum; | ||
837 | int runlen; | ||
838 | int encode; | ||
839 | |||
840 | do { | ||
841 | char *src = buffer; | ||
842 | putDebugChar('$'); | ||
843 | checksum = 0; | ||
844 | while (*src) { | ||
845 | /* Do run length encoding */ | ||
846 | putDebugChar(*src); | ||
847 | checksum += *src; | ||
848 | runlen = 0; | ||
849 | while (runlen < RUNLENMAX && *src == src[runlen]) { | ||
850 | runlen++; | ||
851 | } | ||
852 | if (runlen > 3) { | ||
853 | /* Got a useful amount */ | ||
854 | putDebugChar ('*'); | ||
855 | checksum += '*'; | ||
856 | encode = runlen + ' ' - 4; | ||
857 | putDebugChar(encode); | ||
858 | checksum += encode; | ||
859 | src += runlen; | ||
860 | } else { | ||
861 | src++; | ||
862 | } | ||
863 | } | ||
864 | putDebugChar('#'); | ||
865 | putDebugChar(highhex (checksum)); | ||
866 | putDebugChar(lowhex (checksum)); | ||
867 | } while(kgdb_started && (getDebugChar() != '+')); | ||
868 | } | ||
869 | |||
870 | /* The string str is prepended with the GDB printout token and sent. Required | ||
871 | in traditional implementations. */ | ||
872 | void | ||
873 | putDebugString(const unsigned char *str, int len) | ||
874 | { | ||
875 | /* Move SPC forward if we are single-stepping. */ | ||
876 | asm("spchere:"); | ||
877 | asm("move $spc, $r10"); | ||
878 | asm("cmp.d spchere, $r10"); | ||
879 | asm("bne nosstep"); | ||
880 | asm("nop"); | ||
881 | asm("move.d spccont, $r10"); | ||
882 | asm("move $r10, $spc"); | ||
883 | asm("nosstep:"); | ||
884 | |||
885 | output_buffer[0] = 'O'; | ||
886 | mem2hex(&output_buffer[1], (unsigned char *)str, len); | ||
887 | putpacket(output_buffer); | ||
888 | |||
889 | asm("spccont:"); | ||
890 | } | ||
891 | |||
892 | /********************************** Handle exceptions ************************/ | ||
893 | /* Build and send a response packet in order to inform the host the | ||
894 | stub is stopped. TAAn...:r...;n...:r...;n...:r...; | ||
895 | AA = signal number | ||
896 | n... = register number (hex) | ||
897 | r... = register contents | ||
898 | n... = `thread' | ||
899 | r... = thread process ID. This is a hex integer. | ||
900 | n... = other string not starting with valid hex digit. | ||
901 | gdb should ignore this n,r pair and go on to the next. | ||
902 | This way we can extend the protocol. */ | ||
903 | static void | ||
904 | stub_is_stopped(int sigval) | ||
905 | { | ||
906 | char *ptr = output_buffer; | ||
907 | unsigned int reg_cont; | ||
908 | |||
909 | /* Send trap type (converted to signal) */ | ||
910 | |||
911 | *ptr++ = 'T'; | ||
912 | *ptr++ = highhex(sigval); | ||
913 | *ptr++ = lowhex(sigval); | ||
914 | |||
915 | if (((reg.exs & 0xff00) >> 8) == 0xc) { | ||
916 | |||
917 | /* Some kind of hardware watchpoint triggered. Find which one | ||
918 | and determine its type (read/write/access). */ | ||
919 | int S, bp, trig_bits = 0, rw_bits = 0; | ||
920 | int trig_mask = 0; | ||
921 | unsigned int *bp_d_regs = &sreg.s3_3; | ||
922 | /* In a lot of cases, the stopped data address will simply be EDA. | ||
923 | In some cases, we adjust it to match the watched data range. | ||
924 | (We don't want to change the actual EDA though). */ | ||
925 | unsigned int stopped_data_address; | ||
926 | /* The S field of EXS. */ | ||
927 | S = (reg.exs & 0xffff0000) >> 16; | ||
928 | |||
929 | if (S & 1) { | ||
930 | /* Instruction watchpoint. */ | ||
931 | /* FIXME: Check against, and possibly adjust reported EDA. */ | ||
932 | } else { | ||
933 | /* Data watchpoint. Find the one that triggered. */ | ||
934 | for (bp = 0; bp < 6; bp++) { | ||
935 | |||
936 | /* Dx_RD, Dx_WR in the S field of EXS for this BP. */ | ||
937 | int bitpos_trig = 1 + bp * 2; | ||
938 | /* Dx_BPRD, Dx_BPWR in BP_CTRL for this BP. */ | ||
939 | int bitpos_config = 2 + bp * 4; | ||
940 | |||
941 | /* Get read/write trig bits for this BP. */ | ||
942 | trig_bits = (S & (3 << bitpos_trig)) >> bitpos_trig; | ||
943 | |||
944 | /* Read/write config bits for this BP. */ | ||
945 | rw_bits = (sreg.s0_3 & (3 << bitpos_config)) >> bitpos_config; | ||
946 | if (trig_bits) { | ||
947 | /* Sanity check: the BP shouldn't trigger for accesses | ||
948 | that it isn't configured for. */ | ||
949 | if ((rw_bits == 0x1 && trig_bits != 0x1) || | ||
950 | (rw_bits == 0x2 && trig_bits != 0x2)) | ||
951 | panic("Invalid r/w trigging for this BP"); | ||
952 | |||
953 | /* Mark this BP as trigged for future reference. */ | ||
954 | trig_mask |= (1 << bp); | ||
955 | |||
956 | if (reg.eda >= bp_d_regs[bp * 2] && | ||
957 | reg.eda <= bp_d_regs[bp * 2 + 1]) { | ||
958 | /* EDA withing range for this BP; it must be the one | ||
959 | we're looking for. */ | ||
960 | stopped_data_address = reg.eda; | ||
961 | break; | ||
962 | } | ||
963 | } | ||
964 | } | ||
965 | if (bp < 6) { | ||
966 | /* Found a trigged BP with EDA within its configured data range. */ | ||
967 | } else if (trig_mask) { | ||
968 | /* Something triggered, but EDA doesn't match any BP's range. */ | ||
969 | for (bp = 0; bp < 6; bp++) { | ||
970 | /* Dx_BPRD, Dx_BPWR in BP_CTRL for this BP. */ | ||
971 | int bitpos_config = 2 + bp * 4; | ||
972 | |||
973 | /* Read/write config bits for this BP (needed later). */ | ||
974 | rw_bits = (sreg.s0_3 & (3 << bitpos_config)) >> bitpos_config; | ||
975 | |||
976 | if (trig_mask & (1 << bp)) { | ||
977 | /* EDA within 31 bytes of the configured start address? */ | ||
978 | if (reg.eda + 31 >= bp_d_regs[bp * 2]) { | ||
979 | /* Changing the reported address to match | ||
980 | the start address of the first applicable BP. */ | ||
981 | stopped_data_address = bp_d_regs[bp * 2]; | ||
982 | break; | ||
983 | } else { | ||
984 | /* We continue since we might find another useful BP. */ | ||
985 | printk("EDA doesn't match trigged BP's range"); | ||
986 | } | ||
987 | } | ||
988 | } | ||
989 | } | ||
990 | |||
991 | /* No match yet? */ | ||
992 | BUG_ON(bp >= 6); | ||
993 | /* Note that we report the type according to what the BP is configured | ||
994 | for (otherwise we'd never report an 'awatch'), not according to how | ||
995 | it trigged. We did check that the trigged bits match what the BP is | ||
996 | configured for though. */ | ||
997 | if (rw_bits == 0x1) { | ||
998 | /* read */ | ||
999 | strncpy(ptr, "rwatch", 6); | ||
1000 | ptr += 6; | ||
1001 | } else if (rw_bits == 0x2) { | ||
1002 | /* write */ | ||
1003 | strncpy(ptr, "watch", 5); | ||
1004 | ptr += 5; | ||
1005 | } else if (rw_bits == 0x3) { | ||
1006 | /* access */ | ||
1007 | strncpy(ptr, "awatch", 6); | ||
1008 | ptr += 6; | ||
1009 | } else { | ||
1010 | panic("Invalid r/w bits for this BP."); | ||
1011 | } | ||
1012 | |||
1013 | *ptr++ = ':'; | ||
1014 | /* Note that we don't read_register(EDA, ...) */ | ||
1015 | ptr = mem2hex_nbo(ptr, (unsigned char *)&stopped_data_address, register_size[EDA]); | ||
1016 | *ptr++ = ';'; | ||
1017 | } | ||
1018 | } | ||
1019 | /* Only send PC, frame and stack pointer. */ | ||
1020 | read_register(PC, ®_cont); | ||
1021 | *ptr++ = highhex(PC); | ||
1022 | *ptr++ = lowhex(PC); | ||
1023 | *ptr++ = ':'; | ||
1024 | ptr = mem2hex(ptr, (unsigned char *)®_cont, register_size[PC]); | ||
1025 | *ptr++ = ';'; | ||
1026 | |||
1027 | read_register(R8, ®_cont); | ||
1028 | *ptr++ = highhex(R8); | ||
1029 | *ptr++ = lowhex(R8); | ||
1030 | *ptr++ = ':'; | ||
1031 | ptr = mem2hex(ptr, (unsigned char *)®_cont, register_size[R8]); | ||
1032 | *ptr++ = ';'; | ||
1033 | |||
1034 | read_register(SP, ®_cont); | ||
1035 | *ptr++ = highhex(SP); | ||
1036 | *ptr++ = lowhex(SP); | ||
1037 | *ptr++ = ':'; | ||
1038 | ptr = mem2hex(ptr, (unsigned char *)®_cont, register_size[SP]); | ||
1039 | *ptr++ = ';'; | ||
1040 | |||
1041 | /* Send ERP as well; this will save us an entire register fetch in some cases. */ | ||
1042 | read_register(ERP, ®_cont); | ||
1043 | *ptr++ = highhex(ERP); | ||
1044 | *ptr++ = lowhex(ERP); | ||
1045 | *ptr++ = ':'; | ||
1046 | ptr = mem2hex(ptr, (unsigned char *)®_cont, register_size[ERP]); | ||
1047 | *ptr++ = ';'; | ||
1048 | |||
1049 | /* null-terminate and send it off */ | ||
1050 | *ptr = 0; | ||
1051 | putpacket(output_buffer); | ||
1052 | } | ||
1053 | |||
1054 | /* Returns the size of an instruction that has a delay slot. */ | ||
1055 | |||
1056 | int insn_size(unsigned long pc) | ||
1057 | { | ||
1058 | unsigned short opcode = *(unsigned short *)pc; | ||
1059 | int size = 0; | ||
1060 | |||
1061 | switch ((opcode & 0x0f00) >> 8) { | ||
1062 | case 0x0: | ||
1063 | case 0x9: | ||
1064 | case 0xb: | ||
1065 | size = 2; | ||
1066 | break; | ||
1067 | case 0xe: | ||
1068 | case 0xf: | ||
1069 | size = 6; | ||
1070 | break; | ||
1071 | case 0xd: | ||
1072 | /* Could be 4 or 6; check more bits. */ | ||
1073 | if ((opcode & 0xff) == 0xff) | ||
1074 | size = 4; | ||
1075 | else | ||
1076 | size = 6; | ||
1077 | break; | ||
1078 | default: | ||
1079 | panic("Couldn't find size of opcode 0x%x at 0x%lx\n", opcode, pc); | ||
1080 | } | ||
1081 | |||
1082 | return size; | ||
1083 | } | ||
1084 | |||
1085 | void register_fixup(int sigval) | ||
1086 | { | ||
1087 | /* Compensate for ACR push at the beginning of exception handler. */ | ||
1088 | reg.sp += 4; | ||
1089 | |||
1090 | /* Standard case. */ | ||
1091 | reg.pc = reg.erp; | ||
1092 | if (reg.erp & 0x1) { | ||
1093 | /* Delay slot bit set. Report as stopped on proper instruction. */ | ||
1094 | if (reg.spc) { | ||
1095 | /* Rely on SPC if set. */ | ||
1096 | reg.pc = reg.spc; | ||
1097 | } else { | ||
1098 | /* Calculate the PC from the size of the instruction | ||
1099 | that the delay slot we're in belongs to. */ | ||
1100 | reg.pc += insn_size(reg.erp & ~1) - 1 ; | ||
1101 | } | ||
1102 | } | ||
1103 | |||
1104 | if ((reg.exs & 0x3) == 0x0) { | ||
1105 | /* Bits 1 - 0 indicate the type of memory operation performed | ||
1106 | by the interrupted instruction. 0 means no memory operation, | ||
1107 | and EDA is undefined in that case. We zero it to avoid confusion. */ | ||
1108 | reg.eda = 0; | ||
1109 | } | ||
1110 | |||
1111 | if (sigval == SIGTRAP) { | ||
1112 | /* Break 8, single step or hardware breakpoint exception. */ | ||
1113 | |||
1114 | /* Check IDX field of EXS. */ | ||
1115 | if (((reg.exs & 0xff00) >> 8) == 0x18) { | ||
1116 | |||
1117 | /* Break 8. */ | ||
1118 | |||
1119 | /* Static (compiled) breakpoints must return to the next instruction | ||
1120 | in order to avoid infinite loops (default value of ERP). Dynamic | ||
1121 | (gdb-invoked) must subtract the size of the break instruction from | ||
1122 | the ERP so that the instruction that was originally in the break | ||
1123 | instruction's place will be run when we return from the exception. */ | ||
1124 | if (!dynamic_bp) { | ||
1125 | /* Assuming that all breakpoints are dynamic from now on. */ | ||
1126 | dynamic_bp = 1; | ||
1127 | } else { | ||
1128 | |||
1129 | /* Only if not in a delay slot. */ | ||
1130 | if (!(reg.erp & 0x1)) { | ||
1131 | reg.erp -= 2; | ||
1132 | reg.pc -= 2; | ||
1133 | } | ||
1134 | } | ||
1135 | |||
1136 | } else if (((reg.exs & 0xff00) >> 8) == 0x3) { | ||
1137 | /* Single step. */ | ||
1138 | /* Don't fiddle with S1. */ | ||
1139 | |||
1140 | } else if (((reg.exs & 0xff00) >> 8) == 0xc) { | ||
1141 | |||
1142 | /* Hardware watchpoint exception. */ | ||
1143 | |||
1144 | /* SPC has been updated so that we will get a single step exception | ||
1145 | when we return, but we don't want that. */ | ||
1146 | reg.spc = 0; | ||
1147 | |||
1148 | /* Don't fiddle with S1. */ | ||
1149 | } | ||
1150 | |||
1151 | } else if (sigval == SIGINT) { | ||
1152 | /* Nothing special. */ | ||
1153 | } | ||
1154 | } | ||
1155 | |||
1156 | static void insert_watchpoint(char type, int addr, int len) | ||
1157 | { | ||
1158 | /* Breakpoint/watchpoint types (GDB terminology): | ||
1159 | 0 = memory breakpoint for instructions | ||
1160 | (not supported; done via memory write instead) | ||
1161 | 1 = hardware breakpoint for instructions (supported) | ||
1162 | 2 = write watchpoint (supported) | ||
1163 | 3 = read watchpoint (supported) | ||
1164 | 4 = access watchpoint (supported) */ | ||
1165 | |||
1166 | if (type < '1' || type > '4') { | ||
1167 | output_buffer[0] = 0; | ||
1168 | return; | ||
1169 | } | ||
1170 | |||
1171 | /* Read watchpoints are set as access watchpoints, because of GDB's | ||
1172 | inability to deal with pure read watchpoints. */ | ||
1173 | if (type == '3') | ||
1174 | type = '4'; | ||
1175 | |||
1176 | if (type == '1') { | ||
1177 | /* Hardware (instruction) breakpoint. */ | ||
1178 | /* Bit 0 in BP_CTRL holds the configuration for I0. */ | ||
1179 | if (sreg.s0_3 & 0x1) { | ||
1180 | /* Already in use. */ | ||
1181 | gdb_cris_strcpy(output_buffer, error_message[E04]); | ||
1182 | return; | ||
1183 | } | ||
1184 | /* Configure. */ | ||
1185 | sreg.s1_3 = addr; | ||
1186 | sreg.s2_3 = (addr + len - 1); | ||
1187 | sreg.s0_3 |= 1; | ||
1188 | } else { | ||
1189 | int bp; | ||
1190 | unsigned int *bp_d_regs = &sreg.s3_3; | ||
1191 | |||
1192 | /* The watchpoint allocation scheme is the simplest possible. | ||
1193 | For example, if a region is watched for read and | ||
1194 | a write watch is requested, a new watchpoint will | ||
1195 | be used. Also, if a watch for a region that is already | ||
1196 | covered by one or more existing watchpoints, a new | ||
1197 | watchpoint will be used. */ | ||
1198 | |||
1199 | /* First, find a free data watchpoint. */ | ||
1200 | for (bp = 0; bp < 6; bp++) { | ||
1201 | /* Each data watchpoint's control registers occupy 2 bits | ||
1202 | (hence the 3), starting at bit 2 for D0 (hence the 2) | ||
1203 | with 4 bits between for each watchpoint (yes, the 4). */ | ||
1204 | if (!(sreg.s0_3 & (0x3 << (2 + (bp * 4))))) { | ||
1205 | break; | ||
1206 | } | ||
1207 | } | ||
1208 | |||
1209 | if (bp > 5) { | ||
1210 | /* We're out of watchpoints. */ | ||
1211 | gdb_cris_strcpy(output_buffer, error_message[E04]); | ||
1212 | return; | ||
1213 | } | ||
1214 | |||
1215 | /* Configure the control register first. */ | ||
1216 | if (type == '3' || type == '4') { | ||
1217 | /* Trigger on read. */ | ||
1218 | sreg.s0_3 |= (1 << (2 + bp * 4)); | ||
1219 | } | ||
1220 | if (type == '2' || type == '4') { | ||
1221 | /* Trigger on write. */ | ||
1222 | sreg.s0_3 |= (2 << (2 + bp * 4)); | ||
1223 | } | ||
1224 | |||
1225 | /* Ugly pointer arithmetics to configure the watched range. */ | ||
1226 | bp_d_regs[bp * 2] = addr; | ||
1227 | bp_d_regs[bp * 2 + 1] = (addr + len - 1); | ||
1228 | } | ||
1229 | |||
1230 | /* Set the S1 flag to enable watchpoints. */ | ||
1231 | reg.ccs |= (1 << (S_CCS_BITNR + CCS_SHIFT)); | ||
1232 | gdb_cris_strcpy(output_buffer, "OK"); | ||
1233 | } | ||
1234 | |||
1235 | static void remove_watchpoint(char type, int addr, int len) | ||
1236 | { | ||
1237 | /* Breakpoint/watchpoint types: | ||
1238 | 0 = memory breakpoint for instructions | ||
1239 | (not supported; done via memory write instead) | ||
1240 | 1 = hardware breakpoint for instructions (supported) | ||
1241 | 2 = write watchpoint (supported) | ||
1242 | 3 = read watchpoint (supported) | ||
1243 | 4 = access watchpoint (supported) */ | ||
1244 | if (type < '1' || type > '4') { | ||
1245 | output_buffer[0] = 0; | ||
1246 | return; | ||
1247 | } | ||
1248 | |||
1249 | /* Read watchpoints are set as access watchpoints, because of GDB's | ||
1250 | inability to deal with pure read watchpoints. */ | ||
1251 | if (type == '3') | ||
1252 | type = '4'; | ||
1253 | |||
1254 | if (type == '1') { | ||
1255 | /* Hardware breakpoint. */ | ||
1256 | /* Bit 0 in BP_CTRL holds the configuration for I0. */ | ||
1257 | if (!(sreg.s0_3 & 0x1)) { | ||
1258 | /* Not in use. */ | ||
1259 | gdb_cris_strcpy(output_buffer, error_message[E04]); | ||
1260 | return; | ||
1261 | } | ||
1262 | /* Deconfigure. */ | ||
1263 | sreg.s1_3 = 0; | ||
1264 | sreg.s2_3 = 0; | ||
1265 | sreg.s0_3 &= ~1; | ||
1266 | } else { | ||
1267 | int bp; | ||
1268 | unsigned int *bp_d_regs = &sreg.s3_3; | ||
1269 | /* Try to find a watchpoint that is configured for the | ||
1270 | specified range, then check that read/write also matches. */ | ||
1271 | |||
1272 | /* Ugly pointer arithmetic, since I cannot rely on a | ||
1273 | single switch (addr) as there may be several watchpoints with | ||
1274 | the same start address for example. */ | ||
1275 | |||
1276 | for (bp = 0; bp < 6; bp++) { | ||
1277 | if (bp_d_regs[bp * 2] == addr && | ||
1278 | bp_d_regs[bp * 2 + 1] == (addr + len - 1)) { | ||
1279 | /* Matching range. */ | ||
1280 | int bitpos = 2 + bp * 4; | ||
1281 | int rw_bits; | ||
1282 | |||
1283 | /* Read/write bits for this BP. */ | ||
1284 | rw_bits = (sreg.s0_3 & (0x3 << bitpos)) >> bitpos; | ||
1285 | |||
1286 | if ((type == '3' && rw_bits == 0x1) || | ||
1287 | (type == '2' && rw_bits == 0x2) || | ||
1288 | (type == '4' && rw_bits == 0x3)) { | ||
1289 | /* Read/write matched. */ | ||
1290 | break; | ||
1291 | } | ||
1292 | } | ||
1293 | } | ||
1294 | |||
1295 | if (bp > 5) { | ||
1296 | /* No watchpoint matched. */ | ||
1297 | gdb_cris_strcpy(output_buffer, error_message[E04]); | ||
1298 | return; | ||
1299 | } | ||
1300 | |||
1301 | /* Found a matching watchpoint. Now, deconfigure it by | ||
1302 | both disabling read/write in bp_ctrl and zeroing its | ||
1303 | start/end addresses. */ | ||
1304 | sreg.s0_3 &= ~(3 << (2 + (bp * 4))); | ||
1305 | bp_d_regs[bp * 2] = 0; | ||
1306 | bp_d_regs[bp * 2 + 1] = 0; | ||
1307 | } | ||
1308 | |||
1309 | /* Note that we don't clear the S1 flag here. It's done when continuing. */ | ||
1310 | gdb_cris_strcpy(output_buffer, "OK"); | ||
1311 | } | ||
1312 | |||
1313 | |||
1314 | |||
1315 | /* All expected commands are sent from remote.c. Send a response according | ||
1316 | to the description in remote.c. */ | ||
1317 | void | ||
1318 | handle_exception(int sigval) | ||
1319 | { | ||
1320 | /* Avoid warning of not used. */ | ||
1321 | |||
1322 | USEDFUN(handle_exception); | ||
1323 | USEDVAR(internal_stack[0]); | ||
1324 | |||
1325 | register_fixup(sigval); | ||
1326 | |||
1327 | /* Send response. */ | ||
1328 | stub_is_stopped(sigval); | ||
1329 | |||
1330 | for (;;) { | ||
1331 | output_buffer[0] = '\0'; | ||
1332 | getpacket(input_buffer); | ||
1333 | switch (input_buffer[0]) { | ||
1334 | case 'g': | ||
1335 | /* Read registers: g | ||
1336 | Success: Each byte of register data is described by two hex digits. | ||
1337 | Registers are in the internal order for GDB, and the bytes | ||
1338 | in a register are in the same order the machine uses. | ||
1339 | Failure: void. */ | ||
1340 | { | ||
1341 | char *buf; | ||
1342 | /* General and special registers. */ | ||
1343 | buf = mem2hex(output_buffer, (char *)®, sizeof(registers)); | ||
1344 | /* Support registers. */ | ||
1345 | /* -1 because of the null termination that mem2hex adds. */ | ||
1346 | mem2hex(buf, | ||
1347 | (char *)&sreg + (reg.srs * 16 * sizeof(unsigned int)), | ||
1348 | 16 * sizeof(unsigned int)); | ||
1349 | break; | ||
1350 | } | ||
1351 | case 'G': | ||
1352 | /* Write registers. GXX..XX | ||
1353 | Each byte of register data is described by two hex digits. | ||
1354 | Success: OK | ||
1355 | Failure: void. */ | ||
1356 | /* General and special registers. */ | ||
1357 | hex2mem((char *)®, &input_buffer[1], sizeof(registers)); | ||
1358 | /* Support registers. */ | ||
1359 | hex2mem((char *)&sreg + (reg.srs * 16 * sizeof(unsigned int)), | ||
1360 | &input_buffer[1] + sizeof(registers), | ||
1361 | 16 * sizeof(unsigned int)); | ||
1362 | gdb_cris_strcpy(output_buffer, "OK"); | ||
1363 | break; | ||
1364 | |||
1365 | case 'P': | ||
1366 | /* Write register. Pn...=r... | ||
1367 | Write register n..., hex value without 0x, with value r..., | ||
1368 | which contains a hex value without 0x and two hex digits | ||
1369 | for each byte in the register (target byte order). P1f=11223344 means | ||
1370 | set register 31 to 44332211. | ||
1371 | Success: OK | ||
1372 | Failure: E02, E05 */ | ||
1373 | { | ||
1374 | char *suffix; | ||
1375 | int regno = gdb_cris_strtol(&input_buffer[1], &suffix, 16); | ||
1376 | int status; | ||
1377 | |||
1378 | status = write_register(regno, suffix+1); | ||
1379 | |||
1380 | switch (status) { | ||
1381 | case E02: | ||
1382 | /* Do not support read-only registers. */ | ||
1383 | gdb_cris_strcpy(output_buffer, error_message[E02]); | ||
1384 | break; | ||
1385 | case E05: | ||
1386 | /* Do not support non-existing registers. */ | ||
1387 | gdb_cris_strcpy(output_buffer, error_message[E05]); | ||
1388 | break; | ||
1389 | default: | ||
1390 | /* Valid register number. */ | ||
1391 | gdb_cris_strcpy(output_buffer, "OK"); | ||
1392 | break; | ||
1393 | } | ||
1394 | } | ||
1395 | break; | ||
1396 | |||
1397 | case 'm': | ||
1398 | /* Read from memory. mAA..AA,LLLL | ||
1399 | AA..AA is the address and LLLL is the length. | ||
1400 | Success: XX..XX is the memory content. Can be fewer bytes than | ||
1401 | requested if only part of the data may be read. m6000120a,6c means | ||
1402 | retrieve 108 byte from base address 6000120a. | ||
1403 | Failure: void. */ | ||
1404 | { | ||
1405 | char *suffix; | ||
1406 | unsigned char *addr = (unsigned char *)gdb_cris_strtol(&input_buffer[1], | ||
1407 | &suffix, 16); | ||
1408 | int len = gdb_cris_strtol(suffix+1, 0, 16); | ||
1409 | |||
1410 | /* Bogus read (i.e. outside the kernel's | ||
1411 | segment)? . */ | ||
1412 | if (!((unsigned int)addr >= 0xc0000000 && | ||
1413 | (unsigned int)addr < 0xd0000000)) | ||
1414 | addr = NULL; | ||
1415 | |||
1416 | mem2hex(output_buffer, addr, len); | ||
1417 | } | ||
1418 | break; | ||
1419 | |||
1420 | case 'X': | ||
1421 | /* Write to memory. XAA..AA,LLLL:XX..XX | ||
1422 | AA..AA is the start address, LLLL is the number of bytes, and | ||
1423 | XX..XX is the binary data. | ||
1424 | Success: OK | ||
1425 | Failure: void. */ | ||
1426 | case 'M': | ||
1427 | /* Write to memory. MAA..AA,LLLL:XX..XX | ||
1428 | AA..AA is the start address, LLLL is the number of bytes, and | ||
1429 | XX..XX is the hexadecimal data. | ||
1430 | Success: OK | ||
1431 | Failure: void. */ | ||
1432 | { | ||
1433 | char *lenptr; | ||
1434 | char *dataptr; | ||
1435 | unsigned char *addr = (unsigned char *)gdb_cris_strtol(&input_buffer[1], | ||
1436 | &lenptr, 16); | ||
1437 | int len = gdb_cris_strtol(lenptr+1, &dataptr, 16); | ||
1438 | if (*lenptr == ',' && *dataptr == ':') { | ||
1439 | if (input_buffer[0] == 'M') { | ||
1440 | hex2mem(addr, dataptr + 1, len); | ||
1441 | } else /* X */ { | ||
1442 | bin2mem(addr, dataptr + 1, len); | ||
1443 | } | ||
1444 | gdb_cris_strcpy(output_buffer, "OK"); | ||
1445 | } | ||
1446 | else { | ||
1447 | gdb_cris_strcpy(output_buffer, error_message[E06]); | ||
1448 | } | ||
1449 | } | ||
1450 | break; | ||
1451 | |||
1452 | case 'c': | ||
1453 | /* Continue execution. cAA..AA | ||
1454 | AA..AA is the address where execution is resumed. If AA..AA is | ||
1455 | omitted, resume at the present address. | ||
1456 | Success: return to the executing thread. | ||
1457 | Failure: will never know. */ | ||
1458 | |||
1459 | if (input_buffer[1] != '\0') { | ||
1460 | /* FIXME: Doesn't handle address argument. */ | ||
1461 | gdb_cris_strcpy(output_buffer, error_message[E04]); | ||
1462 | break; | ||
1463 | } | ||
1464 | |||
1465 | /* Before continuing, make sure everything is set up correctly. */ | ||
1466 | |||
1467 | /* Set the SPC to some unlikely value. */ | ||
1468 | reg.spc = 0; | ||
1469 | /* Set the S1 flag to 0 unless some watchpoint is enabled (since setting | ||
1470 | S1 to 0 would also disable watchpoints). (Note that bits 26-31 in BP_CTRL | ||
1471 | are reserved, so don't check against those). */ | ||
1472 | if ((sreg.s0_3 & 0x3fff) == 0) { | ||
1473 | reg.ccs &= ~(1 << (S_CCS_BITNR + CCS_SHIFT)); | ||
1474 | } | ||
1475 | |||
1476 | return; | ||
1477 | |||
1478 | case 's': | ||
1479 | /* Step. sAA..AA | ||
1480 | AA..AA is the address where execution is resumed. If AA..AA is | ||
1481 | omitted, resume at the present address. Success: return to the | ||
1482 | executing thread. Failure: will never know. */ | ||
1483 | |||
1484 | if (input_buffer[1] != '\0') { | ||
1485 | /* FIXME: Doesn't handle address argument. */ | ||
1486 | gdb_cris_strcpy(output_buffer, error_message[E04]); | ||
1487 | break; | ||
1488 | } | ||
1489 | |||
1490 | /* Set the SPC to PC, which is where we'll return | ||
1491 | (deduced previously). */ | ||
1492 | reg.spc = reg.pc; | ||
1493 | |||
1494 | /* Set the S1 (first stacked, not current) flag, which will | ||
1495 | kick into action when we rfe. */ | ||
1496 | reg.ccs |= (1 << (S_CCS_BITNR + CCS_SHIFT)); | ||
1497 | return; | ||
1498 | |||
1499 | case 'Z': | ||
1500 | |||
1501 | /* Insert breakpoint or watchpoint, Ztype,addr,length. | ||
1502 | Remote protocol says: A remote target shall return an empty string | ||
1503 | for an unrecognized breakpoint or watchpoint packet type. */ | ||
1504 | { | ||
1505 | char *lenptr; | ||
1506 | char *dataptr; | ||
1507 | int addr = gdb_cris_strtol(&input_buffer[3], &lenptr, 16); | ||
1508 | int len = gdb_cris_strtol(lenptr + 1, &dataptr, 16); | ||
1509 | char type = input_buffer[1]; | ||
1510 | |||
1511 | insert_watchpoint(type, addr, len); | ||
1512 | break; | ||
1513 | } | ||
1514 | |||
1515 | case 'z': | ||
1516 | /* Remove breakpoint or watchpoint, Ztype,addr,length. | ||
1517 | Remote protocol says: A remote target shall return an empty string | ||
1518 | for an unrecognized breakpoint or watchpoint packet type. */ | ||
1519 | { | ||
1520 | char *lenptr; | ||
1521 | char *dataptr; | ||
1522 | int addr = gdb_cris_strtol(&input_buffer[3], &lenptr, 16); | ||
1523 | int len = gdb_cris_strtol(lenptr + 1, &dataptr, 16); | ||
1524 | char type = input_buffer[1]; | ||
1525 | |||
1526 | remove_watchpoint(type, addr, len); | ||
1527 | break; | ||
1528 | } | ||
1529 | |||
1530 | |||
1531 | case '?': | ||
1532 | /* The last signal which caused a stop. ? | ||
1533 | Success: SAA, where AA is the signal number. | ||
1534 | Failure: void. */ | ||
1535 | output_buffer[0] = 'S'; | ||
1536 | output_buffer[1] = highhex(sigval); | ||
1537 | output_buffer[2] = lowhex(sigval); | ||
1538 | output_buffer[3] = 0; | ||
1539 | break; | ||
1540 | |||
1541 | case 'D': | ||
1542 | /* Detach from host. D | ||
1543 | Success: OK, and return to the executing thread. | ||
1544 | Failure: will never know */ | ||
1545 | putpacket("OK"); | ||
1546 | return; | ||
1547 | |||
1548 | case 'k': | ||
1549 | case 'r': | ||
1550 | /* kill request or reset request. | ||
1551 | Success: restart of target. | ||
1552 | Failure: will never know. */ | ||
1553 | kill_restart(); | ||
1554 | break; | ||
1555 | |||
1556 | case 'C': | ||
1557 | case 'S': | ||
1558 | case '!': | ||
1559 | case 'R': | ||
1560 | case 'd': | ||
1561 | /* Continue with signal sig. Csig;AA..AA | ||
1562 | Step with signal sig. Ssig;AA..AA | ||
1563 | Use the extended remote protocol. ! | ||
1564 | Restart the target system. R0 | ||
1565 | Toggle debug flag. d | ||
1566 | Search backwards. tAA:PP,MM | ||
1567 | Not supported: E04 */ | ||
1568 | |||
1569 | /* FIXME: What's the difference between not supported | ||
1570 | and ignored (below)? */ | ||
1571 | gdb_cris_strcpy(output_buffer, error_message[E04]); | ||
1572 | break; | ||
1573 | |||
1574 | default: | ||
1575 | /* The stub should ignore other request and send an empty | ||
1576 | response ($#<checksum>). This way we can extend the protocol and GDB | ||
1577 | can tell whether the stub it is talking to uses the old or the new. */ | ||
1578 | output_buffer[0] = 0; | ||
1579 | break; | ||
1580 | } | ||
1581 | putpacket(output_buffer); | ||
1582 | } | ||
1583 | } | ||
1584 | |||
1585 | void | ||
1586 | kgdb_init(void) | ||
1587 | { | ||
1588 | reg_intr_vect_rw_mask intr_mask; | ||
1589 | reg_ser_rw_intr_mask ser_intr_mask; | ||
1590 | |||
1591 | /* Configure the kgdb serial port. */ | ||
1592 | #if defined(CONFIG_ETRAX_KGDB_PORT0) | ||
1593 | /* Note: no shortcut registered (not handled by multiple_interrupt). | ||
1594 | See entry.S. */ | ||
1595 | set_exception_vector(SER0_INTR_VECT, kgdb_handle_exception); | ||
1596 | /* Enable the ser irq in the global config. */ | ||
1597 | intr_mask = REG_RD(intr_vect, regi_irq, rw_mask); | ||
1598 | intr_mask.ser0 = 1; | ||
1599 | REG_WR(intr_vect, regi_irq, rw_mask, intr_mask); | ||
1600 | |||
1601 | ser_intr_mask = REG_RD(ser, regi_ser0, rw_intr_mask); | ||
1602 | ser_intr_mask.data_avail = regk_ser_yes; | ||
1603 | REG_WR(ser, regi_ser0, rw_intr_mask, ser_intr_mask); | ||
1604 | #elif defined(CONFIG_ETRAX_KGDB_PORT1) | ||
1605 | /* Note: no shortcut registered (not handled by multiple_interrupt). | ||
1606 | See entry.S. */ | ||
1607 | set_exception_vector(SER1_INTR_VECT, kgdb_handle_exception); | ||
1608 | /* Enable the ser irq in the global config. */ | ||
1609 | intr_mask = REG_RD(intr_vect, regi_irq, rw_mask); | ||
1610 | intr_mask.ser1 = 1; | ||
1611 | REG_WR(intr_vect, regi_irq, rw_mask, intr_mask); | ||
1612 | |||
1613 | ser_intr_mask = REG_RD(ser, regi_ser1, rw_intr_mask); | ||
1614 | ser_intr_mask.data_avail = regk_ser_yes; | ||
1615 | REG_WR(ser, regi_ser1, rw_intr_mask, ser_intr_mask); | ||
1616 | #elif defined(CONFIG_ETRAX_KGDB_PORT2) | ||
1617 | /* Note: no shortcut registered (not handled by multiple_interrupt). | ||
1618 | See entry.S. */ | ||
1619 | set_exception_vector(SER2_INTR_VECT, kgdb_handle_exception); | ||
1620 | /* Enable the ser irq in the global config. */ | ||
1621 | intr_mask = REG_RD(intr_vect, regi_irq, rw_mask); | ||
1622 | intr_mask.ser2 = 1; | ||
1623 | REG_WR(intr_vect, regi_irq, rw_mask, intr_mask); | ||
1624 | |||
1625 | ser_intr_mask = REG_RD(ser, regi_ser2, rw_intr_mask); | ||
1626 | ser_intr_mask.data_avail = regk_ser_yes; | ||
1627 | REG_WR(ser, regi_ser2, rw_intr_mask, ser_intr_mask); | ||
1628 | #elif defined(CONFIG_ETRAX_KGDB_PORT3) | ||
1629 | /* Note: no shortcut registered (not handled by multiple_interrupt). | ||
1630 | See entry.S. */ | ||
1631 | set_exception_vector(SER3_INTR_VECT, kgdb_handle_exception); | ||
1632 | /* Enable the ser irq in the global config. */ | ||
1633 | intr_mask = REG_RD(intr_vect, regi_irq, rw_mask); | ||
1634 | intr_mask.ser3 = 1; | ||
1635 | REG_WR(intr_vect, regi_irq, rw_mask, intr_mask); | ||
1636 | |||
1637 | ser_intr_mask = REG_RD(ser, regi_ser3, rw_intr_mask); | ||
1638 | ser_intr_mask.data_avail = regk_ser_yes; | ||
1639 | REG_WR(ser, regi_ser3, rw_intr_mask, ser_intr_mask); | ||
1640 | #endif | ||
1641 | |||
1642 | } | ||
1643 | /* Performs a complete re-start from scratch. */ | ||
1644 | static void | ||
1645 | kill_restart(void) | ||
1646 | { | ||
1647 | machine_restart(""); | ||
1648 | } | ||
1649 | |||
1650 | /* Use this static breakpoint in the start-up only. */ | ||
1651 | |||
1652 | void | ||
1653 | breakpoint(void) | ||
1654 | { | ||
1655 | kgdb_started = 1; | ||
1656 | dynamic_bp = 0; /* This is a static, not a dynamic breakpoint. */ | ||
1657 | __asm__ volatile ("break 8"); /* Jump to kgdb_handle_breakpoint. */ | ||
1658 | } | ||
1659 | |||
1660 | /****************************** End of file **********************************/ | ||