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authorLinus Torvalds <torvalds@g5.osdl.org>2005-11-02 00:32:14 -0500
committerLinus Torvalds <torvalds@g5.osdl.org>2005-11-02 00:32:14 -0500
commit7f36b1e9582c06d0ddef5f2416c9b17017647d1f (patch)
treef83cbcef623476b9b8a14f7a0cc66eb92552a651 /arch/arm/mach-ixp2000/uengine.c
parent0e016b9fa134d79341cca5e336ccbcea066d5f81 (diff)
parent73ee723e4c6d179c2e9496cc4caf160a18d95603 (diff)
Merge master.kernel.org:/home/rmk/linux-2.6-arm
Diffstat (limited to 'arch/arm/mach-ixp2000/uengine.c')
-rw-r--r--arch/arm/mach-ixp2000/uengine.c474
1 files changed, 474 insertions, 0 deletions
diff --git a/arch/arm/mach-ixp2000/uengine.c b/arch/arm/mach-ixp2000/uengine.c
new file mode 100644
index 000000000000..43e234349d4a
--- /dev/null
+++ b/arch/arm/mach-ixp2000/uengine.c
@@ -0,0 +1,474 @@
1/*
2 * Generic library functions for the microengines found on the Intel
3 * IXP2000 series of network processors.
4 *
5 * Copyright (C) 2004, 2005 Lennert Buytenhek <buytenh@wantstofly.org>
6 * Dedicated to Marija Kulikova.
7 *
8 * This program is free software; you can redistribute it and/or modify
9 * it under the terms of the GNU Lesser General Public License as
10 * published by the Free Software Foundation; either version 2.1 of the
11 * License, or (at your option) any later version.
12 */
13
14#include <linux/config.h>
15#include <linux/kernel.h>
16#include <linux/init.h>
17#include <linux/slab.h>
18#include <linux/module.h>
19#include <linux/string.h>
20#include <asm/hardware.h>
21#include <asm/arch/ixp2000-regs.h>
22#include <asm/arch/uengine.h>
23#include <asm/io.h>
24
25#define USTORE_ADDRESS 0x000
26#define USTORE_DATA_LOWER 0x004
27#define USTORE_DATA_UPPER 0x008
28#define CTX_ENABLES 0x018
29#define CC_ENABLE 0x01c
30#define CSR_CTX_POINTER 0x020
31#define INDIRECT_CTX_STS 0x040
32#define ACTIVE_CTX_STS 0x044
33#define INDIRECT_CTX_SIG_EVENTS 0x048
34#define INDIRECT_CTX_WAKEUP_EVENTS 0x050
35#define NN_PUT 0x080
36#define NN_GET 0x084
37#define TIMESTAMP_LOW 0x0c0
38#define TIMESTAMP_HIGH 0x0c4
39#define T_INDEX_BYTE_INDEX 0x0f4
40#define LOCAL_CSR_STATUS 0x180
41
42u32 ixp2000_uengine_mask;
43
44static void *ixp2000_uengine_csr_area(int uengine)
45{
46 return ((void *)IXP2000_UENGINE_CSR_VIRT_BASE) + (uengine << 10);
47}
48
49/*
50 * LOCAL_CSR_STATUS=1 after a read or write to a microengine's CSR
51 * space means that the microengine we tried to access was also trying
52 * to access its own CSR space on the same clock cycle as we did. When
53 * this happens, we lose the arbitration process by default, and the
54 * read or write we tried to do was not actually performed, so we try
55 * again until it succeeds.
56 */
57u32 ixp2000_uengine_csr_read(int uengine, int offset)
58{
59 void *uebase;
60 u32 *local_csr_status;
61 u32 *reg;
62 u32 value;
63
64 uebase = ixp2000_uengine_csr_area(uengine);
65
66 local_csr_status = (u32 *)(uebase + LOCAL_CSR_STATUS);
67 reg = (u32 *)(uebase + offset);
68 do {
69 value = ixp2000_reg_read(reg);
70 } while (ixp2000_reg_read(local_csr_status) & 1);
71
72 return value;
73}
74EXPORT_SYMBOL(ixp2000_uengine_csr_read);
75
76void ixp2000_uengine_csr_write(int uengine, int offset, u32 value)
77{
78 void *uebase;
79 u32 *local_csr_status;
80 u32 *reg;
81
82 uebase = ixp2000_uengine_csr_area(uengine);
83
84 local_csr_status = (u32 *)(uebase + LOCAL_CSR_STATUS);
85 reg = (u32 *)(uebase + offset);
86 do {
87 ixp2000_reg_write(reg, value);
88 } while (ixp2000_reg_read(local_csr_status) & 1);
89}
90EXPORT_SYMBOL(ixp2000_uengine_csr_write);
91
92void ixp2000_uengine_reset(u32 uengine_mask)
93{
94 ixp2000_reg_write(IXP2000_RESET1, uengine_mask & ixp2000_uengine_mask);
95 ixp2000_reg_write(IXP2000_RESET1, 0);
96}
97EXPORT_SYMBOL(ixp2000_uengine_reset);
98
99void ixp2000_uengine_set_mode(int uengine, u32 mode)
100{
101 /*
102 * CTL_STR_PAR_EN: unconditionally enable parity checking on
103 * control store.
104 */
105 mode |= 0x10000000;
106 ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mode);
107
108 /*
109 * Enable updating of condition codes.
110 */
111 ixp2000_uengine_csr_write(uengine, CC_ENABLE, 0x00002000);
112
113 /*
114 * Initialise other per-microengine registers.
115 */
116 ixp2000_uengine_csr_write(uengine, NN_PUT, 0x00);
117 ixp2000_uengine_csr_write(uengine, NN_GET, 0x00);
118 ixp2000_uengine_csr_write(uengine, T_INDEX_BYTE_INDEX, 0);
119}
120EXPORT_SYMBOL(ixp2000_uengine_set_mode);
121
122static int make_even_parity(u32 x)
123{
124 return hweight32(x) & 1;
125}
126
127static void ustore_write(int uengine, u64 insn)
128{
129 /*
130 * Generate even parity for top and bottom 20 bits.
131 */
132 insn |= (u64)make_even_parity((insn >> 20) & 0x000fffff) << 41;
133 insn |= (u64)make_even_parity(insn & 0x000fffff) << 40;
134
135 /*
136 * Write to microstore. The second write auto-increments
137 * the USTORE_ADDRESS index register.
138 */
139 ixp2000_uengine_csr_write(uengine, USTORE_DATA_LOWER, (u32)insn);
140 ixp2000_uengine_csr_write(uengine, USTORE_DATA_UPPER, (u32)(insn >> 32));
141}
142
143void ixp2000_uengine_load_microcode(int uengine, u8 *ucode, int insns)
144{
145 int i;
146
147 /*
148 * Start writing to microstore at address 0.
149 */
150 ixp2000_uengine_csr_write(uengine, USTORE_ADDRESS, 0x80000000);
151 for (i = 0; i < insns; i++) {
152 u64 insn;
153
154 insn = (((u64)ucode[0]) << 32) |
155 (((u64)ucode[1]) << 24) |
156 (((u64)ucode[2]) << 16) |
157 (((u64)ucode[3]) << 8) |
158 ((u64)ucode[4]);
159 ucode += 5;
160
161 ustore_write(uengine, insn);
162 }
163
164 /*
165 * Pad with a few NOPs at the end (to avoid the microengine
166 * aborting as it prefetches beyond the last instruction), unless
167 * we run off the end of the instruction store first, at which
168 * point the address register will wrap back to zero.
169 */
170 for (i = 0; i < 4; i++) {
171 u32 addr;
172
173 addr = ixp2000_uengine_csr_read(uengine, USTORE_ADDRESS);
174 if (addr == 0x80000000)
175 break;
176 ustore_write(uengine, 0xf0000c0300ULL);
177 }
178
179 /*
180 * End programming.
181 */
182 ixp2000_uengine_csr_write(uengine, USTORE_ADDRESS, 0x00000000);
183}
184EXPORT_SYMBOL(ixp2000_uengine_load_microcode);
185
186void ixp2000_uengine_init_context(int uengine, int context, int pc)
187{
188 /*
189 * Select the right context for indirect access.
190 */
191 ixp2000_uengine_csr_write(uengine, CSR_CTX_POINTER, context);
192
193 /*
194 * Initialise signal masks to immediately go to Ready state.
195 */
196 ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_SIG_EVENTS, 1);
197 ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_WAKEUP_EVENTS, 1);
198
199 /*
200 * Set program counter.
201 */
202 ixp2000_uengine_csr_write(uengine, INDIRECT_CTX_STS, pc);
203}
204EXPORT_SYMBOL(ixp2000_uengine_init_context);
205
206void ixp2000_uengine_start_contexts(int uengine, u8 ctx_mask)
207{
208 u32 mask;
209
210 /*
211 * Enable the specified context to go to Executing state.
212 */
213 mask = ixp2000_uengine_csr_read(uengine, CTX_ENABLES);
214 mask |= ctx_mask << 8;
215 ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mask);
216}
217EXPORT_SYMBOL(ixp2000_uengine_start_contexts);
218
219void ixp2000_uengine_stop_contexts(int uengine, u8 ctx_mask)
220{
221 u32 mask;
222
223 /*
224 * Disable the Ready->Executing transition. Note that this
225 * does not stop the context until it voluntarily yields.
226 */
227 mask = ixp2000_uengine_csr_read(uengine, CTX_ENABLES);
228 mask &= ~(ctx_mask << 8);
229 ixp2000_uengine_csr_write(uengine, CTX_ENABLES, mask);
230}
231EXPORT_SYMBOL(ixp2000_uengine_stop_contexts);
232
233static int check_ixp_type(struct ixp2000_uengine_code *c)
234{
235 u32 product_id;
236 u32 rev;
237
238 product_id = ixp2000_reg_read(IXP2000_PRODUCT_ID);
239 if (((product_id >> 16) & 0x1f) != 0)
240 return 0;
241
242 switch ((product_id >> 8) & 0xff) {
243 case 0: /* IXP2800 */
244 if (!(c->cpu_model_bitmask & 4))
245 return 0;
246 break;
247
248 case 1: /* IXP2850 */
249 if (!(c->cpu_model_bitmask & 8))
250 return 0;
251 break;
252
253 case 2: /* IXP2400 */
254 if (!(c->cpu_model_bitmask & 2))
255 return 0;
256 break;
257
258 default:
259 return 0;
260 }
261
262 rev = product_id & 0xff;
263 if (rev < c->cpu_min_revision || rev > c->cpu_max_revision)
264 return 0;
265
266 return 1;
267}
268
269static void generate_ucode(u8 *ucode, u32 *gpr_a, u32 *gpr_b)
270{
271 int offset;
272 int i;
273
274 offset = 0;
275
276 for (i = 0; i < 128; i++) {
277 u8 b3;
278 u8 b2;
279 u8 b1;
280 u8 b0;
281
282 b3 = (gpr_a[i] >> 24) & 0xff;
283 b2 = (gpr_a[i] >> 16) & 0xff;
284 b1 = (gpr_a[i] >> 8) & 0xff;
285 b0 = gpr_a[i] & 0xff;
286
287 // immed[@ai, (b1 << 8) | b0]
288 // 11110000 0000VVVV VVVV11VV VVVVVV00 1IIIIIII
289 ucode[offset++] = 0xf0;
290 ucode[offset++] = (b1 >> 4);
291 ucode[offset++] = (b1 << 4) | 0x0c | (b0 >> 6);
292 ucode[offset++] = (b0 << 2);
293 ucode[offset++] = 0x80 | i;
294
295 // immed_w1[@ai, (b3 << 8) | b2]
296 // 11110100 0100VVVV VVVV11VV VVVVVV00 1IIIIIII
297 ucode[offset++] = 0xf4;
298 ucode[offset++] = 0x40 | (b3 >> 4);
299 ucode[offset++] = (b3 << 4) | 0x0c | (b2 >> 6);
300 ucode[offset++] = (b2 << 2);
301 ucode[offset++] = 0x80 | i;
302 }
303
304 for (i = 0; i < 128; i++) {
305 u8 b3;
306 u8 b2;
307 u8 b1;
308 u8 b0;
309
310 b3 = (gpr_b[i] >> 24) & 0xff;
311 b2 = (gpr_b[i] >> 16) & 0xff;
312 b1 = (gpr_b[i] >> 8) & 0xff;
313 b0 = gpr_b[i] & 0xff;
314
315 // immed[@bi, (b1 << 8) | b0]
316 // 11110000 0000VVVV VVVV001I IIIIII11 VVVVVVVV
317 ucode[offset++] = 0xf0;
318 ucode[offset++] = (b1 >> 4);
319 ucode[offset++] = (b1 << 4) | 0x02 | (i >> 6);
320 ucode[offset++] = (i << 2) | 0x03;
321 ucode[offset++] = b0;
322
323 // immed_w1[@bi, (b3 << 8) | b2]
324 // 11110100 0100VVVV VVVV001I IIIIII11 VVVVVVVV
325 ucode[offset++] = 0xf4;
326 ucode[offset++] = 0x40 | (b3 >> 4);
327 ucode[offset++] = (b3 << 4) | 0x02 | (i >> 6);
328 ucode[offset++] = (i << 2) | 0x03;
329 ucode[offset++] = b2;
330 }
331
332 // ctx_arb[kill]
333 ucode[offset++] = 0xe0;
334 ucode[offset++] = 0x00;
335 ucode[offset++] = 0x01;
336 ucode[offset++] = 0x00;
337 ucode[offset++] = 0x00;
338}
339
340static int set_initial_registers(int uengine, struct ixp2000_uengine_code *c)
341{
342 int per_ctx_regs;
343 u32 *gpr_a;
344 u32 *gpr_b;
345 u8 *ucode;
346 int i;
347
348 gpr_a = kmalloc(128 * sizeof(u32), GFP_KERNEL);
349 gpr_b = kmalloc(128 * sizeof(u32), GFP_KERNEL);
350 ucode = kmalloc(513 * 5, GFP_KERNEL);
351 if (gpr_a == NULL || gpr_b == NULL || ucode == NULL) {
352 kfree(ucode);
353 kfree(gpr_b);
354 kfree(gpr_a);
355 return 1;
356 }
357
358 per_ctx_regs = 16;
359 if (c->uengine_parameters & IXP2000_UENGINE_4_CONTEXTS)
360 per_ctx_regs = 32;
361
362 memset(gpr_a, 0, sizeof(gpr_a));
363 memset(gpr_b, 0, sizeof(gpr_b));
364 for (i = 0; i < 256; i++) {
365 struct ixp2000_reg_value *r = c->initial_reg_values + i;
366 u32 *bank;
367 int inc;
368 int j;
369
370 if (r->reg == -1)
371 break;
372
373 bank = (r->reg & 0x400) ? gpr_b : gpr_a;
374 inc = (r->reg & 0x80) ? 128 : per_ctx_regs;
375
376 j = r->reg & 0x7f;
377 while (j < 128) {
378 bank[j] = r->value;
379 j += inc;
380 }
381 }
382
383 generate_ucode(ucode, gpr_a, gpr_b);
384 ixp2000_uengine_load_microcode(uengine, ucode, 513);
385 ixp2000_uengine_init_context(uengine, 0, 0);
386 ixp2000_uengine_start_contexts(uengine, 0x01);
387 for (i = 0; i < 100; i++) {
388 u32 status;
389
390 status = ixp2000_uengine_csr_read(uengine, ACTIVE_CTX_STS);
391 if (!(status & 0x80000000))
392 break;
393 }
394 ixp2000_uengine_stop_contexts(uengine, 0x01);
395
396 kfree(ucode);
397 kfree(gpr_b);
398 kfree(gpr_a);
399
400 return !!(i == 100);
401}
402
403int ixp2000_uengine_load(int uengine, struct ixp2000_uengine_code *c)
404{
405 int ctx;
406
407 if (!check_ixp_type(c))
408 return 1;
409
410 if (!(ixp2000_uengine_mask & (1 << uengine)))
411 return 1;
412
413 ixp2000_uengine_reset(1 << uengine);
414 ixp2000_uengine_set_mode(uengine, c->uengine_parameters);
415 if (set_initial_registers(uengine, c))
416 return 1;
417 ixp2000_uengine_load_microcode(uengine, c->insns, c->num_insns);
418
419 for (ctx = 0; ctx < 8; ctx++)
420 ixp2000_uengine_init_context(uengine, ctx, 0);
421
422 return 0;
423}
424EXPORT_SYMBOL(ixp2000_uengine_load);
425
426
427static int __init ixp2000_uengine_init(void)
428{
429 int uengine;
430 u32 value;
431
432 /*
433 * Determine number of microengines present.
434 */
435 switch ((ixp2000_reg_read(IXP2000_PRODUCT_ID) >> 8) & 0x1fff) {
436 case 0: /* IXP2800 */
437 case 1: /* IXP2850 */
438 ixp2000_uengine_mask = 0x00ff00ff;
439 break;
440
441 case 2: /* IXP2400 */
442 ixp2000_uengine_mask = 0x000f000f;
443 break;
444
445 default:
446 printk(KERN_INFO "Detected unknown IXP2000 model (%.8x)\n",
447 (unsigned int)ixp2000_reg_read(IXP2000_PRODUCT_ID));
448 ixp2000_uengine_mask = 0x00000000;
449 break;
450 }
451
452 /*
453 * Reset microengines.
454 */
455 ixp2000_reg_write(IXP2000_RESET1, ixp2000_uengine_mask);
456 ixp2000_reg_write(IXP2000_RESET1, 0);
457
458 /*
459 * Synchronise timestamp counters across all microengines.
460 */
461 value = ixp2000_reg_read(IXP2000_MISC_CONTROL);
462 ixp2000_reg_write(IXP2000_MISC_CONTROL, value & ~0x80);
463 for (uengine = 0; uengine < 32; uengine++) {
464 if (ixp2000_uengine_mask & (1 << uengine)) {
465 ixp2000_uengine_csr_write(uengine, TIMESTAMP_LOW, 0);
466 ixp2000_uengine_csr_write(uengine, TIMESTAMP_HIGH, 0);
467 }
468 }
469 ixp2000_reg_write(IXP2000_MISC_CONTROL, value | 0x80);
470
471 return 0;
472}
473
474subsys_initcall(ixp2000_uengine_init);