| blob | 2d2f5aa5c500585f8c8e60287972ed17ed7bfcc7 |
1 /*
2 * Copyright (C) 2024 Mikulas Patocka
3 *
4 * This file is part of Ajla.
5 *
6 * Ajla is free software: you can redistribute it and/or modify it under the
7 * terms of the GNU General Public License as published by the Free Software
8 * Foundation, either version 3 of the License, or (at your option) any later
9 * version.
10 *
11 * Ajla is distributed in the hope that it will be useful, but WITHOUT ANY
12 * WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
13 * A PARTICULAR PURPOSE. See the GNU General Public License for more details.
14 *
15 * You should have received a copy of the GNU General Public License along with
16 * Ajla. If not, see <https://www.gnu.org/licenses/>.
17 */
19 #define OP_SIZE_NATIVE OP_SIZE_8
20 #define OP_SIZE_ADDRESS OP_SIZE_8
22 #define JMP_LIMIT JMP_LONG
24 #define UNALIGNED_TRAP 0
26 #define ALU_WRITES_FLAGS(alu, im) 0
27 #define ALU1_WRITES_FLAGS(alu) 0
28 #define ROT_WRITES_FLAGS(alu, size, im) 0
29 #define COND_IS_LOGICAL(cond) 0
31 #define ARCH_PARTIAL_ALU(size) 0
32 #define ARCH_IS_3ADDRESS(alu, f) 1
33 #define ARCH_IS_3ADDRESS_IMM(alu, f) 1
34 #define ARCH_IS_3ADDRESS_ROT(alu, size) 1
35 #define ARCH_IS_3ADDRESS_ROT_IMM(alu) 1
36 #define ARCH_IS_2ADDRESS(alu) 1
37 #define ARCH_IS_3ADDRESS_FP 1
38 #define ARCH_HAS_JMP_2REGS(cond) 0
39 #define ARCH_HAS_FLAGS 1
40 #define ARCH_PREFERS_SX(size) 0
41 #define ARCH_HAS_BWX 1
42 #define ARCH_HAS_MUL 1
43 #define ARCH_HAS_DIV 1
44 #define ARCH_HAS_ANDN 1
45 #define ARCH_HAS_SHIFTED_ADD(bits) 1
46 #define ARCH_HAS_BTX(btx, size, cnst) 0
47 #define ARCH_SHIFT_SIZE OP_SIZE_4
48 #define ARCH_BOOL_SIZE OP_SIZE_4
49 #define ARCH_HAS_FP_GP_MOV 1
50 #define ARCH_NEEDS_BARRIER 0
52 #define i_size(size) maximum(size, OP_SIZE_4)
53 #define i_size_rot(size) maximum(size, OP_SIZE_4)
54 #define i_size_cmp(size) maximum(size, OP_SIZE_4)
56 #define R_0 0x00
57 #define R_1 0x01
58 #define R_2 0x02
59 #define R_3 0x03
60 #define R_4 0x04
61 #define R_5 0x05
62 #define R_6 0x06
63 #define R_7 0x07
64 #define R_8 0x08
65 #define R_9 0x09
66 #define R_10 0x0a
67 #define R_11 0x0b
68 #define R_12 0x0c
69 #define R_13 0x0d
70 #define R_14 0x0e
71 #define R_15 0x0f
72 #define R_16 0x10
73 #define R_17 0x11
74 #define R_18 0x12
75 #define R_19 0x13
76 #define R_20 0x14
77 #define R_21 0x15
78 #define R_22 0x16
79 #define R_23 0x17
80 #define R_24 0x18
81 #define R_25 0x19
82 #define R_26 0x1a
83 #define R_27 0x1b
84 #define R_28 0x1c
85 #define R_FP 0x1d
86 #define R_LR 0x1e
87 #define R_SP 0x1f
89 #define FR_0 0x20
90 #define FR_1 0x21
91 #define FR_2 0x22
92 #define FR_3 0x23
93 #define FR_4 0x24
94 #define FR_5 0x25
95 #define FR_6 0x26
96 #define FR_7 0x27
97 #define FR_8 0x28
98 #define FR_9 0x29
99 #define FR_10 0x2a
100 #define FR_11 0x2b
101 #define FR_12 0x2c
102 #define FR_13 0x2d
103 #define FR_14 0x2e
104 #define FR_15 0x2f
105 #define FR_16 0x30
106 #define FR_17 0x31
107 #define FR_18 0x32
108 #define FR_19 0x33
109 #define FR_20 0x34
110 #define FR_21 0x35
111 #define FR_22 0x36
112 #define FR_23 0x37
113 #define FR_24 0x38
114 #define FR_25 0x39
115 #define FR_26 0x3a
116 #define FR_27 0x3b
117 #define FR_28 0x3c
118 #define FR_29 0x3d
119 #define FR_30 0x3e
120 #define FR_31 0x3f
122 #define FRAME_SIZE 0x60
124 #define R_FRAME R_28
125 #define R_UPCALL R_27
126 #define R_TIMESTAMP R_26
127 #define R_SAVED_1 R_25
128 #define R_SAVED_2 R_24
129 #define R_SAVED_3 R_23
130 #define R_SAVED_4 R_22
131 #define R_SAVED_5 R_21
132 #define R_SAVED_6 R_20
133 #define R_SAVED_7 R_19
135 #define R_SCRATCH_1 R_0
136 #define R_SCRATCH_2 R_1
137 #define R_SCRATCH_3 R_2
138 #define R_SCRATCH_4 R_3
139 #define R_SCRATCH_NA_1 R_8
140 #define R_SCRATCH_NA_2 R_9
141 #ifdef HAVE_BITWISE_FRAME
142 #define R_SCRATCH_NA_3 R_10
143 #endif
144 #define R_OFFSET_IMM R_16
145 #define R_CONST_IMM R_17
147 #define R_ARG0 R_0
148 #define R_ARG1 R_1
149 #define R_ARG2 R_2
150 #define R_ARG3 R_3
151 #define R_RET0 R_0
152 #define R_RET1 R_1
154 #define FR_SCRATCH_1 FR_0
155 #define FR_SCRATCH_2 FR_1
157 #define SUPPORTED_FP 0x6
158 #define SUPPORTED_FP_HALF_CVT 0x1
160 static bool reg_is_fp(unsigned reg)
161 {
162 return reg >= 0x20 && reg < 0x40;
163 }
165 static const uint8_t regs_saved[] = { R_SAVED_7, R_SAVED_6, R_SAVED_5, R_SAVED_4, R_SAVED_3 };
166 static const uint8_t regs_volatile[] = { R_4, R_5, R_6, R_7,
167 #ifndef HAVE_BITWISE_FRAME
168 R_10,
169 #endif
170 R_11, R_12, R_13, R_14, R_15, R_LR };
171 static const uint8_t fp_saved[] = { 0 };
172 #define n_fp_saved 0U
173 static const uint8_t fp_volatile[] = { FR_2, FR_3, FR_4, FR_5, FR_6, FR_7, FR_16, FR_17, FR_18, FR_19, FR_20, FR_21, FR_22, FR_23, FR_24, FR_25, FR_26, FR_27, FR_28, FR_29, FR_30, FR_31 };
174 #define reg_is_saved(r) ((r) >= R_19 && (r) <= R_FP)
176 struct logical_imm {
177 uint64_t value;
178 uint16_t code;
179 };
181 static const struct logical_imm value_to_code_4_table[] = {
182 #include "arm64-w.inc"
183 };
185 static const struct logical_imm value_to_code_8_table[] = {
186 #include "arm64-x.inc"
187 };
189 static int16_t value_to_code(uint8_t size, uint64_t value)
190 {
191 size_t result;
192 if (size == OP_SIZE_4) {
193 binary_search(size_t, n_array_elements(value_to_code_4_table), result, value_to_code_4_table[result].value == value, value_to_code_4_table[result].value < value, return -1);
194 return value_to_code_4_table[result].code;
195 } else {
196 binary_search(size_t, n_array_elements(value_to_code_8_table), result, value_to_code_8_table[result].value == value, value_to_code_8_table[result].value < value, return -1);
197 return value_to_code_8_table[result].code;
198 }
199 }
201 static bool attr_w gen_load_constant(struct codegen_context *ctx, unsigned reg, uint64_t c)
202 {
203 int16_t code;
205 if (c < 0x10000)
206 goto skip_lookup;
208 code = value_to_code(OP_SIZE_4, c);
209 if (code >= 0) {
210 gen_insn(INSN_ALU, OP_SIZE_4, ALU_OR, 0);
211 gen_one(reg);
212 gen_one(0x1f);
213 gen_one(ARG_IMM);
214 gen_eight(c);
215 return true;
216 }
218 code = value_to_code(OP_SIZE_8, c);
219 if (code >= 0) {
220 gen_insn(INSN_ALU, OP_SIZE_8, ALU_OR, 0);
221 gen_one(reg);
222 gen_one(0x1f);
223 gen_one(ARG_IMM);
224 gen_eight(c);
225 return true;
226 }
228 skip_lookup:
229 if ((int64_t)c < 0) {
230 gen_insn(INSN_MOV, OP_SIZE_8, 0, 0);
231 gen_one(reg);
232 gen_one(ARG_IMM);
233 gen_eight((c & 0xffff) | 0xffffffffffff0000ULL);
234 if ((c & 0xffff0000ULL) != 0xffff0000ULL) {
235 gen_insn(INSN_MOV_MASK, OP_SIZE_8, MOV_MASK_16_32, 0);
236 gen_one(reg);
237 gen_one(reg);
238 gen_one(ARG_IMM);
239 gen_eight((c >> 16) & 0xffff);
240 }
241 if ((c & 0xffff00000000ULL) != 0xffff00000000ULL) {
242 gen_insn(INSN_MOV_MASK, OP_SIZE_8, MOV_MASK_32_48, 0);
243 gen_one(reg);
244 gen_one(reg);
245 gen_one(ARG_IMM);
246 gen_eight((c >> 32) & 0xffff);
247 }
248 if ((c & 0xffff000000000000ULL) != 0xffff000000000000ULL) {
249 gen_insn(INSN_MOV_MASK, OP_SIZE_8, MOV_MASK_48_64, 0);
250 gen_one(reg);
251 gen_one(reg);
252 gen_one(ARG_IMM);
253 gen_eight((c >> 48) & 0xffff);
254 }
255 } else {
256 gen_insn(INSN_MOV, OP_SIZE_8, 0, 0);
257 gen_one(reg);
258 gen_one(ARG_IMM);
259 gen_eight(c & 0xffff);
260 if (c & 0xffff0000ULL) {
261 gen_insn(INSN_MOV_MASK, OP_SIZE_8, MOV_MASK_16_32, 0);
262 gen_one(reg);
263 gen_one(reg);
264 gen_one(ARG_IMM);
265 gen_eight((c >> 16) & 0xffff);
266 }
267 if (c & 0xffff00000000ULL) {
268 gen_insn(INSN_MOV_MASK, OP_SIZE_8, MOV_MASK_32_48, 0);
269 gen_one(reg);
270 gen_one(reg);
271 gen_one(ARG_IMM);
272 gen_eight((c >> 32) & 0xffff);
273 }
274 if (c & 0xffff000000000000ULL) {
275 gen_insn(INSN_MOV_MASK, OP_SIZE_8, MOV_MASK_48_64, 0);
276 gen_one(reg);
277 gen_one(reg);
278 gen_one(ARG_IMM);
279 gen_eight((c >> 48) & 0xffff);
280 }
281 }
282 return true;
283 }
285 static bool attr_w gen_address(struct codegen_context *ctx, unsigned base, int64_t imm, unsigned purpose, unsigned size)
286 {
287 ctx->base_reg = base;
288 ctx->offset_imm = imm;
289 ctx->offset_reg = false;
290 switch (purpose) {
291 case IMM_PURPOSE_LDR_OFFSET:
292 case IMM_PURPOSE_LDR_SX_OFFSET:
293 case IMM_PURPOSE_STR_OFFSET:
294 case IMM_PURPOSE_VLDR_VSTR_OFFSET:
295 case IMM_PURPOSE_MVI_CLI_OFFSET:
296 if (likely(imm >= -256) && likely(imm <= 255))
297 return true;
298 if (likely(imm >= 0)) {
299 if (unlikely((imm & ((1 << size) - 1)) != 0))
300 break;
301 if (likely((imm >> size) <= 4095))
302 return true;
303 }
304 break;
305 case IMM_PURPOSE_LDP_STP_OFFSET:
306 if (unlikely((imm & ((1 << size) - 1)) != 0))
307 break;
308 if (imm / (1 << size) >= -64 && imm / (1 << size) <= 63)
309 return true;
310 break;
311 default:
312 internal(file_line, "gen_address: invalid purpose %d", purpose);
313 }
314 g(gen_load_constant(ctx, R_OFFSET_IMM, imm));
315 if (purpose == IMM_PURPOSE_LDP_STP_OFFSET) {
316 gen_insn(INSN_ALU, OP_SIZE_ADDRESS, ALU_ADD, 0);
317 gen_one(R_OFFSET_IMM);
318 gen_one(R_OFFSET_IMM);
319 gen_one(base);
320 ctx->base_reg = R_OFFSET_IMM;
321 ctx->offset_imm = 0;
322 return true;
323 }
324 ctx->offset_reg = true;
325 return true;
327 }
329 static bool is_direct_const(int64_t imm, unsigned purpose, unsigned size)
330 {
331 switch (purpose) {
332 case IMM_PURPOSE_STORE_VALUE:
333 if (!imm)
334 return true;
335 break;
336 case IMM_PURPOSE_ADD:
337 case IMM_PURPOSE_SUB:
338 case IMM_PURPOSE_CMP:
339 case IMM_PURPOSE_CMP_LOGICAL:
340 if (imm >= 0 && imm < 4096)
341 return true;
342 break;
343 case IMM_PURPOSE_AND:
344 case IMM_PURPOSE_OR:
345 case IMM_PURPOSE_XOR:
346 case IMM_PURPOSE_ANDN:
347 case IMM_PURPOSE_TEST:
348 if (value_to_code(size, imm) >= 0)
349 return true;
350 break;
351 case IMM_PURPOSE_MUL:
352 break;
353 default:
354 internal(file_line, "is_direct_const: invalid purpose %u (imm %"PRIxMAX", size %u)", purpose, (uintmax_t)imm, size);
355 }
356 return false;
357 }
359 static bool attr_w gen_imm(struct codegen_context *ctx, int64_t imm, unsigned purpose, unsigned size)
360 {
361 if (is_direct_const(imm, purpose, size)) {
362 ctx->const_imm = imm;
363 ctx->const_reg = false;
364 } else {
365 g(gen_load_constant(ctx, R_CONST_IMM, imm));
366 ctx->const_reg = true;
367 }
368 return true;
369 }
371 static bool attr_w gen_entry(struct codegen_context *ctx)
372 {
373 gen_insn(INSN_STP, OP_SIZE_8, 0, 0);
374 gen_one(ARG_ADDRESS_1_PRE_I);
375 gen_one(R_SP);
376 gen_eight(-FRAME_SIZE);
377 gen_one(R_FP);
378 gen_one(R_LR);
380 gen_insn(INSN_MOV, OP_SIZE_8, 0, 0);
381 gen_one(R_FP);
382 gen_one(R_SP);
384 gen_insn(INSN_STP, OP_SIZE_8, 0, 0);
385 gen_one(ARG_ADDRESS_1);
386 gen_one(R_SP);
387 gen_eight(0x10);
388 gen_one(R_UPCALL);
389 gen_one(R_FRAME);
391 gen_insn(INSN_STP, OP_SIZE_8, 0, 0);
392 gen_one(ARG_ADDRESS_1);
393 gen_one(R_SP);
394 gen_eight(0x20);
395 gen_one(R_SAVED_1);
396 gen_one(R_TIMESTAMP);
398 gen_insn(INSN_STP, OP_SIZE_8, 0, 0);
399 gen_one(ARG_ADDRESS_1);
400 gen_one(R_SP);
401 gen_eight(0x30);
402 gen_one(R_SAVED_3);
403 gen_one(R_SAVED_2);
405 gen_insn(INSN_STP, OP_SIZE_8, 0, 0);
406 gen_one(ARG_ADDRESS_1);
407 gen_one(R_SP);
408 gen_eight(0x40);
409 gen_one(R_SAVED_5);
410 gen_one(R_SAVED_4);
412 gen_insn(INSN_STP, OP_SIZE_8, 0, 0);
413 gen_one(ARG_ADDRESS_1);
414 gen_one(R_SP);
415 gen_eight(0x50);
416 gen_one(R_SAVED_7);
417 gen_one(R_SAVED_6);
419 gen_insn(INSN_MOV, OP_SIZE_8, 0, 0);
420 gen_one(R_FRAME);
421 gen_one(R_ARG0);
423 gen_insn(INSN_MOV, OP_SIZE_8, 0, 0);
424 gen_one(R_UPCALL);
425 gen_one(R_ARG1);
427 gen_insn(INSN_MOV, OP_SIZE_8, 0, 0);
428 gen_one(R_TIMESTAMP);
429 gen_one(R_ARG2);
431 gen_insn(INSN_JMP_INDIRECT, 0, 0, 0);
432 gen_one(R_ARG3);
434 return true;
435 }
437 static bool attr_w gen_escape_arg(struct codegen_context *ctx, ip_t ip, uint32_t escape_label)
438 {
439 g(gen_load_constant(ctx, R_RET1, ip));
441 gen_insn(INSN_JMP, 0, 0, 0);
442 gen_four(escape_label);
444 return true;
445 }
447 static bool attr_w gen_escape(struct codegen_context *ctx)
448 {
449 gen_insn(INSN_MOV, OP_SIZE_8, 0, 0);
450 gen_one(R_RET0);
451 gen_one(R_FRAME);
453 gen_insn(INSN_LDP, OP_SIZE_8, 0, 0);
454 gen_one(R_SAVED_7);
455 gen_one(R_SAVED_6);
456 gen_one(ARG_ADDRESS_1);
457 gen_one(R_SP);
458 gen_eight(0x50);
460 gen_insn(INSN_LDP, OP_SIZE_8, 0, 0);
461 gen_one(R_SAVED_5);
462 gen_one(R_SAVED_4);
463 gen_one(ARG_ADDRESS_1);
464 gen_one(R_SP);
465 gen_eight(0x40);
467 gen_insn(INSN_LDP, OP_SIZE_8, 0, 0);
468 gen_one(R_SAVED_3);
469 gen_one(R_SAVED_2);
470 gen_one(ARG_ADDRESS_1);
471 gen_one(R_SP);
472 gen_eight(0x30);
474 gen_insn(INSN_LDP, OP_SIZE_8, 0, 0);
475 gen_one(R_SAVED_1);
476 gen_one(R_TIMESTAMP);
477 gen_one(ARG_ADDRESS_1);
478 gen_one(R_SP);
479 gen_eight(0x20);
481 gen_insn(INSN_LDP, OP_SIZE_8, 0, 0);
482 gen_one(R_UPCALL);
483 gen_one(R_FRAME);
484 gen_one(ARG_ADDRESS_1);
485 gen_one(R_SP);
486 gen_eight(0x10);
488 gen_insn(INSN_LDP, OP_SIZE_8, 0, 0);
489 gen_one(R_FP);
490 gen_one(R_LR);
491 gen_one(ARG_ADDRESS_1_POST_I);
492 gen_one(R_SP);
493 gen_eight(FRAME_SIZE);
495 gen_insn(INSN_RET, 0, 0, 0);
497 return true;
498 }
500 static bool attr_w gen_upcall_argument(struct codegen_context attr_unused *ctx, unsigned attr_unused arg)
501 {
502 return true;
503 }
505 static bool attr_w gen_upcall(struct codegen_context *ctx, unsigned offset, unsigned n_args)
506 {
507 g(gen_address(ctx, R_UPCALL, offset, IMM_PURPOSE_LDR_OFFSET, OP_SIZE_8));
508 gen_insn(INSN_MOV, OP_SIZE_8, 0, 0);
509 gen_one(R_SCRATCH_NA_1);
510 gen_address_offset();
512 gen_insn(INSN_CALL_INDIRECT, OP_SIZE_8, 0, 0);
513 gen_one(R_SCRATCH_NA_1);
515 g(gen_upcall_end(ctx, n_args));
517 return true;
518 }
520 static bool attr_w gen_timestamp_test(struct codegen_context *ctx, uint32_t escape_label)
521 {
522 g(gen_address(ctx, R_UPCALL, offsetof(struct cg_upcall_vector_s, ts), IMM_PURPOSE_LDR_OFFSET, OP_SIZE_4));
523 gen_insn(INSN_MOV, OP_SIZE_4, 0, 0);
524 gen_one(R_SCRATCH_1);
525 gen_address_offset();
527 gen_insn(INSN_CMP, OP_SIZE_4, 0, 1);
528 gen_one(R_SCRATCH_1);
529 gen_one(R_TIMESTAMP);
531 gen_insn(INSN_JMP_COND, OP_SIZE_4, COND_NE, 0);
532 gen_four(escape_label);
534 return true;
535 }