1 /* 2 * Copyright (C) 2016-2018 Netronome Systems, Inc. 3 * 4 * This software is dual licensed under the GNU General License Version 2, 5 * June 1991 as shown in the file COPYING in the top-level directory of this 6 * source tree or the BSD 2-Clause License provided below. You have the 7 * option to license this software under the complete terms of either license. 8 * 9 * The BSD 2-Clause License: 10 * 11 * Redistribution and use in source and binary forms, with or 12 * without modification, are permitted provided that the following 13 * conditions are met: 14 * 15 * 1. Redistributions of source code must retain the above 16 * copyright notice, this list of conditions and the following 17 * disclaimer. 18 * 19 * 2. Redistributions in binary form must reproduce the above 20 * copyright notice, this list of conditions and the following 21 * disclaimer in the documentation and/or other materials 22 * provided with the distribution. 23 * 24 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, 25 * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF 26 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND 27 * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS 28 * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN 29 * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN 30 * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE 31 * SOFTWARE. 32 */ 33 34 #define pr_fmt(fmt) "NFP net bpf: " fmt 35 36 #include <linux/bug.h> 37 #include <linux/bpf.h> 38 #include <linux/filter.h> 39 #include <linux/kernel.h> 40 #include <linux/pkt_cls.h> 41 #include <linux/reciprocal_div.h> 42 #include <linux/unistd.h> 43 44 #include "main.h" 45 #include "../nfp_asm.h" 46 #include "../nfp_net_ctrl.h" 47 48 /* --- NFP prog --- */ 49 /* Foreach "multiple" entries macros provide pos and next<n> pointers. 50 * It's safe to modify the next pointers (but not pos). 51 */ 52 #define nfp_for_each_insn_walk2(nfp_prog, pos, next) \ 53 for (pos = list_first_entry(&(nfp_prog)->insns, typeof(*pos), l), \ 54 next = list_next_entry(pos, l); \ 55 &(nfp_prog)->insns != &pos->l && \ 56 &(nfp_prog)->insns != &next->l; \ 57 pos = nfp_meta_next(pos), \ 58 next = nfp_meta_next(pos)) 59 60 #define nfp_for_each_insn_walk3(nfp_prog, pos, next, next2) \ 61 for (pos = list_first_entry(&(nfp_prog)->insns, typeof(*pos), l), \ 62 next = list_next_entry(pos, l), \ 63 next2 = list_next_entry(next, l); \ 64 &(nfp_prog)->insns != &pos->l && \ 65 &(nfp_prog)->insns != &next->l && \ 66 &(nfp_prog)->insns != &next2->l; \ 67 pos = nfp_meta_next(pos), \ 68 next = nfp_meta_next(pos), \ 69 next2 = nfp_meta_next(next)) 70 71 static bool 72 nfp_meta_has_prev(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 73 { 74 return meta->l.prev != &nfp_prog->insns; 75 } 76 77 static void nfp_prog_push(struct nfp_prog *nfp_prog, u64 insn) 78 { 79 if (nfp_prog->__prog_alloc_len / sizeof(u64) == nfp_prog->prog_len) { 80 pr_warn("instruction limit reached (%u NFP instructions)\n", 81 nfp_prog->prog_len); 82 nfp_prog->error = -ENOSPC; 83 return; 84 } 85 86 nfp_prog->prog[nfp_prog->prog_len] = insn; 87 nfp_prog->prog_len++; 88 } 89 90 static unsigned int nfp_prog_current_offset(struct nfp_prog *nfp_prog) 91 { 92 return nfp_prog->prog_len; 93 } 94 95 static bool 96 nfp_prog_confirm_current_offset(struct nfp_prog *nfp_prog, unsigned int off) 97 { 98 /* If there is a recorded error we may have dropped instructions; 99 * that doesn't have to be due to translator bug, and the translation 100 * will fail anyway, so just return OK. 101 */ 102 if (nfp_prog->error) 103 return true; 104 return !WARN_ON_ONCE(nfp_prog_current_offset(nfp_prog) != off); 105 } 106 107 /* --- Emitters --- */ 108 static void 109 __emit_cmd(struct nfp_prog *nfp_prog, enum cmd_tgt_map op, 110 u8 mode, u8 xfer, u8 areg, u8 breg, u8 size, enum cmd_ctx_swap ctx, 111 bool indir) 112 { 113 u64 insn; 114 115 insn = FIELD_PREP(OP_CMD_A_SRC, areg) | 116 FIELD_PREP(OP_CMD_CTX, ctx) | 117 FIELD_PREP(OP_CMD_B_SRC, breg) | 118 FIELD_PREP(OP_CMD_TOKEN, cmd_tgt_act[op].token) | 119 FIELD_PREP(OP_CMD_XFER, xfer) | 120 FIELD_PREP(OP_CMD_CNT, size) | 121 FIELD_PREP(OP_CMD_SIG, ctx != CMD_CTX_NO_SWAP) | 122 FIELD_PREP(OP_CMD_TGT_CMD, cmd_tgt_act[op].tgt_cmd) | 123 FIELD_PREP(OP_CMD_INDIR, indir) | 124 FIELD_PREP(OP_CMD_MODE, mode); 125 126 nfp_prog_push(nfp_prog, insn); 127 } 128 129 static void 130 emit_cmd_any(struct nfp_prog *nfp_prog, enum cmd_tgt_map op, u8 mode, u8 xfer, 131 swreg lreg, swreg rreg, u8 size, enum cmd_ctx_swap ctx, bool indir) 132 { 133 struct nfp_insn_re_regs reg; 134 int err; 135 136 err = swreg_to_restricted(reg_none(), lreg, rreg, ®, false); 137 if (err) { 138 nfp_prog->error = err; 139 return; 140 } 141 if (reg.swap) { 142 pr_err("cmd can't swap arguments\n"); 143 nfp_prog->error = -EFAULT; 144 return; 145 } 146 if (reg.dst_lmextn || reg.src_lmextn) { 147 pr_err("cmd can't use LMextn\n"); 148 nfp_prog->error = -EFAULT; 149 return; 150 } 151 152 __emit_cmd(nfp_prog, op, mode, xfer, reg.areg, reg.breg, size, ctx, 153 indir); 154 } 155 156 static void 157 emit_cmd(struct nfp_prog *nfp_prog, enum cmd_tgt_map op, u8 mode, u8 xfer, 158 swreg lreg, swreg rreg, u8 size, enum cmd_ctx_swap ctx) 159 { 160 emit_cmd_any(nfp_prog, op, mode, xfer, lreg, rreg, size, ctx, false); 161 } 162 163 static void 164 emit_cmd_indir(struct nfp_prog *nfp_prog, enum cmd_tgt_map op, u8 mode, u8 xfer, 165 swreg lreg, swreg rreg, u8 size, enum cmd_ctx_swap ctx) 166 { 167 emit_cmd_any(nfp_prog, op, mode, xfer, lreg, rreg, size, ctx, true); 168 } 169 170 static void 171 __emit_br(struct nfp_prog *nfp_prog, enum br_mask mask, enum br_ev_pip ev_pip, 172 enum br_ctx_signal_state css, u16 addr, u8 defer) 173 { 174 u16 addr_lo, addr_hi; 175 u64 insn; 176 177 addr_lo = addr & (OP_BR_ADDR_LO >> __bf_shf(OP_BR_ADDR_LO)); 178 addr_hi = addr != addr_lo; 179 180 insn = OP_BR_BASE | 181 FIELD_PREP(OP_BR_MASK, mask) | 182 FIELD_PREP(OP_BR_EV_PIP, ev_pip) | 183 FIELD_PREP(OP_BR_CSS, css) | 184 FIELD_PREP(OP_BR_DEFBR, defer) | 185 FIELD_PREP(OP_BR_ADDR_LO, addr_lo) | 186 FIELD_PREP(OP_BR_ADDR_HI, addr_hi); 187 188 nfp_prog_push(nfp_prog, insn); 189 } 190 191 static void 192 emit_br_relo(struct nfp_prog *nfp_prog, enum br_mask mask, u16 addr, u8 defer, 193 enum nfp_relo_type relo) 194 { 195 if (mask == BR_UNC && defer > 2) { 196 pr_err("BUG: branch defer out of bounds %d\n", defer); 197 nfp_prog->error = -EFAULT; 198 return; 199 } 200 201 __emit_br(nfp_prog, mask, 202 mask != BR_UNC ? BR_EV_PIP_COND : BR_EV_PIP_UNCOND, 203 BR_CSS_NONE, addr, defer); 204 205 nfp_prog->prog[nfp_prog->prog_len - 1] |= 206 FIELD_PREP(OP_RELO_TYPE, relo); 207 } 208 209 static void 210 emit_br(struct nfp_prog *nfp_prog, enum br_mask mask, u16 addr, u8 defer) 211 { 212 emit_br_relo(nfp_prog, mask, addr, defer, RELO_BR_REL); 213 } 214 215 static void 216 __emit_br_bit(struct nfp_prog *nfp_prog, u16 areg, u16 breg, u16 addr, u8 defer, 217 bool set, bool src_lmextn) 218 { 219 u16 addr_lo, addr_hi; 220 u64 insn; 221 222 addr_lo = addr & (OP_BR_BIT_ADDR_LO >> __bf_shf(OP_BR_BIT_ADDR_LO)); 223 addr_hi = addr != addr_lo; 224 225 insn = OP_BR_BIT_BASE | 226 FIELD_PREP(OP_BR_BIT_A_SRC, areg) | 227 FIELD_PREP(OP_BR_BIT_B_SRC, breg) | 228 FIELD_PREP(OP_BR_BIT_BV, set) | 229 FIELD_PREP(OP_BR_BIT_DEFBR, defer) | 230 FIELD_PREP(OP_BR_BIT_ADDR_LO, addr_lo) | 231 FIELD_PREP(OP_BR_BIT_ADDR_HI, addr_hi) | 232 FIELD_PREP(OP_BR_BIT_SRC_LMEXTN, src_lmextn); 233 234 nfp_prog_push(nfp_prog, insn); 235 } 236 237 static void 238 emit_br_bit_relo(struct nfp_prog *nfp_prog, swreg src, u8 bit, u16 addr, 239 u8 defer, bool set, enum nfp_relo_type relo) 240 { 241 struct nfp_insn_re_regs reg; 242 int err; 243 244 /* NOTE: The bit to test is specified as an rotation amount, such that 245 * the bit to test will be placed on the MSB of the result when 246 * doing a rotate right. For bit X, we need right rotate X + 1. 247 */ 248 bit += 1; 249 250 err = swreg_to_restricted(reg_none(), src, reg_imm(bit), ®, false); 251 if (err) { 252 nfp_prog->error = err; 253 return; 254 } 255 256 __emit_br_bit(nfp_prog, reg.areg, reg.breg, addr, defer, set, 257 reg.src_lmextn); 258 259 nfp_prog->prog[nfp_prog->prog_len - 1] |= 260 FIELD_PREP(OP_RELO_TYPE, relo); 261 } 262 263 static void 264 emit_br_bset(struct nfp_prog *nfp_prog, swreg src, u8 bit, u16 addr, u8 defer) 265 { 266 emit_br_bit_relo(nfp_prog, src, bit, addr, defer, true, RELO_BR_REL); 267 } 268 269 static void 270 __emit_br_alu(struct nfp_prog *nfp_prog, u16 areg, u16 breg, u16 imm_hi, 271 u8 defer, bool dst_lmextn, bool src_lmextn) 272 { 273 u64 insn; 274 275 insn = OP_BR_ALU_BASE | 276 FIELD_PREP(OP_BR_ALU_A_SRC, areg) | 277 FIELD_PREP(OP_BR_ALU_B_SRC, breg) | 278 FIELD_PREP(OP_BR_ALU_DEFBR, defer) | 279 FIELD_PREP(OP_BR_ALU_IMM_HI, imm_hi) | 280 FIELD_PREP(OP_BR_ALU_SRC_LMEXTN, src_lmextn) | 281 FIELD_PREP(OP_BR_ALU_DST_LMEXTN, dst_lmextn); 282 283 nfp_prog_push(nfp_prog, insn); 284 } 285 286 static void emit_rtn(struct nfp_prog *nfp_prog, swreg base, u8 defer) 287 { 288 struct nfp_insn_ur_regs reg; 289 int err; 290 291 err = swreg_to_unrestricted(reg_none(), base, reg_imm(0), ®); 292 if (err) { 293 nfp_prog->error = err; 294 return; 295 } 296 297 __emit_br_alu(nfp_prog, reg.areg, reg.breg, 0, defer, reg.dst_lmextn, 298 reg.src_lmextn); 299 } 300 301 static void 302 __emit_immed(struct nfp_prog *nfp_prog, u16 areg, u16 breg, u16 imm_hi, 303 enum immed_width width, bool invert, 304 enum immed_shift shift, bool wr_both, 305 bool dst_lmextn, bool src_lmextn) 306 { 307 u64 insn; 308 309 insn = OP_IMMED_BASE | 310 FIELD_PREP(OP_IMMED_A_SRC, areg) | 311 FIELD_PREP(OP_IMMED_B_SRC, breg) | 312 FIELD_PREP(OP_IMMED_IMM, imm_hi) | 313 FIELD_PREP(OP_IMMED_WIDTH, width) | 314 FIELD_PREP(OP_IMMED_INV, invert) | 315 FIELD_PREP(OP_IMMED_SHIFT, shift) | 316 FIELD_PREP(OP_IMMED_WR_AB, wr_both) | 317 FIELD_PREP(OP_IMMED_SRC_LMEXTN, src_lmextn) | 318 FIELD_PREP(OP_IMMED_DST_LMEXTN, dst_lmextn); 319 320 nfp_prog_push(nfp_prog, insn); 321 } 322 323 static void 324 emit_immed(struct nfp_prog *nfp_prog, swreg dst, u16 imm, 325 enum immed_width width, bool invert, enum immed_shift shift) 326 { 327 struct nfp_insn_ur_regs reg; 328 int err; 329 330 if (swreg_type(dst) == NN_REG_IMM) { 331 nfp_prog->error = -EFAULT; 332 return; 333 } 334 335 err = swreg_to_unrestricted(dst, dst, reg_imm(imm & 0xff), ®); 336 if (err) { 337 nfp_prog->error = err; 338 return; 339 } 340 341 /* Use reg.dst when destination is No-Dest. */ 342 __emit_immed(nfp_prog, 343 swreg_type(dst) == NN_REG_NONE ? reg.dst : reg.areg, 344 reg.breg, imm >> 8, width, invert, shift, 345 reg.wr_both, reg.dst_lmextn, reg.src_lmextn); 346 } 347 348 static void 349 __emit_shf(struct nfp_prog *nfp_prog, u16 dst, enum alu_dst_ab dst_ab, 350 enum shf_sc sc, u8 shift, 351 u16 areg, enum shf_op op, u16 breg, bool i8, bool sw, bool wr_both, 352 bool dst_lmextn, bool src_lmextn) 353 { 354 u64 insn; 355 356 if (!FIELD_FIT(OP_SHF_SHIFT, shift)) { 357 nfp_prog->error = -EFAULT; 358 return; 359 } 360 361 if (sc == SHF_SC_L_SHF) 362 shift = 32 - shift; 363 364 insn = OP_SHF_BASE | 365 FIELD_PREP(OP_SHF_A_SRC, areg) | 366 FIELD_PREP(OP_SHF_SC, sc) | 367 FIELD_PREP(OP_SHF_B_SRC, breg) | 368 FIELD_PREP(OP_SHF_I8, i8) | 369 FIELD_PREP(OP_SHF_SW, sw) | 370 FIELD_PREP(OP_SHF_DST, dst) | 371 FIELD_PREP(OP_SHF_SHIFT, shift) | 372 FIELD_PREP(OP_SHF_OP, op) | 373 FIELD_PREP(OP_SHF_DST_AB, dst_ab) | 374 FIELD_PREP(OP_SHF_WR_AB, wr_both) | 375 FIELD_PREP(OP_SHF_SRC_LMEXTN, src_lmextn) | 376 FIELD_PREP(OP_SHF_DST_LMEXTN, dst_lmextn); 377 378 nfp_prog_push(nfp_prog, insn); 379 } 380 381 static void 382 emit_shf(struct nfp_prog *nfp_prog, swreg dst, 383 swreg lreg, enum shf_op op, swreg rreg, enum shf_sc sc, u8 shift) 384 { 385 struct nfp_insn_re_regs reg; 386 int err; 387 388 err = swreg_to_restricted(dst, lreg, rreg, ®, true); 389 if (err) { 390 nfp_prog->error = err; 391 return; 392 } 393 394 __emit_shf(nfp_prog, reg.dst, reg.dst_ab, sc, shift, 395 reg.areg, op, reg.breg, reg.i8, reg.swap, reg.wr_both, 396 reg.dst_lmextn, reg.src_lmextn); 397 } 398 399 static void 400 emit_shf_indir(struct nfp_prog *nfp_prog, swreg dst, 401 swreg lreg, enum shf_op op, swreg rreg, enum shf_sc sc) 402 { 403 if (sc == SHF_SC_R_ROT) { 404 pr_err("indirect shift is not allowed on rotation\n"); 405 nfp_prog->error = -EFAULT; 406 return; 407 } 408 409 emit_shf(nfp_prog, dst, lreg, op, rreg, sc, 0); 410 } 411 412 static void 413 __emit_alu(struct nfp_prog *nfp_prog, u16 dst, enum alu_dst_ab dst_ab, 414 u16 areg, enum alu_op op, u16 breg, bool swap, bool wr_both, 415 bool dst_lmextn, bool src_lmextn) 416 { 417 u64 insn; 418 419 insn = OP_ALU_BASE | 420 FIELD_PREP(OP_ALU_A_SRC, areg) | 421 FIELD_PREP(OP_ALU_B_SRC, breg) | 422 FIELD_PREP(OP_ALU_DST, dst) | 423 FIELD_PREP(OP_ALU_SW, swap) | 424 FIELD_PREP(OP_ALU_OP, op) | 425 FIELD_PREP(OP_ALU_DST_AB, dst_ab) | 426 FIELD_PREP(OP_ALU_WR_AB, wr_both) | 427 FIELD_PREP(OP_ALU_SRC_LMEXTN, src_lmextn) | 428 FIELD_PREP(OP_ALU_DST_LMEXTN, dst_lmextn); 429 430 nfp_prog_push(nfp_prog, insn); 431 } 432 433 static void 434 emit_alu(struct nfp_prog *nfp_prog, swreg dst, 435 swreg lreg, enum alu_op op, swreg rreg) 436 { 437 struct nfp_insn_ur_regs reg; 438 int err; 439 440 err = swreg_to_unrestricted(dst, lreg, rreg, ®); 441 if (err) { 442 nfp_prog->error = err; 443 return; 444 } 445 446 __emit_alu(nfp_prog, reg.dst, reg.dst_ab, 447 reg.areg, op, reg.breg, reg.swap, reg.wr_both, 448 reg.dst_lmextn, reg.src_lmextn); 449 } 450 451 static void 452 __emit_mul(struct nfp_prog *nfp_prog, enum alu_dst_ab dst_ab, u16 areg, 453 enum mul_type type, enum mul_step step, u16 breg, bool swap, 454 bool wr_both, bool dst_lmextn, bool src_lmextn) 455 { 456 u64 insn; 457 458 insn = OP_MUL_BASE | 459 FIELD_PREP(OP_MUL_A_SRC, areg) | 460 FIELD_PREP(OP_MUL_B_SRC, breg) | 461 FIELD_PREP(OP_MUL_STEP, step) | 462 FIELD_PREP(OP_MUL_DST_AB, dst_ab) | 463 FIELD_PREP(OP_MUL_SW, swap) | 464 FIELD_PREP(OP_MUL_TYPE, type) | 465 FIELD_PREP(OP_MUL_WR_AB, wr_both) | 466 FIELD_PREP(OP_MUL_SRC_LMEXTN, src_lmextn) | 467 FIELD_PREP(OP_MUL_DST_LMEXTN, dst_lmextn); 468 469 nfp_prog_push(nfp_prog, insn); 470 } 471 472 static void 473 emit_mul(struct nfp_prog *nfp_prog, swreg lreg, enum mul_type type, 474 enum mul_step step, swreg rreg) 475 { 476 struct nfp_insn_ur_regs reg; 477 u16 areg; 478 int err; 479 480 if (type == MUL_TYPE_START && step != MUL_STEP_NONE) { 481 nfp_prog->error = -EINVAL; 482 return; 483 } 484 485 if (step == MUL_LAST || step == MUL_LAST_2) { 486 /* When type is step and step Number is LAST or LAST2, left 487 * source is used as destination. 488 */ 489 err = swreg_to_unrestricted(lreg, reg_none(), rreg, ®); 490 areg = reg.dst; 491 } else { 492 err = swreg_to_unrestricted(reg_none(), lreg, rreg, ®); 493 areg = reg.areg; 494 } 495 496 if (err) { 497 nfp_prog->error = err; 498 return; 499 } 500 501 __emit_mul(nfp_prog, reg.dst_ab, areg, type, step, reg.breg, reg.swap, 502 reg.wr_both, reg.dst_lmextn, reg.src_lmextn); 503 } 504 505 static void 506 __emit_ld_field(struct nfp_prog *nfp_prog, enum shf_sc sc, 507 u8 areg, u8 bmask, u8 breg, u8 shift, bool imm8, 508 bool zero, bool swap, bool wr_both, 509 bool dst_lmextn, bool src_lmextn) 510 { 511 u64 insn; 512 513 insn = OP_LDF_BASE | 514 FIELD_PREP(OP_LDF_A_SRC, areg) | 515 FIELD_PREP(OP_LDF_SC, sc) | 516 FIELD_PREP(OP_LDF_B_SRC, breg) | 517 FIELD_PREP(OP_LDF_I8, imm8) | 518 FIELD_PREP(OP_LDF_SW, swap) | 519 FIELD_PREP(OP_LDF_ZF, zero) | 520 FIELD_PREP(OP_LDF_BMASK, bmask) | 521 FIELD_PREP(OP_LDF_SHF, shift) | 522 FIELD_PREP(OP_LDF_WR_AB, wr_both) | 523 FIELD_PREP(OP_LDF_SRC_LMEXTN, src_lmextn) | 524 FIELD_PREP(OP_LDF_DST_LMEXTN, dst_lmextn); 525 526 nfp_prog_push(nfp_prog, insn); 527 } 528 529 static void 530 emit_ld_field_any(struct nfp_prog *nfp_prog, swreg dst, u8 bmask, swreg src, 531 enum shf_sc sc, u8 shift, bool zero) 532 { 533 struct nfp_insn_re_regs reg; 534 int err; 535 536 /* Note: ld_field is special as it uses one of the src regs as dst */ 537 err = swreg_to_restricted(dst, dst, src, ®, true); 538 if (err) { 539 nfp_prog->error = err; 540 return; 541 } 542 543 __emit_ld_field(nfp_prog, sc, reg.areg, bmask, reg.breg, shift, 544 reg.i8, zero, reg.swap, reg.wr_both, 545 reg.dst_lmextn, reg.src_lmextn); 546 } 547 548 static void 549 emit_ld_field(struct nfp_prog *nfp_prog, swreg dst, u8 bmask, swreg src, 550 enum shf_sc sc, u8 shift) 551 { 552 emit_ld_field_any(nfp_prog, dst, bmask, src, sc, shift, false); 553 } 554 555 static void 556 __emit_lcsr(struct nfp_prog *nfp_prog, u16 areg, u16 breg, bool wr, u16 addr, 557 bool dst_lmextn, bool src_lmextn) 558 { 559 u64 insn; 560 561 insn = OP_LCSR_BASE | 562 FIELD_PREP(OP_LCSR_A_SRC, areg) | 563 FIELD_PREP(OP_LCSR_B_SRC, breg) | 564 FIELD_PREP(OP_LCSR_WRITE, wr) | 565 FIELD_PREP(OP_LCSR_ADDR, addr / 4) | 566 FIELD_PREP(OP_LCSR_SRC_LMEXTN, src_lmextn) | 567 FIELD_PREP(OP_LCSR_DST_LMEXTN, dst_lmextn); 568 569 nfp_prog_push(nfp_prog, insn); 570 } 571 572 static void emit_csr_wr(struct nfp_prog *nfp_prog, swreg src, u16 addr) 573 { 574 struct nfp_insn_ur_regs reg; 575 int err; 576 577 /* This instruction takes immeds instead of reg_none() for the ignored 578 * operand, but we can't encode 2 immeds in one instr with our normal 579 * swreg infra so if param is an immed, we encode as reg_none() and 580 * copy the immed to both operands. 581 */ 582 if (swreg_type(src) == NN_REG_IMM) { 583 err = swreg_to_unrestricted(reg_none(), src, reg_none(), ®); 584 reg.breg = reg.areg; 585 } else { 586 err = swreg_to_unrestricted(reg_none(), src, reg_imm(0), ®); 587 } 588 if (err) { 589 nfp_prog->error = err; 590 return; 591 } 592 593 __emit_lcsr(nfp_prog, reg.areg, reg.breg, true, addr, 594 false, reg.src_lmextn); 595 } 596 597 /* CSR value is read in following immed[gpr, 0] */ 598 static void __emit_csr_rd(struct nfp_prog *nfp_prog, u16 addr) 599 { 600 __emit_lcsr(nfp_prog, 0, 0, false, addr, false, false); 601 } 602 603 static void emit_nop(struct nfp_prog *nfp_prog) 604 { 605 __emit_immed(nfp_prog, UR_REG_IMM, UR_REG_IMM, 0, 0, 0, 0, 0, 0, 0); 606 } 607 608 /* --- Wrappers --- */ 609 static bool pack_immed(u32 imm, u16 *val, enum immed_shift *shift) 610 { 611 if (!(imm & 0xffff0000)) { 612 *val = imm; 613 *shift = IMMED_SHIFT_0B; 614 } else if (!(imm & 0xff0000ff)) { 615 *val = imm >> 8; 616 *shift = IMMED_SHIFT_1B; 617 } else if (!(imm & 0x0000ffff)) { 618 *val = imm >> 16; 619 *shift = IMMED_SHIFT_2B; 620 } else { 621 return false; 622 } 623 624 return true; 625 } 626 627 static void wrp_immed(struct nfp_prog *nfp_prog, swreg dst, u32 imm) 628 { 629 enum immed_shift shift; 630 u16 val; 631 632 if (pack_immed(imm, &val, &shift)) { 633 emit_immed(nfp_prog, dst, val, IMMED_WIDTH_ALL, false, shift); 634 } else if (pack_immed(~imm, &val, &shift)) { 635 emit_immed(nfp_prog, dst, val, IMMED_WIDTH_ALL, true, shift); 636 } else { 637 emit_immed(nfp_prog, dst, imm & 0xffff, IMMED_WIDTH_ALL, 638 false, IMMED_SHIFT_0B); 639 emit_immed(nfp_prog, dst, imm >> 16, IMMED_WIDTH_WORD, 640 false, IMMED_SHIFT_2B); 641 } 642 } 643 644 static void 645 wrp_immed_relo(struct nfp_prog *nfp_prog, swreg dst, u32 imm, 646 enum nfp_relo_type relo) 647 { 648 if (imm > 0xffff) { 649 pr_err("relocation of a large immediate!\n"); 650 nfp_prog->error = -EFAULT; 651 return; 652 } 653 emit_immed(nfp_prog, dst, imm, IMMED_WIDTH_ALL, false, IMMED_SHIFT_0B); 654 655 nfp_prog->prog[nfp_prog->prog_len - 1] |= 656 FIELD_PREP(OP_RELO_TYPE, relo); 657 } 658 659 /* ur_load_imm_any() - encode immediate or use tmp register (unrestricted) 660 * If the @imm is small enough encode it directly in operand and return 661 * otherwise load @imm to a spare register and return its encoding. 662 */ 663 static swreg ur_load_imm_any(struct nfp_prog *nfp_prog, u32 imm, swreg tmp_reg) 664 { 665 if (FIELD_FIT(UR_REG_IMM_MAX, imm)) 666 return reg_imm(imm); 667 668 wrp_immed(nfp_prog, tmp_reg, imm); 669 return tmp_reg; 670 } 671 672 /* re_load_imm_any() - encode immediate or use tmp register (restricted) 673 * If the @imm is small enough encode it directly in operand and return 674 * otherwise load @imm to a spare register and return its encoding. 675 */ 676 static swreg re_load_imm_any(struct nfp_prog *nfp_prog, u32 imm, swreg tmp_reg) 677 { 678 if (FIELD_FIT(RE_REG_IMM_MAX, imm)) 679 return reg_imm(imm); 680 681 wrp_immed(nfp_prog, tmp_reg, imm); 682 return tmp_reg; 683 } 684 685 static void wrp_nops(struct nfp_prog *nfp_prog, unsigned int count) 686 { 687 while (count--) 688 emit_nop(nfp_prog); 689 } 690 691 static void wrp_mov(struct nfp_prog *nfp_prog, swreg dst, swreg src) 692 { 693 emit_alu(nfp_prog, dst, reg_none(), ALU_OP_NONE, src); 694 } 695 696 static void wrp_reg_mov(struct nfp_prog *nfp_prog, u16 dst, u16 src) 697 { 698 wrp_mov(nfp_prog, reg_both(dst), reg_b(src)); 699 } 700 701 /* wrp_reg_subpart() - load @field_len bytes from @offset of @src, write the 702 * result to @dst from low end. 703 */ 704 static void 705 wrp_reg_subpart(struct nfp_prog *nfp_prog, swreg dst, swreg src, u8 field_len, 706 u8 offset) 707 { 708 enum shf_sc sc = offset ? SHF_SC_R_SHF : SHF_SC_NONE; 709 u8 mask = (1 << field_len) - 1; 710 711 emit_ld_field_any(nfp_prog, dst, mask, src, sc, offset * 8, true); 712 } 713 714 /* wrp_reg_or_subpart() - load @field_len bytes from low end of @src, or the 715 * result to @dst from offset, there is no change on the other bits of @dst. 716 */ 717 static void 718 wrp_reg_or_subpart(struct nfp_prog *nfp_prog, swreg dst, swreg src, 719 u8 field_len, u8 offset) 720 { 721 enum shf_sc sc = offset ? SHF_SC_L_SHF : SHF_SC_NONE; 722 u8 mask = ((1 << field_len) - 1) << offset; 723 724 emit_ld_field(nfp_prog, dst, mask, src, sc, 32 - offset * 8); 725 } 726 727 static void 728 addr40_offset(struct nfp_prog *nfp_prog, u8 src_gpr, swreg offset, 729 swreg *rega, swreg *regb) 730 { 731 if (offset == reg_imm(0)) { 732 *rega = reg_a(src_gpr); 733 *regb = reg_b(src_gpr + 1); 734 return; 735 } 736 737 emit_alu(nfp_prog, imm_a(nfp_prog), reg_a(src_gpr), ALU_OP_ADD, offset); 738 emit_alu(nfp_prog, imm_b(nfp_prog), reg_b(src_gpr + 1), ALU_OP_ADD_C, 739 reg_imm(0)); 740 *rega = imm_a(nfp_prog); 741 *regb = imm_b(nfp_prog); 742 } 743 744 /* NFP has Command Push Pull bus which supports bluk memory operations. */ 745 static int nfp_cpp_memcpy(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 746 { 747 bool descending_seq = meta->ldst_gather_len < 0; 748 s16 len = abs(meta->ldst_gather_len); 749 swreg src_base, off; 750 bool src_40bit_addr; 751 unsigned int i; 752 u8 xfer_num; 753 754 off = re_load_imm_any(nfp_prog, meta->insn.off, imm_b(nfp_prog)); 755 src_40bit_addr = meta->ptr.type == PTR_TO_MAP_VALUE; 756 src_base = reg_a(meta->insn.src_reg * 2); 757 xfer_num = round_up(len, 4) / 4; 758 759 if (src_40bit_addr) 760 addr40_offset(nfp_prog, meta->insn.src_reg * 2, off, &src_base, 761 &off); 762 763 /* Setup PREV_ALU fields to override memory read length. */ 764 if (len > 32) 765 wrp_immed(nfp_prog, reg_none(), 766 CMD_OVE_LEN | FIELD_PREP(CMD_OV_LEN, xfer_num - 1)); 767 768 /* Memory read from source addr into transfer-in registers. */ 769 emit_cmd_any(nfp_prog, CMD_TGT_READ32_SWAP, 770 src_40bit_addr ? CMD_MODE_40b_BA : CMD_MODE_32b, 0, 771 src_base, off, xfer_num - 1, CMD_CTX_SWAP, len > 32); 772 773 /* Move from transfer-in to transfer-out. */ 774 for (i = 0; i < xfer_num; i++) 775 wrp_mov(nfp_prog, reg_xfer(i), reg_xfer(i)); 776 777 off = re_load_imm_any(nfp_prog, meta->paired_st->off, imm_b(nfp_prog)); 778 779 if (len <= 8) { 780 /* Use single direct_ref write8. */ 781 emit_cmd(nfp_prog, CMD_TGT_WRITE8_SWAP, CMD_MODE_32b, 0, 782 reg_a(meta->paired_st->dst_reg * 2), off, len - 1, 783 CMD_CTX_SWAP); 784 } else if (len <= 32 && IS_ALIGNED(len, 4)) { 785 /* Use single direct_ref write32. */ 786 emit_cmd(nfp_prog, CMD_TGT_WRITE32_SWAP, CMD_MODE_32b, 0, 787 reg_a(meta->paired_st->dst_reg * 2), off, xfer_num - 1, 788 CMD_CTX_SWAP); 789 } else if (len <= 32) { 790 /* Use single indirect_ref write8. */ 791 wrp_immed(nfp_prog, reg_none(), 792 CMD_OVE_LEN | FIELD_PREP(CMD_OV_LEN, len - 1)); 793 emit_cmd_indir(nfp_prog, CMD_TGT_WRITE8_SWAP, CMD_MODE_32b, 0, 794 reg_a(meta->paired_st->dst_reg * 2), off, 795 len - 1, CMD_CTX_SWAP); 796 } else if (IS_ALIGNED(len, 4)) { 797 /* Use single indirect_ref write32. */ 798 wrp_immed(nfp_prog, reg_none(), 799 CMD_OVE_LEN | FIELD_PREP(CMD_OV_LEN, xfer_num - 1)); 800 emit_cmd_indir(nfp_prog, CMD_TGT_WRITE32_SWAP, CMD_MODE_32b, 0, 801 reg_a(meta->paired_st->dst_reg * 2), off, 802 xfer_num - 1, CMD_CTX_SWAP); 803 } else if (len <= 40) { 804 /* Use one direct_ref write32 to write the first 32-bytes, then 805 * another direct_ref write8 to write the remaining bytes. 806 */ 807 emit_cmd(nfp_prog, CMD_TGT_WRITE32_SWAP, CMD_MODE_32b, 0, 808 reg_a(meta->paired_st->dst_reg * 2), off, 7, 809 CMD_CTX_SWAP); 810 811 off = re_load_imm_any(nfp_prog, meta->paired_st->off + 32, 812 imm_b(nfp_prog)); 813 emit_cmd(nfp_prog, CMD_TGT_WRITE8_SWAP, CMD_MODE_32b, 8, 814 reg_a(meta->paired_st->dst_reg * 2), off, len - 33, 815 CMD_CTX_SWAP); 816 } else { 817 /* Use one indirect_ref write32 to write 4-bytes aligned length, 818 * then another direct_ref write8 to write the remaining bytes. 819 */ 820 u8 new_off; 821 822 wrp_immed(nfp_prog, reg_none(), 823 CMD_OVE_LEN | FIELD_PREP(CMD_OV_LEN, xfer_num - 2)); 824 emit_cmd_indir(nfp_prog, CMD_TGT_WRITE32_SWAP, CMD_MODE_32b, 0, 825 reg_a(meta->paired_st->dst_reg * 2), off, 826 xfer_num - 2, CMD_CTX_SWAP); 827 new_off = meta->paired_st->off + (xfer_num - 1) * 4; 828 off = re_load_imm_any(nfp_prog, new_off, imm_b(nfp_prog)); 829 emit_cmd(nfp_prog, CMD_TGT_WRITE8_SWAP, CMD_MODE_32b, 830 xfer_num - 1, reg_a(meta->paired_st->dst_reg * 2), off, 831 (len & 0x3) - 1, CMD_CTX_SWAP); 832 } 833 834 /* TODO: The following extra load is to make sure data flow be identical 835 * before and after we do memory copy optimization. 836 * 837 * The load destination register is not guaranteed to be dead, so we 838 * need to make sure it is loaded with the value the same as before 839 * this transformation. 840 * 841 * These extra loads could be removed once we have accurate register 842 * usage information. 843 */ 844 if (descending_seq) 845 xfer_num = 0; 846 else if (BPF_SIZE(meta->insn.code) != BPF_DW) 847 xfer_num = xfer_num - 1; 848 else 849 xfer_num = xfer_num - 2; 850 851 switch (BPF_SIZE(meta->insn.code)) { 852 case BPF_B: 853 wrp_reg_subpart(nfp_prog, reg_both(meta->insn.dst_reg * 2), 854 reg_xfer(xfer_num), 1, 855 IS_ALIGNED(len, 4) ? 3 : (len & 3) - 1); 856 break; 857 case BPF_H: 858 wrp_reg_subpart(nfp_prog, reg_both(meta->insn.dst_reg * 2), 859 reg_xfer(xfer_num), 2, (len & 3) ^ 2); 860 break; 861 case BPF_W: 862 wrp_mov(nfp_prog, reg_both(meta->insn.dst_reg * 2), 863 reg_xfer(0)); 864 break; 865 case BPF_DW: 866 wrp_mov(nfp_prog, reg_both(meta->insn.dst_reg * 2), 867 reg_xfer(xfer_num)); 868 wrp_mov(nfp_prog, reg_both(meta->insn.dst_reg * 2 + 1), 869 reg_xfer(xfer_num + 1)); 870 break; 871 } 872 873 if (BPF_SIZE(meta->insn.code) != BPF_DW) 874 wrp_immed(nfp_prog, reg_both(meta->insn.dst_reg * 2 + 1), 0); 875 876 return 0; 877 } 878 879 static int 880 data_ld(struct nfp_prog *nfp_prog, swreg offset, u8 dst_gpr, int size) 881 { 882 unsigned int i; 883 u16 shift, sz; 884 885 /* We load the value from the address indicated in @offset and then 886 * shift out the data we don't need. Note: this is big endian! 887 */ 888 sz = max(size, 4); 889 shift = size < 4 ? 4 - size : 0; 890 891 emit_cmd(nfp_prog, CMD_TGT_READ8, CMD_MODE_32b, 0, 892 pptr_reg(nfp_prog), offset, sz - 1, CMD_CTX_SWAP); 893 894 i = 0; 895 if (shift) 896 emit_shf(nfp_prog, reg_both(dst_gpr), reg_none(), SHF_OP_NONE, 897 reg_xfer(0), SHF_SC_R_SHF, shift * 8); 898 else 899 for (; i * 4 < size; i++) 900 wrp_mov(nfp_prog, reg_both(dst_gpr + i), reg_xfer(i)); 901 902 if (i < 2) 903 wrp_immed(nfp_prog, reg_both(dst_gpr + 1), 0); 904 905 return 0; 906 } 907 908 static int 909 data_ld_host_order(struct nfp_prog *nfp_prog, u8 dst_gpr, 910 swreg lreg, swreg rreg, int size, enum cmd_mode mode) 911 { 912 unsigned int i; 913 u8 mask, sz; 914 915 /* We load the value from the address indicated in rreg + lreg and then 916 * mask out the data we don't need. Note: this is little endian! 917 */ 918 sz = max(size, 4); 919 mask = size < 4 ? GENMASK(size - 1, 0) : 0; 920 921 emit_cmd(nfp_prog, CMD_TGT_READ32_SWAP, mode, 0, 922 lreg, rreg, sz / 4 - 1, CMD_CTX_SWAP); 923 924 i = 0; 925 if (mask) 926 emit_ld_field_any(nfp_prog, reg_both(dst_gpr), mask, 927 reg_xfer(0), SHF_SC_NONE, 0, true); 928 else 929 for (; i * 4 < size; i++) 930 wrp_mov(nfp_prog, reg_both(dst_gpr + i), reg_xfer(i)); 931 932 if (i < 2) 933 wrp_immed(nfp_prog, reg_both(dst_gpr + 1), 0); 934 935 return 0; 936 } 937 938 static int 939 data_ld_host_order_addr32(struct nfp_prog *nfp_prog, u8 src_gpr, swreg offset, 940 u8 dst_gpr, u8 size) 941 { 942 return data_ld_host_order(nfp_prog, dst_gpr, reg_a(src_gpr), offset, 943 size, CMD_MODE_32b); 944 } 945 946 static int 947 data_ld_host_order_addr40(struct nfp_prog *nfp_prog, u8 src_gpr, swreg offset, 948 u8 dst_gpr, u8 size) 949 { 950 swreg rega, regb; 951 952 addr40_offset(nfp_prog, src_gpr, offset, ®a, ®b); 953 954 return data_ld_host_order(nfp_prog, dst_gpr, rega, regb, 955 size, CMD_MODE_40b_BA); 956 } 957 958 static int 959 construct_data_ind_ld(struct nfp_prog *nfp_prog, u16 offset, u16 src, u8 size) 960 { 961 swreg tmp_reg; 962 963 /* Calculate the true offset (src_reg + imm) */ 964 tmp_reg = ur_load_imm_any(nfp_prog, offset, imm_b(nfp_prog)); 965 emit_alu(nfp_prog, imm_both(nfp_prog), reg_a(src), ALU_OP_ADD, tmp_reg); 966 967 /* Check packet length (size guaranteed to fit b/c it's u8) */ 968 emit_alu(nfp_prog, imm_a(nfp_prog), 969 imm_a(nfp_prog), ALU_OP_ADD, reg_imm(size)); 970 emit_alu(nfp_prog, reg_none(), 971 plen_reg(nfp_prog), ALU_OP_SUB, imm_a(nfp_prog)); 972 emit_br_relo(nfp_prog, BR_BLO, BR_OFF_RELO, 0, RELO_BR_GO_ABORT); 973 974 /* Load data */ 975 return data_ld(nfp_prog, imm_b(nfp_prog), 0, size); 976 } 977 978 static int construct_data_ld(struct nfp_prog *nfp_prog, u16 offset, u8 size) 979 { 980 swreg tmp_reg; 981 982 /* Check packet length */ 983 tmp_reg = ur_load_imm_any(nfp_prog, offset + size, imm_a(nfp_prog)); 984 emit_alu(nfp_prog, reg_none(), plen_reg(nfp_prog), ALU_OP_SUB, tmp_reg); 985 emit_br_relo(nfp_prog, BR_BLO, BR_OFF_RELO, 0, RELO_BR_GO_ABORT); 986 987 /* Load data */ 988 tmp_reg = re_load_imm_any(nfp_prog, offset, imm_b(nfp_prog)); 989 return data_ld(nfp_prog, tmp_reg, 0, size); 990 } 991 992 static int 993 data_stx_host_order(struct nfp_prog *nfp_prog, u8 dst_gpr, swreg offset, 994 u8 src_gpr, u8 size) 995 { 996 unsigned int i; 997 998 for (i = 0; i * 4 < size; i++) 999 wrp_mov(nfp_prog, reg_xfer(i), reg_a(src_gpr + i)); 1000 1001 emit_cmd(nfp_prog, CMD_TGT_WRITE8_SWAP, CMD_MODE_32b, 0, 1002 reg_a(dst_gpr), offset, size - 1, CMD_CTX_SWAP); 1003 1004 return 0; 1005 } 1006 1007 static int 1008 data_st_host_order(struct nfp_prog *nfp_prog, u8 dst_gpr, swreg offset, 1009 u64 imm, u8 size) 1010 { 1011 wrp_immed(nfp_prog, reg_xfer(0), imm); 1012 if (size == 8) 1013 wrp_immed(nfp_prog, reg_xfer(1), imm >> 32); 1014 1015 emit_cmd(nfp_prog, CMD_TGT_WRITE8_SWAP, CMD_MODE_32b, 0, 1016 reg_a(dst_gpr), offset, size - 1, CMD_CTX_SWAP); 1017 1018 return 0; 1019 } 1020 1021 typedef int 1022 (*lmem_step)(struct nfp_prog *nfp_prog, u8 gpr, u8 gpr_byte, s32 off, 1023 unsigned int size, bool first, bool new_gpr, bool last, bool lm3, 1024 bool needs_inc); 1025 1026 static int 1027 wrp_lmem_load(struct nfp_prog *nfp_prog, u8 dst, u8 dst_byte, s32 off, 1028 unsigned int size, bool first, bool new_gpr, bool last, bool lm3, 1029 bool needs_inc) 1030 { 1031 bool should_inc = needs_inc && new_gpr && !last; 1032 u32 idx, src_byte; 1033 enum shf_sc sc; 1034 swreg reg; 1035 int shf; 1036 u8 mask; 1037 1038 if (WARN_ON_ONCE(dst_byte + size > 4 || off % 4 + size > 4)) 1039 return -EOPNOTSUPP; 1040 1041 idx = off / 4; 1042 1043 /* Move the entire word */ 1044 if (size == 4) { 1045 wrp_mov(nfp_prog, reg_both(dst), 1046 should_inc ? reg_lm_inc(3) : reg_lm(lm3 ? 3 : 0, idx)); 1047 return 0; 1048 } 1049 1050 if (WARN_ON_ONCE(lm3 && idx > RE_REG_LM_IDX_MAX)) 1051 return -EOPNOTSUPP; 1052 1053 src_byte = off % 4; 1054 1055 mask = (1 << size) - 1; 1056 mask <<= dst_byte; 1057 1058 if (WARN_ON_ONCE(mask > 0xf)) 1059 return -EOPNOTSUPP; 1060 1061 shf = abs(src_byte - dst_byte) * 8; 1062 if (src_byte == dst_byte) { 1063 sc = SHF_SC_NONE; 1064 } else if (src_byte < dst_byte) { 1065 shf = 32 - shf; 1066 sc = SHF_SC_L_SHF; 1067 } else { 1068 sc = SHF_SC_R_SHF; 1069 } 1070 1071 /* ld_field can address fewer indexes, if offset too large do RMW. 1072 * Because we RMV twice we waste 2 cycles on unaligned 8 byte writes. 1073 */ 1074 if (idx <= RE_REG_LM_IDX_MAX) { 1075 reg = reg_lm(lm3 ? 3 : 0, idx); 1076 } else { 1077 reg = imm_a(nfp_prog); 1078 /* If it's not the first part of the load and we start a new GPR 1079 * that means we are loading a second part of the LMEM word into 1080 * a new GPR. IOW we've already looked that LMEM word and 1081 * therefore it has been loaded into imm_a(). 1082 */ 1083 if (first || !new_gpr) 1084 wrp_mov(nfp_prog, reg, reg_lm(0, idx)); 1085 } 1086 1087 emit_ld_field_any(nfp_prog, reg_both(dst), mask, reg, sc, shf, new_gpr); 1088 1089 if (should_inc) 1090 wrp_mov(nfp_prog, reg_none(), reg_lm_inc(3)); 1091 1092 return 0; 1093 } 1094 1095 static int 1096 wrp_lmem_store(struct nfp_prog *nfp_prog, u8 src, u8 src_byte, s32 off, 1097 unsigned int size, bool first, bool new_gpr, bool last, bool lm3, 1098 bool needs_inc) 1099 { 1100 bool should_inc = needs_inc && new_gpr && !last; 1101 u32 idx, dst_byte; 1102 enum shf_sc sc; 1103 swreg reg; 1104 int shf; 1105 u8 mask; 1106 1107 if (WARN_ON_ONCE(src_byte + size > 4 || off % 4 + size > 4)) 1108 return -EOPNOTSUPP; 1109 1110 idx = off / 4; 1111 1112 /* Move the entire word */ 1113 if (size == 4) { 1114 wrp_mov(nfp_prog, 1115 should_inc ? reg_lm_inc(3) : reg_lm(lm3 ? 3 : 0, idx), 1116 reg_b(src)); 1117 return 0; 1118 } 1119 1120 if (WARN_ON_ONCE(lm3 && idx > RE_REG_LM_IDX_MAX)) 1121 return -EOPNOTSUPP; 1122 1123 dst_byte = off % 4; 1124 1125 mask = (1 << size) - 1; 1126 mask <<= dst_byte; 1127 1128 if (WARN_ON_ONCE(mask > 0xf)) 1129 return -EOPNOTSUPP; 1130 1131 shf = abs(src_byte - dst_byte) * 8; 1132 if (src_byte == dst_byte) { 1133 sc = SHF_SC_NONE; 1134 } else if (src_byte < dst_byte) { 1135 shf = 32 - shf; 1136 sc = SHF_SC_L_SHF; 1137 } else { 1138 sc = SHF_SC_R_SHF; 1139 } 1140 1141 /* ld_field can address fewer indexes, if offset too large do RMW. 1142 * Because we RMV twice we waste 2 cycles on unaligned 8 byte writes. 1143 */ 1144 if (idx <= RE_REG_LM_IDX_MAX) { 1145 reg = reg_lm(lm3 ? 3 : 0, idx); 1146 } else { 1147 reg = imm_a(nfp_prog); 1148 /* Only first and last LMEM locations are going to need RMW, 1149 * the middle location will be overwritten fully. 1150 */ 1151 if (first || last) 1152 wrp_mov(nfp_prog, reg, reg_lm(0, idx)); 1153 } 1154 1155 emit_ld_field(nfp_prog, reg, mask, reg_b(src), sc, shf); 1156 1157 if (new_gpr || last) { 1158 if (idx > RE_REG_LM_IDX_MAX) 1159 wrp_mov(nfp_prog, reg_lm(0, idx), reg); 1160 if (should_inc) 1161 wrp_mov(nfp_prog, reg_none(), reg_lm_inc(3)); 1162 } 1163 1164 return 0; 1165 } 1166 1167 static int 1168 mem_op_stack(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 1169 unsigned int size, unsigned int ptr_off, u8 gpr, u8 ptr_gpr, 1170 bool clr_gpr, lmem_step step) 1171 { 1172 s32 off = nfp_prog->stack_frame_depth + meta->insn.off + ptr_off; 1173 bool first = true, last; 1174 bool needs_inc = false; 1175 swreg stack_off_reg; 1176 u8 prev_gpr = 255; 1177 u32 gpr_byte = 0; 1178 bool lm3 = true; 1179 int ret; 1180 1181 if (meta->ptr_not_const) { 1182 /* Use of the last encountered ptr_off is OK, they all have 1183 * the same alignment. Depend on low bits of value being 1184 * discarded when written to LMaddr register. 1185 */ 1186 stack_off_reg = ur_load_imm_any(nfp_prog, meta->insn.off, 1187 stack_imm(nfp_prog)); 1188 1189 emit_alu(nfp_prog, imm_b(nfp_prog), 1190 reg_a(ptr_gpr), ALU_OP_ADD, stack_off_reg); 1191 1192 needs_inc = true; 1193 } else if (off + size <= 64) { 1194 /* We can reach bottom 64B with LMaddr0 */ 1195 lm3 = false; 1196 } else if (round_down(off, 32) == round_down(off + size - 1, 32)) { 1197 /* We have to set up a new pointer. If we know the offset 1198 * and the entire access falls into a single 32 byte aligned 1199 * window we won't have to increment the LM pointer. 1200 * The 32 byte alignment is imporant because offset is ORed in 1201 * not added when doing *l$indexN[off]. 1202 */ 1203 stack_off_reg = ur_load_imm_any(nfp_prog, round_down(off, 32), 1204 stack_imm(nfp_prog)); 1205 emit_alu(nfp_prog, imm_b(nfp_prog), 1206 stack_reg(nfp_prog), ALU_OP_ADD, stack_off_reg); 1207 1208 off %= 32; 1209 } else { 1210 stack_off_reg = ur_load_imm_any(nfp_prog, round_down(off, 4), 1211 stack_imm(nfp_prog)); 1212 1213 emit_alu(nfp_prog, imm_b(nfp_prog), 1214 stack_reg(nfp_prog), ALU_OP_ADD, stack_off_reg); 1215 1216 needs_inc = true; 1217 } 1218 if (lm3) { 1219 emit_csr_wr(nfp_prog, imm_b(nfp_prog), NFP_CSR_ACT_LM_ADDR3); 1220 /* For size < 4 one slot will be filled by zeroing of upper. */ 1221 wrp_nops(nfp_prog, clr_gpr && size < 8 ? 2 : 3); 1222 } 1223 1224 if (clr_gpr && size < 8) 1225 wrp_immed(nfp_prog, reg_both(gpr + 1), 0); 1226 1227 while (size) { 1228 u32 slice_end; 1229 u8 slice_size; 1230 1231 slice_size = min(size, 4 - gpr_byte); 1232 slice_end = min(off + slice_size, round_up(off + 1, 4)); 1233 slice_size = slice_end - off; 1234 1235 last = slice_size == size; 1236 1237 if (needs_inc) 1238 off %= 4; 1239 1240 ret = step(nfp_prog, gpr, gpr_byte, off, slice_size, 1241 first, gpr != prev_gpr, last, lm3, needs_inc); 1242 if (ret) 1243 return ret; 1244 1245 prev_gpr = gpr; 1246 first = false; 1247 1248 gpr_byte += slice_size; 1249 if (gpr_byte >= 4) { 1250 gpr_byte -= 4; 1251 gpr++; 1252 } 1253 1254 size -= slice_size; 1255 off += slice_size; 1256 } 1257 1258 return 0; 1259 } 1260 1261 static void 1262 wrp_alu_imm(struct nfp_prog *nfp_prog, u8 dst, enum alu_op alu_op, u32 imm) 1263 { 1264 swreg tmp_reg; 1265 1266 if (alu_op == ALU_OP_AND) { 1267 if (!imm) 1268 wrp_immed(nfp_prog, reg_both(dst), 0); 1269 if (!imm || !~imm) 1270 return; 1271 } 1272 if (alu_op == ALU_OP_OR) { 1273 if (!~imm) 1274 wrp_immed(nfp_prog, reg_both(dst), ~0U); 1275 if (!imm || !~imm) 1276 return; 1277 } 1278 if (alu_op == ALU_OP_XOR) { 1279 if (!~imm) 1280 emit_alu(nfp_prog, reg_both(dst), reg_none(), 1281 ALU_OP_NOT, reg_b(dst)); 1282 if (!imm || !~imm) 1283 return; 1284 } 1285 1286 tmp_reg = ur_load_imm_any(nfp_prog, imm, imm_b(nfp_prog)); 1287 emit_alu(nfp_prog, reg_both(dst), reg_a(dst), alu_op, tmp_reg); 1288 } 1289 1290 static int 1291 wrp_alu64_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 1292 enum alu_op alu_op, bool skip) 1293 { 1294 const struct bpf_insn *insn = &meta->insn; 1295 u64 imm = insn->imm; /* sign extend */ 1296 1297 if (skip) { 1298 meta->skip = true; 1299 return 0; 1300 } 1301 1302 wrp_alu_imm(nfp_prog, insn->dst_reg * 2, alu_op, imm & ~0U); 1303 wrp_alu_imm(nfp_prog, insn->dst_reg * 2 + 1, alu_op, imm >> 32); 1304 1305 return 0; 1306 } 1307 1308 static int 1309 wrp_alu64_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 1310 enum alu_op alu_op) 1311 { 1312 u8 dst = meta->insn.dst_reg * 2, src = meta->insn.src_reg * 2; 1313 1314 emit_alu(nfp_prog, reg_both(dst), reg_a(dst), alu_op, reg_b(src)); 1315 emit_alu(nfp_prog, reg_both(dst + 1), 1316 reg_a(dst + 1), alu_op, reg_b(src + 1)); 1317 1318 return 0; 1319 } 1320 1321 static int 1322 wrp_alu32_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 1323 enum alu_op alu_op, bool skip) 1324 { 1325 const struct bpf_insn *insn = &meta->insn; 1326 1327 if (skip) { 1328 meta->skip = true; 1329 return 0; 1330 } 1331 1332 wrp_alu_imm(nfp_prog, insn->dst_reg * 2, alu_op, insn->imm); 1333 wrp_immed(nfp_prog, reg_both(insn->dst_reg * 2 + 1), 0); 1334 1335 return 0; 1336 } 1337 1338 static int 1339 wrp_alu32_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 1340 enum alu_op alu_op) 1341 { 1342 u8 dst = meta->insn.dst_reg * 2, src = meta->insn.src_reg * 2; 1343 1344 emit_alu(nfp_prog, reg_both(dst), reg_a(dst), alu_op, reg_b(src)); 1345 wrp_immed(nfp_prog, reg_both(meta->insn.dst_reg * 2 + 1), 0); 1346 1347 return 0; 1348 } 1349 1350 static void 1351 wrp_test_reg_one(struct nfp_prog *nfp_prog, u8 dst, enum alu_op alu_op, u8 src, 1352 enum br_mask br_mask, u16 off) 1353 { 1354 emit_alu(nfp_prog, reg_none(), reg_a(dst), alu_op, reg_b(src)); 1355 emit_br(nfp_prog, br_mask, off, 0); 1356 } 1357 1358 static int 1359 wrp_test_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 1360 enum alu_op alu_op, enum br_mask br_mask) 1361 { 1362 const struct bpf_insn *insn = &meta->insn; 1363 1364 wrp_test_reg_one(nfp_prog, insn->dst_reg * 2, alu_op, 1365 insn->src_reg * 2, br_mask, insn->off); 1366 wrp_test_reg_one(nfp_prog, insn->dst_reg * 2 + 1, alu_op, 1367 insn->src_reg * 2 + 1, br_mask, insn->off); 1368 1369 return 0; 1370 } 1371 1372 static const struct jmp_code_map { 1373 enum br_mask br_mask; 1374 bool swap; 1375 } jmp_code_map[] = { 1376 [BPF_JGT >> 4] = { BR_BLO, true }, 1377 [BPF_JGE >> 4] = { BR_BHS, false }, 1378 [BPF_JLT >> 4] = { BR_BLO, false }, 1379 [BPF_JLE >> 4] = { BR_BHS, true }, 1380 [BPF_JSGT >> 4] = { BR_BLT, true }, 1381 [BPF_JSGE >> 4] = { BR_BGE, false }, 1382 [BPF_JSLT >> 4] = { BR_BLT, false }, 1383 [BPF_JSLE >> 4] = { BR_BGE, true }, 1384 }; 1385 1386 static const struct jmp_code_map *nfp_jmp_code_get(struct nfp_insn_meta *meta) 1387 { 1388 unsigned int op; 1389 1390 op = BPF_OP(meta->insn.code) >> 4; 1391 /* br_mask of 0 is BR_BEQ which we don't use in jump code table */ 1392 if (WARN_ONCE(op >= ARRAY_SIZE(jmp_code_map) || 1393 !jmp_code_map[op].br_mask, 1394 "no code found for jump instruction")) 1395 return NULL; 1396 1397 return &jmp_code_map[op]; 1398 } 1399 1400 static int cmp_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1401 { 1402 const struct bpf_insn *insn = &meta->insn; 1403 u64 imm = insn->imm; /* sign extend */ 1404 const struct jmp_code_map *code; 1405 enum alu_op alu_op, carry_op; 1406 u8 reg = insn->dst_reg * 2; 1407 swreg tmp_reg; 1408 1409 code = nfp_jmp_code_get(meta); 1410 if (!code) 1411 return -EINVAL; 1412 1413 alu_op = meta->jump_neg_op ? ALU_OP_ADD : ALU_OP_SUB; 1414 carry_op = meta->jump_neg_op ? ALU_OP_ADD_C : ALU_OP_SUB_C; 1415 1416 tmp_reg = ur_load_imm_any(nfp_prog, imm & ~0U, imm_b(nfp_prog)); 1417 if (!code->swap) 1418 emit_alu(nfp_prog, reg_none(), reg_a(reg), alu_op, tmp_reg); 1419 else 1420 emit_alu(nfp_prog, reg_none(), tmp_reg, alu_op, reg_a(reg)); 1421 1422 tmp_reg = ur_load_imm_any(nfp_prog, imm >> 32, imm_b(nfp_prog)); 1423 if (!code->swap) 1424 emit_alu(nfp_prog, reg_none(), 1425 reg_a(reg + 1), carry_op, tmp_reg); 1426 else 1427 emit_alu(nfp_prog, reg_none(), 1428 tmp_reg, carry_op, reg_a(reg + 1)); 1429 1430 emit_br(nfp_prog, code->br_mask, insn->off, 0); 1431 1432 return 0; 1433 } 1434 1435 static int cmp_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1436 { 1437 const struct bpf_insn *insn = &meta->insn; 1438 const struct jmp_code_map *code; 1439 u8 areg, breg; 1440 1441 code = nfp_jmp_code_get(meta); 1442 if (!code) 1443 return -EINVAL; 1444 1445 areg = insn->dst_reg * 2; 1446 breg = insn->src_reg * 2; 1447 1448 if (code->swap) { 1449 areg ^= breg; 1450 breg ^= areg; 1451 areg ^= breg; 1452 } 1453 1454 emit_alu(nfp_prog, reg_none(), reg_a(areg), ALU_OP_SUB, reg_b(breg)); 1455 emit_alu(nfp_prog, reg_none(), 1456 reg_a(areg + 1), ALU_OP_SUB_C, reg_b(breg + 1)); 1457 emit_br(nfp_prog, code->br_mask, insn->off, 0); 1458 1459 return 0; 1460 } 1461 1462 static void wrp_end32(struct nfp_prog *nfp_prog, swreg reg_in, u8 gpr_out) 1463 { 1464 emit_ld_field(nfp_prog, reg_both(gpr_out), 0xf, reg_in, 1465 SHF_SC_R_ROT, 8); 1466 emit_ld_field(nfp_prog, reg_both(gpr_out), 0x5, reg_a(gpr_out), 1467 SHF_SC_R_ROT, 16); 1468 } 1469 1470 static void 1471 wrp_mul_u32(struct nfp_prog *nfp_prog, swreg dst_hi, swreg dst_lo, swreg lreg, 1472 swreg rreg, bool gen_high_half) 1473 { 1474 emit_mul(nfp_prog, lreg, MUL_TYPE_START, MUL_STEP_NONE, rreg); 1475 emit_mul(nfp_prog, lreg, MUL_TYPE_STEP_32x32, MUL_STEP_1, rreg); 1476 emit_mul(nfp_prog, lreg, MUL_TYPE_STEP_32x32, MUL_STEP_2, rreg); 1477 emit_mul(nfp_prog, lreg, MUL_TYPE_STEP_32x32, MUL_STEP_3, rreg); 1478 emit_mul(nfp_prog, lreg, MUL_TYPE_STEP_32x32, MUL_STEP_4, rreg); 1479 emit_mul(nfp_prog, dst_lo, MUL_TYPE_STEP_32x32, MUL_LAST, reg_none()); 1480 if (gen_high_half) 1481 emit_mul(nfp_prog, dst_hi, MUL_TYPE_STEP_32x32, MUL_LAST_2, 1482 reg_none()); 1483 else 1484 wrp_immed(nfp_prog, dst_hi, 0); 1485 } 1486 1487 static void 1488 wrp_mul_u16(struct nfp_prog *nfp_prog, swreg dst_hi, swreg dst_lo, swreg lreg, 1489 swreg rreg) 1490 { 1491 emit_mul(nfp_prog, lreg, MUL_TYPE_START, MUL_STEP_NONE, rreg); 1492 emit_mul(nfp_prog, lreg, MUL_TYPE_STEP_16x16, MUL_STEP_1, rreg); 1493 emit_mul(nfp_prog, lreg, MUL_TYPE_STEP_16x16, MUL_STEP_2, rreg); 1494 emit_mul(nfp_prog, dst_lo, MUL_TYPE_STEP_16x16, MUL_LAST, reg_none()); 1495 } 1496 1497 static int 1498 wrp_mul(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 1499 bool gen_high_half, bool ropnd_from_reg) 1500 { 1501 swreg multiplier, multiplicand, dst_hi, dst_lo; 1502 const struct bpf_insn *insn = &meta->insn; 1503 u32 lopnd_max, ropnd_max; 1504 u8 dst_reg; 1505 1506 dst_reg = insn->dst_reg; 1507 multiplicand = reg_a(dst_reg * 2); 1508 dst_hi = reg_both(dst_reg * 2 + 1); 1509 dst_lo = reg_both(dst_reg * 2); 1510 lopnd_max = meta->umax_dst; 1511 if (ropnd_from_reg) { 1512 multiplier = reg_b(insn->src_reg * 2); 1513 ropnd_max = meta->umax_src; 1514 } else { 1515 u32 imm = insn->imm; 1516 1517 multiplier = ur_load_imm_any(nfp_prog, imm, imm_b(nfp_prog)); 1518 ropnd_max = imm; 1519 } 1520 if (lopnd_max > U16_MAX || ropnd_max > U16_MAX) 1521 wrp_mul_u32(nfp_prog, dst_hi, dst_lo, multiplicand, multiplier, 1522 gen_high_half); 1523 else 1524 wrp_mul_u16(nfp_prog, dst_hi, dst_lo, multiplicand, multiplier); 1525 1526 return 0; 1527 } 1528 1529 static int wrp_div_imm(struct nfp_prog *nfp_prog, u8 dst, u64 imm) 1530 { 1531 swreg dst_both = reg_both(dst), dst_a = reg_a(dst), dst_b = reg_a(dst); 1532 struct reciprocal_value_adv rvalue; 1533 u8 pre_shift, exp; 1534 swreg magic; 1535 1536 if (imm > U32_MAX) { 1537 wrp_immed(nfp_prog, dst_both, 0); 1538 return 0; 1539 } 1540 1541 /* NOTE: because we are using "reciprocal_value_adv" which doesn't 1542 * support "divisor > (1u << 31)", we need to JIT separate NFP sequence 1543 * to handle such case which actually equals to the result of unsigned 1544 * comparison "dst >= imm" which could be calculated using the following 1545 * NFP sequence: 1546 * 1547 * alu[--, dst, -, imm] 1548 * immed[imm, 0] 1549 * alu[dst, imm, +carry, 0] 1550 * 1551 */ 1552 if (imm > 1U << 31) { 1553 swreg tmp_b = ur_load_imm_any(nfp_prog, imm, imm_b(nfp_prog)); 1554 1555 emit_alu(nfp_prog, reg_none(), dst_a, ALU_OP_SUB, tmp_b); 1556 wrp_immed(nfp_prog, imm_a(nfp_prog), 0); 1557 emit_alu(nfp_prog, dst_both, imm_a(nfp_prog), ALU_OP_ADD_C, 1558 reg_imm(0)); 1559 return 0; 1560 } 1561 1562 rvalue = reciprocal_value_adv(imm, 32); 1563 exp = rvalue.exp; 1564 if (rvalue.is_wide_m && !(imm & 1)) { 1565 pre_shift = fls(imm & -imm) - 1; 1566 rvalue = reciprocal_value_adv(imm >> pre_shift, 32 - pre_shift); 1567 } else { 1568 pre_shift = 0; 1569 } 1570 magic = ur_load_imm_any(nfp_prog, rvalue.m, imm_b(nfp_prog)); 1571 if (imm == 1U << exp) { 1572 emit_shf(nfp_prog, dst_both, reg_none(), SHF_OP_NONE, dst_b, 1573 SHF_SC_R_SHF, exp); 1574 } else if (rvalue.is_wide_m) { 1575 wrp_mul_u32(nfp_prog, imm_both(nfp_prog), reg_none(), dst_a, 1576 magic, true); 1577 emit_alu(nfp_prog, dst_both, dst_a, ALU_OP_SUB, 1578 imm_b(nfp_prog)); 1579 emit_shf(nfp_prog, dst_both, reg_none(), SHF_OP_NONE, dst_b, 1580 SHF_SC_R_SHF, 1); 1581 emit_alu(nfp_prog, dst_both, dst_a, ALU_OP_ADD, 1582 imm_b(nfp_prog)); 1583 emit_shf(nfp_prog, dst_both, reg_none(), SHF_OP_NONE, dst_b, 1584 SHF_SC_R_SHF, rvalue.sh - 1); 1585 } else { 1586 if (pre_shift) 1587 emit_shf(nfp_prog, dst_both, reg_none(), SHF_OP_NONE, 1588 dst_b, SHF_SC_R_SHF, pre_shift); 1589 wrp_mul_u32(nfp_prog, dst_both, reg_none(), dst_a, magic, true); 1590 emit_shf(nfp_prog, dst_both, reg_none(), SHF_OP_NONE, 1591 dst_b, SHF_SC_R_SHF, rvalue.sh); 1592 } 1593 1594 return 0; 1595 } 1596 1597 static int adjust_head(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1598 { 1599 swreg tmp = imm_a(nfp_prog), tmp_len = imm_b(nfp_prog); 1600 struct nfp_bpf_cap_adjust_head *adjust_head; 1601 u32 ret_einval, end; 1602 1603 adjust_head = &nfp_prog->bpf->adjust_head; 1604 1605 /* Optimized version - 5 vs 14 cycles */ 1606 if (nfp_prog->adjust_head_location != UINT_MAX) { 1607 if (WARN_ON_ONCE(nfp_prog->adjust_head_location != meta->n)) 1608 return -EINVAL; 1609 1610 emit_alu(nfp_prog, pptr_reg(nfp_prog), 1611 reg_a(2 * 2), ALU_OP_ADD, pptr_reg(nfp_prog)); 1612 emit_alu(nfp_prog, plen_reg(nfp_prog), 1613 plen_reg(nfp_prog), ALU_OP_SUB, reg_a(2 * 2)); 1614 emit_alu(nfp_prog, pv_len(nfp_prog), 1615 pv_len(nfp_prog), ALU_OP_SUB, reg_a(2 * 2)); 1616 1617 wrp_immed(nfp_prog, reg_both(0), 0); 1618 wrp_immed(nfp_prog, reg_both(1), 0); 1619 1620 /* TODO: when adjust head is guaranteed to succeed we can 1621 * also eliminate the following if (r0 == 0) branch. 1622 */ 1623 1624 return 0; 1625 } 1626 1627 ret_einval = nfp_prog_current_offset(nfp_prog) + 14; 1628 end = ret_einval + 2; 1629 1630 /* We need to use a temp because offset is just a part of the pkt ptr */ 1631 emit_alu(nfp_prog, tmp, 1632 reg_a(2 * 2), ALU_OP_ADD_2B, pptr_reg(nfp_prog)); 1633 1634 /* Validate result will fit within FW datapath constraints */ 1635 emit_alu(nfp_prog, reg_none(), 1636 tmp, ALU_OP_SUB, reg_imm(adjust_head->off_min)); 1637 emit_br(nfp_prog, BR_BLO, ret_einval, 0); 1638 emit_alu(nfp_prog, reg_none(), 1639 reg_imm(adjust_head->off_max), ALU_OP_SUB, tmp); 1640 emit_br(nfp_prog, BR_BLO, ret_einval, 0); 1641 1642 /* Validate the length is at least ETH_HLEN */ 1643 emit_alu(nfp_prog, tmp_len, 1644 plen_reg(nfp_prog), ALU_OP_SUB, reg_a(2 * 2)); 1645 emit_alu(nfp_prog, reg_none(), 1646 tmp_len, ALU_OP_SUB, reg_imm(ETH_HLEN)); 1647 emit_br(nfp_prog, BR_BMI, ret_einval, 0); 1648 1649 /* Load the ret code */ 1650 wrp_immed(nfp_prog, reg_both(0), 0); 1651 wrp_immed(nfp_prog, reg_both(1), 0); 1652 1653 /* Modify the packet metadata */ 1654 emit_ld_field(nfp_prog, pptr_reg(nfp_prog), 0x3, tmp, SHF_SC_NONE, 0); 1655 1656 /* Skip over the -EINVAL ret code (defer 2) */ 1657 emit_br(nfp_prog, BR_UNC, end, 2); 1658 1659 emit_alu(nfp_prog, plen_reg(nfp_prog), 1660 plen_reg(nfp_prog), ALU_OP_SUB, reg_a(2 * 2)); 1661 emit_alu(nfp_prog, pv_len(nfp_prog), 1662 pv_len(nfp_prog), ALU_OP_SUB, reg_a(2 * 2)); 1663 1664 /* return -EINVAL target */ 1665 if (!nfp_prog_confirm_current_offset(nfp_prog, ret_einval)) 1666 return -EINVAL; 1667 1668 wrp_immed(nfp_prog, reg_both(0), -22); 1669 wrp_immed(nfp_prog, reg_both(1), ~0); 1670 1671 if (!nfp_prog_confirm_current_offset(nfp_prog, end)) 1672 return -EINVAL; 1673 1674 return 0; 1675 } 1676 1677 static int adjust_tail(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1678 { 1679 u32 ret_einval, end; 1680 swreg plen, delta; 1681 1682 BUILD_BUG_ON(plen_reg(nfp_prog) != reg_b(STATIC_REG_PKT_LEN)); 1683 1684 plen = imm_a(nfp_prog); 1685 delta = reg_a(2 * 2); 1686 1687 ret_einval = nfp_prog_current_offset(nfp_prog) + 9; 1688 end = nfp_prog_current_offset(nfp_prog) + 11; 1689 1690 /* Calculate resulting length */ 1691 emit_alu(nfp_prog, plen, plen_reg(nfp_prog), ALU_OP_ADD, delta); 1692 /* delta == 0 is not allowed by the kernel, add must overflow to make 1693 * length smaller. 1694 */ 1695 emit_br(nfp_prog, BR_BCC, ret_einval, 0); 1696 1697 /* if (new_len < 14) then -EINVAL */ 1698 emit_alu(nfp_prog, reg_none(), plen, ALU_OP_SUB, reg_imm(ETH_HLEN)); 1699 emit_br(nfp_prog, BR_BMI, ret_einval, 0); 1700 1701 emit_alu(nfp_prog, plen_reg(nfp_prog), 1702 plen_reg(nfp_prog), ALU_OP_ADD, delta); 1703 emit_alu(nfp_prog, pv_len(nfp_prog), 1704 pv_len(nfp_prog), ALU_OP_ADD, delta); 1705 1706 emit_br(nfp_prog, BR_UNC, end, 2); 1707 wrp_immed(nfp_prog, reg_both(0), 0); 1708 wrp_immed(nfp_prog, reg_both(1), 0); 1709 1710 if (!nfp_prog_confirm_current_offset(nfp_prog, ret_einval)) 1711 return -EINVAL; 1712 1713 wrp_immed(nfp_prog, reg_both(0), -22); 1714 wrp_immed(nfp_prog, reg_both(1), ~0); 1715 1716 if (!nfp_prog_confirm_current_offset(nfp_prog, end)) 1717 return -EINVAL; 1718 1719 return 0; 1720 } 1721 1722 static int 1723 map_call_stack_common(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1724 { 1725 bool load_lm_ptr; 1726 u32 ret_tgt; 1727 s64 lm_off; 1728 1729 /* We only have to reload LM0 if the key is not at start of stack */ 1730 lm_off = nfp_prog->stack_frame_depth; 1731 lm_off += meta->arg2.reg.var_off.value + meta->arg2.reg.off; 1732 load_lm_ptr = meta->arg2.var_off || lm_off; 1733 1734 /* Set LM0 to start of key */ 1735 if (load_lm_ptr) 1736 emit_csr_wr(nfp_prog, reg_b(2 * 2), NFP_CSR_ACT_LM_ADDR0); 1737 if (meta->func_id == BPF_FUNC_map_update_elem) 1738 emit_csr_wr(nfp_prog, reg_b(3 * 2), NFP_CSR_ACT_LM_ADDR2); 1739 1740 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO + meta->func_id, 1741 2, RELO_BR_HELPER); 1742 ret_tgt = nfp_prog_current_offset(nfp_prog) + 2; 1743 1744 /* Load map ID into A0 */ 1745 wrp_mov(nfp_prog, reg_a(0), reg_a(2)); 1746 1747 /* Load the return address into B0 */ 1748 wrp_immed_relo(nfp_prog, reg_b(0), ret_tgt, RELO_IMMED_REL); 1749 1750 if (!nfp_prog_confirm_current_offset(nfp_prog, ret_tgt)) 1751 return -EINVAL; 1752 1753 /* Reset the LM0 pointer */ 1754 if (!load_lm_ptr) 1755 return 0; 1756 1757 emit_csr_wr(nfp_prog, stack_reg(nfp_prog), NFP_CSR_ACT_LM_ADDR0); 1758 wrp_nops(nfp_prog, 3); 1759 1760 return 0; 1761 } 1762 1763 static int 1764 nfp_get_prandom_u32(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1765 { 1766 __emit_csr_rd(nfp_prog, NFP_CSR_PSEUDO_RND_NUM); 1767 /* CSR value is read in following immed[gpr, 0] */ 1768 emit_immed(nfp_prog, reg_both(0), 0, 1769 IMMED_WIDTH_ALL, false, IMMED_SHIFT_0B); 1770 emit_immed(nfp_prog, reg_both(1), 0, 1771 IMMED_WIDTH_ALL, false, IMMED_SHIFT_0B); 1772 return 0; 1773 } 1774 1775 static int 1776 nfp_perf_event_output(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1777 { 1778 swreg ptr_type; 1779 u32 ret_tgt; 1780 1781 ptr_type = ur_load_imm_any(nfp_prog, meta->arg1.type, imm_a(nfp_prog)); 1782 1783 ret_tgt = nfp_prog_current_offset(nfp_prog) + 3; 1784 1785 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO + meta->func_id, 1786 2, RELO_BR_HELPER); 1787 1788 /* Load ptr type into A1 */ 1789 wrp_mov(nfp_prog, reg_a(1), ptr_type); 1790 1791 /* Load the return address into B0 */ 1792 wrp_immed_relo(nfp_prog, reg_b(0), ret_tgt, RELO_IMMED_REL); 1793 1794 if (!nfp_prog_confirm_current_offset(nfp_prog, ret_tgt)) 1795 return -EINVAL; 1796 1797 return 0; 1798 } 1799 1800 static int 1801 nfp_queue_select(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1802 { 1803 u32 jmp_tgt; 1804 1805 jmp_tgt = nfp_prog_current_offset(nfp_prog) + 5; 1806 1807 /* Make sure the queue id fits into FW field */ 1808 emit_alu(nfp_prog, reg_none(), reg_a(meta->insn.src_reg * 2), 1809 ALU_OP_AND_NOT_B, reg_imm(0xff)); 1810 emit_br(nfp_prog, BR_BEQ, jmp_tgt, 2); 1811 1812 /* Set the 'queue selected' bit and the queue value */ 1813 emit_shf(nfp_prog, pv_qsel_set(nfp_prog), 1814 pv_qsel_set(nfp_prog), SHF_OP_OR, reg_imm(1), 1815 SHF_SC_L_SHF, PKT_VEL_QSEL_SET_BIT); 1816 emit_ld_field(nfp_prog, 1817 pv_qsel_val(nfp_prog), 0x1, reg_b(meta->insn.src_reg * 2), 1818 SHF_SC_NONE, 0); 1819 /* Delay slots end here, we will jump over next instruction if queue 1820 * value fits into the field. 1821 */ 1822 emit_ld_field(nfp_prog, 1823 pv_qsel_val(nfp_prog), 0x1, reg_imm(NFP_NET_RXR_MAX), 1824 SHF_SC_NONE, 0); 1825 1826 if (!nfp_prog_confirm_current_offset(nfp_prog, jmp_tgt)) 1827 return -EINVAL; 1828 1829 return 0; 1830 } 1831 1832 /* --- Callbacks --- */ 1833 static int mov_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1834 { 1835 const struct bpf_insn *insn = &meta->insn; 1836 u8 dst = insn->dst_reg * 2; 1837 u8 src = insn->src_reg * 2; 1838 1839 if (insn->src_reg == BPF_REG_10) { 1840 swreg stack_depth_reg; 1841 1842 stack_depth_reg = ur_load_imm_any(nfp_prog, 1843 nfp_prog->stack_frame_depth, 1844 stack_imm(nfp_prog)); 1845 emit_alu(nfp_prog, reg_both(dst), stack_reg(nfp_prog), 1846 ALU_OP_ADD, stack_depth_reg); 1847 wrp_immed(nfp_prog, reg_both(dst + 1), 0); 1848 } else { 1849 wrp_reg_mov(nfp_prog, dst, src); 1850 wrp_reg_mov(nfp_prog, dst + 1, src + 1); 1851 } 1852 1853 return 0; 1854 } 1855 1856 static int mov_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1857 { 1858 u64 imm = meta->insn.imm; /* sign extend */ 1859 1860 wrp_immed(nfp_prog, reg_both(meta->insn.dst_reg * 2), imm & ~0U); 1861 wrp_immed(nfp_prog, reg_both(meta->insn.dst_reg * 2 + 1), imm >> 32); 1862 1863 return 0; 1864 } 1865 1866 static int xor_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1867 { 1868 return wrp_alu64_reg(nfp_prog, meta, ALU_OP_XOR); 1869 } 1870 1871 static int xor_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1872 { 1873 return wrp_alu64_imm(nfp_prog, meta, ALU_OP_XOR, !meta->insn.imm); 1874 } 1875 1876 static int and_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1877 { 1878 return wrp_alu64_reg(nfp_prog, meta, ALU_OP_AND); 1879 } 1880 1881 static int and_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1882 { 1883 return wrp_alu64_imm(nfp_prog, meta, ALU_OP_AND, !~meta->insn.imm); 1884 } 1885 1886 static int or_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1887 { 1888 return wrp_alu64_reg(nfp_prog, meta, ALU_OP_OR); 1889 } 1890 1891 static int or_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1892 { 1893 return wrp_alu64_imm(nfp_prog, meta, ALU_OP_OR, !meta->insn.imm); 1894 } 1895 1896 static int add_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1897 { 1898 const struct bpf_insn *insn = &meta->insn; 1899 1900 emit_alu(nfp_prog, reg_both(insn->dst_reg * 2), 1901 reg_a(insn->dst_reg * 2), ALU_OP_ADD, 1902 reg_b(insn->src_reg * 2)); 1903 emit_alu(nfp_prog, reg_both(insn->dst_reg * 2 + 1), 1904 reg_a(insn->dst_reg * 2 + 1), ALU_OP_ADD_C, 1905 reg_b(insn->src_reg * 2 + 1)); 1906 1907 return 0; 1908 } 1909 1910 static int add_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1911 { 1912 const struct bpf_insn *insn = &meta->insn; 1913 u64 imm = insn->imm; /* sign extend */ 1914 1915 wrp_alu_imm(nfp_prog, insn->dst_reg * 2, ALU_OP_ADD, imm & ~0U); 1916 wrp_alu_imm(nfp_prog, insn->dst_reg * 2 + 1, ALU_OP_ADD_C, imm >> 32); 1917 1918 return 0; 1919 } 1920 1921 static int sub_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1922 { 1923 const struct bpf_insn *insn = &meta->insn; 1924 1925 emit_alu(nfp_prog, reg_both(insn->dst_reg * 2), 1926 reg_a(insn->dst_reg * 2), ALU_OP_SUB, 1927 reg_b(insn->src_reg * 2)); 1928 emit_alu(nfp_prog, reg_both(insn->dst_reg * 2 + 1), 1929 reg_a(insn->dst_reg * 2 + 1), ALU_OP_SUB_C, 1930 reg_b(insn->src_reg * 2 + 1)); 1931 1932 return 0; 1933 } 1934 1935 static int sub_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1936 { 1937 const struct bpf_insn *insn = &meta->insn; 1938 u64 imm = insn->imm; /* sign extend */ 1939 1940 wrp_alu_imm(nfp_prog, insn->dst_reg * 2, ALU_OP_SUB, imm & ~0U); 1941 wrp_alu_imm(nfp_prog, insn->dst_reg * 2 + 1, ALU_OP_SUB_C, imm >> 32); 1942 1943 return 0; 1944 } 1945 1946 static int mul_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1947 { 1948 return wrp_mul(nfp_prog, meta, true, true); 1949 } 1950 1951 static int mul_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1952 { 1953 return wrp_mul(nfp_prog, meta, true, false); 1954 } 1955 1956 static int div_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1957 { 1958 const struct bpf_insn *insn = &meta->insn; 1959 1960 return wrp_div_imm(nfp_prog, insn->dst_reg * 2, insn->imm); 1961 } 1962 1963 static int div_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1964 { 1965 /* NOTE: verifier hook has rejected cases for which verifier doesn't 1966 * know whether the source operand is constant or not. 1967 */ 1968 return wrp_div_imm(nfp_prog, meta->insn.dst_reg * 2, meta->umin_src); 1969 } 1970 1971 static int neg_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 1972 { 1973 const struct bpf_insn *insn = &meta->insn; 1974 1975 emit_alu(nfp_prog, reg_both(insn->dst_reg * 2), reg_imm(0), 1976 ALU_OP_SUB, reg_b(insn->dst_reg * 2)); 1977 emit_alu(nfp_prog, reg_both(insn->dst_reg * 2 + 1), reg_imm(0), 1978 ALU_OP_SUB_C, reg_b(insn->dst_reg * 2 + 1)); 1979 1980 return 0; 1981 } 1982 1983 /* Pseudo code: 1984 * if shift_amt >= 32 1985 * dst_high = dst_low << shift_amt[4:0] 1986 * dst_low = 0; 1987 * else 1988 * dst_high = (dst_high, dst_low) >> (32 - shift_amt) 1989 * dst_low = dst_low << shift_amt 1990 * 1991 * The indirect shift will use the same logic at runtime. 1992 */ 1993 static int __shl_imm64(struct nfp_prog *nfp_prog, u8 dst, u8 shift_amt) 1994 { 1995 if (shift_amt < 32) { 1996 emit_shf(nfp_prog, reg_both(dst + 1), reg_a(dst + 1), 1997 SHF_OP_NONE, reg_b(dst), SHF_SC_R_DSHF, 1998 32 - shift_amt); 1999 emit_shf(nfp_prog, reg_both(dst), reg_none(), SHF_OP_NONE, 2000 reg_b(dst), SHF_SC_L_SHF, shift_amt); 2001 } else if (shift_amt == 32) { 2002 wrp_reg_mov(nfp_prog, dst + 1, dst); 2003 wrp_immed(nfp_prog, reg_both(dst), 0); 2004 } else if (shift_amt > 32) { 2005 emit_shf(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_NONE, 2006 reg_b(dst), SHF_SC_L_SHF, shift_amt - 32); 2007 wrp_immed(nfp_prog, reg_both(dst), 0); 2008 } 2009 2010 return 0; 2011 } 2012 2013 static int shl_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2014 { 2015 const struct bpf_insn *insn = &meta->insn; 2016 u8 dst = insn->dst_reg * 2; 2017 2018 return __shl_imm64(nfp_prog, dst, insn->imm); 2019 } 2020 2021 static void shl_reg64_lt32_high(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2022 { 2023 emit_alu(nfp_prog, imm_both(nfp_prog), reg_imm(32), ALU_OP_SUB, 2024 reg_b(src)); 2025 emit_alu(nfp_prog, reg_none(), imm_a(nfp_prog), ALU_OP_OR, reg_imm(0)); 2026 emit_shf_indir(nfp_prog, reg_both(dst + 1), reg_a(dst + 1), SHF_OP_NONE, 2027 reg_b(dst), SHF_SC_R_DSHF); 2028 } 2029 2030 /* NOTE: for indirect left shift, HIGH part should be calculated first. */ 2031 static void shl_reg64_lt32_low(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2032 { 2033 emit_alu(nfp_prog, reg_none(), reg_a(src), ALU_OP_OR, reg_imm(0)); 2034 emit_shf_indir(nfp_prog, reg_both(dst), reg_none(), SHF_OP_NONE, 2035 reg_b(dst), SHF_SC_L_SHF); 2036 } 2037 2038 static void shl_reg64_lt32(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2039 { 2040 shl_reg64_lt32_high(nfp_prog, dst, src); 2041 shl_reg64_lt32_low(nfp_prog, dst, src); 2042 } 2043 2044 static void shl_reg64_ge32(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2045 { 2046 emit_alu(nfp_prog, reg_none(), reg_a(src), ALU_OP_OR, reg_imm(0)); 2047 emit_shf_indir(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_NONE, 2048 reg_b(dst), SHF_SC_L_SHF); 2049 wrp_immed(nfp_prog, reg_both(dst), 0); 2050 } 2051 2052 static int shl_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2053 { 2054 const struct bpf_insn *insn = &meta->insn; 2055 u64 umin, umax; 2056 u8 dst, src; 2057 2058 dst = insn->dst_reg * 2; 2059 umin = meta->umin_src; 2060 umax = meta->umax_src; 2061 if (umin == umax) 2062 return __shl_imm64(nfp_prog, dst, umin); 2063 2064 src = insn->src_reg * 2; 2065 if (umax < 32) { 2066 shl_reg64_lt32(nfp_prog, dst, src); 2067 } else if (umin >= 32) { 2068 shl_reg64_ge32(nfp_prog, dst, src); 2069 } else { 2070 /* Generate different instruction sequences depending on runtime 2071 * value of shift amount. 2072 */ 2073 u16 label_ge32, label_end; 2074 2075 label_ge32 = nfp_prog_current_offset(nfp_prog) + 7; 2076 emit_br_bset(nfp_prog, reg_a(src), 5, label_ge32, 0); 2077 2078 shl_reg64_lt32_high(nfp_prog, dst, src); 2079 label_end = nfp_prog_current_offset(nfp_prog) + 6; 2080 emit_br(nfp_prog, BR_UNC, label_end, 2); 2081 /* shl_reg64_lt32_low packed in delay slot. */ 2082 shl_reg64_lt32_low(nfp_prog, dst, src); 2083 2084 if (!nfp_prog_confirm_current_offset(nfp_prog, label_ge32)) 2085 return -EINVAL; 2086 shl_reg64_ge32(nfp_prog, dst, src); 2087 2088 if (!nfp_prog_confirm_current_offset(nfp_prog, label_end)) 2089 return -EINVAL; 2090 } 2091 2092 return 0; 2093 } 2094 2095 /* Pseudo code: 2096 * if shift_amt >= 32 2097 * dst_high = 0; 2098 * dst_low = dst_high >> shift_amt[4:0] 2099 * else 2100 * dst_high = dst_high >> shift_amt 2101 * dst_low = (dst_high, dst_low) >> shift_amt 2102 * 2103 * The indirect shift will use the same logic at runtime. 2104 */ 2105 static int __shr_imm64(struct nfp_prog *nfp_prog, u8 dst, u8 shift_amt) 2106 { 2107 if (shift_amt < 32) { 2108 emit_shf(nfp_prog, reg_both(dst), reg_a(dst + 1), SHF_OP_NONE, 2109 reg_b(dst), SHF_SC_R_DSHF, shift_amt); 2110 emit_shf(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_NONE, 2111 reg_b(dst + 1), SHF_SC_R_SHF, shift_amt); 2112 } else if (shift_amt == 32) { 2113 wrp_reg_mov(nfp_prog, dst, dst + 1); 2114 wrp_immed(nfp_prog, reg_both(dst + 1), 0); 2115 } else if (shift_amt > 32) { 2116 emit_shf(nfp_prog, reg_both(dst), reg_none(), SHF_OP_NONE, 2117 reg_b(dst + 1), SHF_SC_R_SHF, shift_amt - 32); 2118 wrp_immed(nfp_prog, reg_both(dst + 1), 0); 2119 } 2120 2121 return 0; 2122 } 2123 2124 static int shr_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2125 { 2126 const struct bpf_insn *insn = &meta->insn; 2127 u8 dst = insn->dst_reg * 2; 2128 2129 return __shr_imm64(nfp_prog, dst, insn->imm); 2130 } 2131 2132 /* NOTE: for indirect right shift, LOW part should be calculated first. */ 2133 static void shr_reg64_lt32_high(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2134 { 2135 emit_alu(nfp_prog, reg_none(), reg_a(src), ALU_OP_OR, reg_imm(0)); 2136 emit_shf_indir(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_NONE, 2137 reg_b(dst + 1), SHF_SC_R_SHF); 2138 } 2139 2140 static void shr_reg64_lt32_low(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2141 { 2142 emit_alu(nfp_prog, reg_none(), reg_a(src), ALU_OP_OR, reg_imm(0)); 2143 emit_shf_indir(nfp_prog, reg_both(dst), reg_a(dst + 1), SHF_OP_NONE, 2144 reg_b(dst), SHF_SC_R_DSHF); 2145 } 2146 2147 static void shr_reg64_lt32(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2148 { 2149 shr_reg64_lt32_low(nfp_prog, dst, src); 2150 shr_reg64_lt32_high(nfp_prog, dst, src); 2151 } 2152 2153 static void shr_reg64_ge32(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2154 { 2155 emit_alu(nfp_prog, reg_none(), reg_a(src), ALU_OP_OR, reg_imm(0)); 2156 emit_shf_indir(nfp_prog, reg_both(dst), reg_none(), SHF_OP_NONE, 2157 reg_b(dst + 1), SHF_SC_R_SHF); 2158 wrp_immed(nfp_prog, reg_both(dst + 1), 0); 2159 } 2160 2161 static int shr_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2162 { 2163 const struct bpf_insn *insn = &meta->insn; 2164 u64 umin, umax; 2165 u8 dst, src; 2166 2167 dst = insn->dst_reg * 2; 2168 umin = meta->umin_src; 2169 umax = meta->umax_src; 2170 if (umin == umax) 2171 return __shr_imm64(nfp_prog, dst, umin); 2172 2173 src = insn->src_reg * 2; 2174 if (umax < 32) { 2175 shr_reg64_lt32(nfp_prog, dst, src); 2176 } else if (umin >= 32) { 2177 shr_reg64_ge32(nfp_prog, dst, src); 2178 } else { 2179 /* Generate different instruction sequences depending on runtime 2180 * value of shift amount. 2181 */ 2182 u16 label_ge32, label_end; 2183 2184 label_ge32 = nfp_prog_current_offset(nfp_prog) + 6; 2185 emit_br_bset(nfp_prog, reg_a(src), 5, label_ge32, 0); 2186 shr_reg64_lt32_low(nfp_prog, dst, src); 2187 label_end = nfp_prog_current_offset(nfp_prog) + 6; 2188 emit_br(nfp_prog, BR_UNC, label_end, 2); 2189 /* shr_reg64_lt32_high packed in delay slot. */ 2190 shr_reg64_lt32_high(nfp_prog, dst, src); 2191 2192 if (!nfp_prog_confirm_current_offset(nfp_prog, label_ge32)) 2193 return -EINVAL; 2194 shr_reg64_ge32(nfp_prog, dst, src); 2195 2196 if (!nfp_prog_confirm_current_offset(nfp_prog, label_end)) 2197 return -EINVAL; 2198 } 2199 2200 return 0; 2201 } 2202 2203 /* Code logic is the same as __shr_imm64 except ashr requires signedness bit 2204 * told through PREV_ALU result. 2205 */ 2206 static int __ashr_imm64(struct nfp_prog *nfp_prog, u8 dst, u8 shift_amt) 2207 { 2208 if (shift_amt < 32) { 2209 emit_shf(nfp_prog, reg_both(dst), reg_a(dst + 1), SHF_OP_NONE, 2210 reg_b(dst), SHF_SC_R_DSHF, shift_amt); 2211 /* Set signedness bit. */ 2212 emit_alu(nfp_prog, reg_none(), reg_a(dst + 1), ALU_OP_OR, 2213 reg_imm(0)); 2214 emit_shf(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_ASHR, 2215 reg_b(dst + 1), SHF_SC_R_SHF, shift_amt); 2216 } else if (shift_amt == 32) { 2217 /* NOTE: this also helps setting signedness bit. */ 2218 wrp_reg_mov(nfp_prog, dst, dst + 1); 2219 emit_shf(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_ASHR, 2220 reg_b(dst + 1), SHF_SC_R_SHF, 31); 2221 } else if (shift_amt > 32) { 2222 emit_alu(nfp_prog, reg_none(), reg_a(dst + 1), ALU_OP_OR, 2223 reg_imm(0)); 2224 emit_shf(nfp_prog, reg_both(dst), reg_none(), SHF_OP_ASHR, 2225 reg_b(dst + 1), SHF_SC_R_SHF, shift_amt - 32); 2226 emit_shf(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_ASHR, 2227 reg_b(dst + 1), SHF_SC_R_SHF, 31); 2228 } 2229 2230 return 0; 2231 } 2232 2233 static int ashr_imm64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2234 { 2235 const struct bpf_insn *insn = &meta->insn; 2236 u8 dst = insn->dst_reg * 2; 2237 2238 return __ashr_imm64(nfp_prog, dst, insn->imm); 2239 } 2240 2241 static void ashr_reg64_lt32_high(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2242 { 2243 /* NOTE: the first insn will set both indirect shift amount (source A) 2244 * and signedness bit (MSB of result). 2245 */ 2246 emit_alu(nfp_prog, reg_none(), reg_a(src), ALU_OP_OR, reg_b(dst + 1)); 2247 emit_shf_indir(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_ASHR, 2248 reg_b(dst + 1), SHF_SC_R_SHF); 2249 } 2250 2251 static void ashr_reg64_lt32_low(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2252 { 2253 /* NOTE: it is the same as logic shift because we don't need to shift in 2254 * signedness bit when the shift amount is less than 32. 2255 */ 2256 return shr_reg64_lt32_low(nfp_prog, dst, src); 2257 } 2258 2259 static void ashr_reg64_lt32(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2260 { 2261 ashr_reg64_lt32_low(nfp_prog, dst, src); 2262 ashr_reg64_lt32_high(nfp_prog, dst, src); 2263 } 2264 2265 static void ashr_reg64_ge32(struct nfp_prog *nfp_prog, u8 dst, u8 src) 2266 { 2267 emit_alu(nfp_prog, reg_none(), reg_a(src), ALU_OP_OR, reg_b(dst + 1)); 2268 emit_shf_indir(nfp_prog, reg_both(dst), reg_none(), SHF_OP_ASHR, 2269 reg_b(dst + 1), SHF_SC_R_SHF); 2270 emit_shf(nfp_prog, reg_both(dst + 1), reg_none(), SHF_OP_ASHR, 2271 reg_b(dst + 1), SHF_SC_R_SHF, 31); 2272 } 2273 2274 /* Like ashr_imm64, but need to use indirect shift. */ 2275 static int ashr_reg64(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2276 { 2277 const struct bpf_insn *insn = &meta->insn; 2278 u64 umin, umax; 2279 u8 dst, src; 2280 2281 dst = insn->dst_reg * 2; 2282 umin = meta->umin_src; 2283 umax = meta->umax_src; 2284 if (umin == umax) 2285 return __ashr_imm64(nfp_prog, dst, umin); 2286 2287 src = insn->src_reg * 2; 2288 if (umax < 32) { 2289 ashr_reg64_lt32(nfp_prog, dst, src); 2290 } else if (umin >= 32) { 2291 ashr_reg64_ge32(nfp_prog, dst, src); 2292 } else { 2293 u16 label_ge32, label_end; 2294 2295 label_ge32 = nfp_prog_current_offset(nfp_prog) + 6; 2296 emit_br_bset(nfp_prog, reg_a(src), 5, label_ge32, 0); 2297 ashr_reg64_lt32_low(nfp_prog, dst, src); 2298 label_end = nfp_prog_current_offset(nfp_prog) + 6; 2299 emit_br(nfp_prog, BR_UNC, label_end, 2); 2300 /* ashr_reg64_lt32_high packed in delay slot. */ 2301 ashr_reg64_lt32_high(nfp_prog, dst, src); 2302 2303 if (!nfp_prog_confirm_current_offset(nfp_prog, label_ge32)) 2304 return -EINVAL; 2305 ashr_reg64_ge32(nfp_prog, dst, src); 2306 2307 if (!nfp_prog_confirm_current_offset(nfp_prog, label_end)) 2308 return -EINVAL; 2309 } 2310 2311 return 0; 2312 } 2313 2314 static int mov_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2315 { 2316 const struct bpf_insn *insn = &meta->insn; 2317 2318 wrp_reg_mov(nfp_prog, insn->dst_reg * 2, insn->src_reg * 2); 2319 wrp_immed(nfp_prog, reg_both(insn->dst_reg * 2 + 1), 0); 2320 2321 return 0; 2322 } 2323 2324 static int mov_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2325 { 2326 const struct bpf_insn *insn = &meta->insn; 2327 2328 wrp_immed(nfp_prog, reg_both(insn->dst_reg * 2), insn->imm); 2329 wrp_immed(nfp_prog, reg_both(insn->dst_reg * 2 + 1), 0); 2330 2331 return 0; 2332 } 2333 2334 static int xor_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2335 { 2336 return wrp_alu32_reg(nfp_prog, meta, ALU_OP_XOR); 2337 } 2338 2339 static int xor_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2340 { 2341 return wrp_alu32_imm(nfp_prog, meta, ALU_OP_XOR, !~meta->insn.imm); 2342 } 2343 2344 static int and_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2345 { 2346 return wrp_alu32_reg(nfp_prog, meta, ALU_OP_AND); 2347 } 2348 2349 static int and_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2350 { 2351 return wrp_alu32_imm(nfp_prog, meta, ALU_OP_AND, !~meta->insn.imm); 2352 } 2353 2354 static int or_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2355 { 2356 return wrp_alu32_reg(nfp_prog, meta, ALU_OP_OR); 2357 } 2358 2359 static int or_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2360 { 2361 return wrp_alu32_imm(nfp_prog, meta, ALU_OP_OR, !meta->insn.imm); 2362 } 2363 2364 static int add_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2365 { 2366 return wrp_alu32_reg(nfp_prog, meta, ALU_OP_ADD); 2367 } 2368 2369 static int add_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2370 { 2371 return wrp_alu32_imm(nfp_prog, meta, ALU_OP_ADD, !meta->insn.imm); 2372 } 2373 2374 static int sub_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2375 { 2376 return wrp_alu32_reg(nfp_prog, meta, ALU_OP_SUB); 2377 } 2378 2379 static int sub_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2380 { 2381 return wrp_alu32_imm(nfp_prog, meta, ALU_OP_SUB, !meta->insn.imm); 2382 } 2383 2384 static int mul_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2385 { 2386 return wrp_mul(nfp_prog, meta, false, true); 2387 } 2388 2389 static int mul_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2390 { 2391 return wrp_mul(nfp_prog, meta, false, false); 2392 } 2393 2394 static int div_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2395 { 2396 return div_reg64(nfp_prog, meta); 2397 } 2398 2399 static int div_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2400 { 2401 return div_imm64(nfp_prog, meta); 2402 } 2403 2404 static int neg_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2405 { 2406 u8 dst = meta->insn.dst_reg * 2; 2407 2408 emit_alu(nfp_prog, reg_both(dst), reg_imm(0), ALU_OP_SUB, reg_b(dst)); 2409 wrp_immed(nfp_prog, reg_both(meta->insn.dst_reg * 2 + 1), 0); 2410 2411 return 0; 2412 } 2413 2414 static int shl_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2415 { 2416 const struct bpf_insn *insn = &meta->insn; 2417 2418 if (!insn->imm) 2419 return 1; /* TODO: zero shift means indirect */ 2420 2421 emit_shf(nfp_prog, reg_both(insn->dst_reg * 2), 2422 reg_none(), SHF_OP_NONE, reg_b(insn->dst_reg * 2), 2423 SHF_SC_L_SHF, insn->imm); 2424 wrp_immed(nfp_prog, reg_both(insn->dst_reg * 2 + 1), 0); 2425 2426 return 0; 2427 } 2428 2429 static int end_reg32(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2430 { 2431 const struct bpf_insn *insn = &meta->insn; 2432 u8 gpr = insn->dst_reg * 2; 2433 2434 switch (insn->imm) { 2435 case 16: 2436 emit_ld_field(nfp_prog, reg_both(gpr), 0x9, reg_b(gpr), 2437 SHF_SC_R_ROT, 8); 2438 emit_ld_field(nfp_prog, reg_both(gpr), 0xe, reg_a(gpr), 2439 SHF_SC_R_SHF, 16); 2440 2441 wrp_immed(nfp_prog, reg_both(gpr + 1), 0); 2442 break; 2443 case 32: 2444 wrp_end32(nfp_prog, reg_a(gpr), gpr); 2445 wrp_immed(nfp_prog, reg_both(gpr + 1), 0); 2446 break; 2447 case 64: 2448 wrp_mov(nfp_prog, imm_a(nfp_prog), reg_b(gpr + 1)); 2449 2450 wrp_end32(nfp_prog, reg_a(gpr), gpr + 1); 2451 wrp_end32(nfp_prog, imm_a(nfp_prog), gpr); 2452 break; 2453 } 2454 2455 return 0; 2456 } 2457 2458 static int imm_ld8_part2(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2459 { 2460 struct nfp_insn_meta *prev = nfp_meta_prev(meta); 2461 u32 imm_lo, imm_hi; 2462 u8 dst; 2463 2464 dst = prev->insn.dst_reg * 2; 2465 imm_lo = prev->insn.imm; 2466 imm_hi = meta->insn.imm; 2467 2468 wrp_immed(nfp_prog, reg_both(dst), imm_lo); 2469 2470 /* mov is always 1 insn, load imm may be two, so try to use mov */ 2471 if (imm_hi == imm_lo) 2472 wrp_mov(nfp_prog, reg_both(dst + 1), reg_a(dst)); 2473 else 2474 wrp_immed(nfp_prog, reg_both(dst + 1), imm_hi); 2475 2476 return 0; 2477 } 2478 2479 static int imm_ld8(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2480 { 2481 meta->double_cb = imm_ld8_part2; 2482 return 0; 2483 } 2484 2485 static int data_ld1(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2486 { 2487 return construct_data_ld(nfp_prog, meta->insn.imm, 1); 2488 } 2489 2490 static int data_ld2(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2491 { 2492 return construct_data_ld(nfp_prog, meta->insn.imm, 2); 2493 } 2494 2495 static int data_ld4(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2496 { 2497 return construct_data_ld(nfp_prog, meta->insn.imm, 4); 2498 } 2499 2500 static int data_ind_ld1(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2501 { 2502 return construct_data_ind_ld(nfp_prog, meta->insn.imm, 2503 meta->insn.src_reg * 2, 1); 2504 } 2505 2506 static int data_ind_ld2(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2507 { 2508 return construct_data_ind_ld(nfp_prog, meta->insn.imm, 2509 meta->insn.src_reg * 2, 2); 2510 } 2511 2512 static int data_ind_ld4(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2513 { 2514 return construct_data_ind_ld(nfp_prog, meta->insn.imm, 2515 meta->insn.src_reg * 2, 4); 2516 } 2517 2518 static int 2519 mem_ldx_stack(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2520 unsigned int size, unsigned int ptr_off) 2521 { 2522 return mem_op_stack(nfp_prog, meta, size, ptr_off, 2523 meta->insn.dst_reg * 2, meta->insn.src_reg * 2, 2524 true, wrp_lmem_load); 2525 } 2526 2527 static int mem_ldx_skb(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2528 u8 size) 2529 { 2530 swreg dst = reg_both(meta->insn.dst_reg * 2); 2531 2532 switch (meta->insn.off) { 2533 case offsetof(struct __sk_buff, len): 2534 if (size != FIELD_SIZEOF(struct __sk_buff, len)) 2535 return -EOPNOTSUPP; 2536 wrp_mov(nfp_prog, dst, plen_reg(nfp_prog)); 2537 break; 2538 case offsetof(struct __sk_buff, data): 2539 if (size != FIELD_SIZEOF(struct __sk_buff, data)) 2540 return -EOPNOTSUPP; 2541 wrp_mov(nfp_prog, dst, pptr_reg(nfp_prog)); 2542 break; 2543 case offsetof(struct __sk_buff, data_end): 2544 if (size != FIELD_SIZEOF(struct __sk_buff, data_end)) 2545 return -EOPNOTSUPP; 2546 emit_alu(nfp_prog, dst, 2547 plen_reg(nfp_prog), ALU_OP_ADD, pptr_reg(nfp_prog)); 2548 break; 2549 default: 2550 return -EOPNOTSUPP; 2551 } 2552 2553 wrp_immed(nfp_prog, reg_both(meta->insn.dst_reg * 2 + 1), 0); 2554 2555 return 0; 2556 } 2557 2558 static int mem_ldx_xdp(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2559 u8 size) 2560 { 2561 swreg dst = reg_both(meta->insn.dst_reg * 2); 2562 2563 switch (meta->insn.off) { 2564 case offsetof(struct xdp_md, data): 2565 if (size != FIELD_SIZEOF(struct xdp_md, data)) 2566 return -EOPNOTSUPP; 2567 wrp_mov(nfp_prog, dst, pptr_reg(nfp_prog)); 2568 break; 2569 case offsetof(struct xdp_md, data_end): 2570 if (size != FIELD_SIZEOF(struct xdp_md, data_end)) 2571 return -EOPNOTSUPP; 2572 emit_alu(nfp_prog, dst, 2573 plen_reg(nfp_prog), ALU_OP_ADD, pptr_reg(nfp_prog)); 2574 break; 2575 default: 2576 return -EOPNOTSUPP; 2577 } 2578 2579 wrp_immed(nfp_prog, reg_both(meta->insn.dst_reg * 2 + 1), 0); 2580 2581 return 0; 2582 } 2583 2584 static int 2585 mem_ldx_data(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2586 unsigned int size) 2587 { 2588 swreg tmp_reg; 2589 2590 tmp_reg = re_load_imm_any(nfp_prog, meta->insn.off, imm_b(nfp_prog)); 2591 2592 return data_ld_host_order_addr32(nfp_prog, meta->insn.src_reg * 2, 2593 tmp_reg, meta->insn.dst_reg * 2, size); 2594 } 2595 2596 static int 2597 mem_ldx_emem(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2598 unsigned int size) 2599 { 2600 swreg tmp_reg; 2601 2602 tmp_reg = re_load_imm_any(nfp_prog, meta->insn.off, imm_b(nfp_prog)); 2603 2604 return data_ld_host_order_addr40(nfp_prog, meta->insn.src_reg * 2, 2605 tmp_reg, meta->insn.dst_reg * 2, size); 2606 } 2607 2608 static void 2609 mem_ldx_data_init_pktcache(struct nfp_prog *nfp_prog, 2610 struct nfp_insn_meta *meta) 2611 { 2612 s16 range_start = meta->pkt_cache.range_start; 2613 s16 range_end = meta->pkt_cache.range_end; 2614 swreg src_base, off; 2615 u8 xfer_num, len; 2616 bool indir; 2617 2618 off = re_load_imm_any(nfp_prog, range_start, imm_b(nfp_prog)); 2619 src_base = reg_a(meta->insn.src_reg * 2); 2620 len = range_end - range_start; 2621 xfer_num = round_up(len, REG_WIDTH) / REG_WIDTH; 2622 2623 indir = len > 8 * REG_WIDTH; 2624 /* Setup PREV_ALU for indirect mode. */ 2625 if (indir) 2626 wrp_immed(nfp_prog, reg_none(), 2627 CMD_OVE_LEN | FIELD_PREP(CMD_OV_LEN, xfer_num - 1)); 2628 2629 /* Cache memory into transfer-in registers. */ 2630 emit_cmd_any(nfp_prog, CMD_TGT_READ32_SWAP, CMD_MODE_32b, 0, src_base, 2631 off, xfer_num - 1, CMD_CTX_SWAP, indir); 2632 } 2633 2634 static int 2635 mem_ldx_data_from_pktcache_unaligned(struct nfp_prog *nfp_prog, 2636 struct nfp_insn_meta *meta, 2637 unsigned int size) 2638 { 2639 s16 range_start = meta->pkt_cache.range_start; 2640 s16 insn_off = meta->insn.off - range_start; 2641 swreg dst_lo, dst_hi, src_lo, src_mid; 2642 u8 dst_gpr = meta->insn.dst_reg * 2; 2643 u8 len_lo = size, len_mid = 0; 2644 u8 idx = insn_off / REG_WIDTH; 2645 u8 off = insn_off % REG_WIDTH; 2646 2647 dst_hi = reg_both(dst_gpr + 1); 2648 dst_lo = reg_both(dst_gpr); 2649 src_lo = reg_xfer(idx); 2650 2651 /* The read length could involve as many as three registers. */ 2652 if (size > REG_WIDTH - off) { 2653 /* Calculate the part in the second register. */ 2654 len_lo = REG_WIDTH - off; 2655 len_mid = size - len_lo; 2656 2657 /* Calculate the part in the third register. */ 2658 if (size > 2 * REG_WIDTH - off) 2659 len_mid = REG_WIDTH; 2660 } 2661 2662 wrp_reg_subpart(nfp_prog, dst_lo, src_lo, len_lo, off); 2663 2664 if (!len_mid) { 2665 wrp_immed(nfp_prog, dst_hi, 0); 2666 return 0; 2667 } 2668 2669 src_mid = reg_xfer(idx + 1); 2670 2671 if (size <= REG_WIDTH) { 2672 wrp_reg_or_subpart(nfp_prog, dst_lo, src_mid, len_mid, len_lo); 2673 wrp_immed(nfp_prog, dst_hi, 0); 2674 } else { 2675 swreg src_hi = reg_xfer(idx + 2); 2676 2677 wrp_reg_or_subpart(nfp_prog, dst_lo, src_mid, 2678 REG_WIDTH - len_lo, len_lo); 2679 wrp_reg_subpart(nfp_prog, dst_hi, src_mid, len_lo, 2680 REG_WIDTH - len_lo); 2681 wrp_reg_or_subpart(nfp_prog, dst_hi, src_hi, REG_WIDTH - len_lo, 2682 len_lo); 2683 } 2684 2685 return 0; 2686 } 2687 2688 static int 2689 mem_ldx_data_from_pktcache_aligned(struct nfp_prog *nfp_prog, 2690 struct nfp_insn_meta *meta, 2691 unsigned int size) 2692 { 2693 swreg dst_lo, dst_hi, src_lo; 2694 u8 dst_gpr, idx; 2695 2696 idx = (meta->insn.off - meta->pkt_cache.range_start) / REG_WIDTH; 2697 dst_gpr = meta->insn.dst_reg * 2; 2698 dst_hi = reg_both(dst_gpr + 1); 2699 dst_lo = reg_both(dst_gpr); 2700 src_lo = reg_xfer(idx); 2701 2702 if (size < REG_WIDTH) { 2703 wrp_reg_subpart(nfp_prog, dst_lo, src_lo, size, 0); 2704 wrp_immed(nfp_prog, dst_hi, 0); 2705 } else if (size == REG_WIDTH) { 2706 wrp_mov(nfp_prog, dst_lo, src_lo); 2707 wrp_immed(nfp_prog, dst_hi, 0); 2708 } else { 2709 swreg src_hi = reg_xfer(idx + 1); 2710 2711 wrp_mov(nfp_prog, dst_lo, src_lo); 2712 wrp_mov(nfp_prog, dst_hi, src_hi); 2713 } 2714 2715 return 0; 2716 } 2717 2718 static int 2719 mem_ldx_data_from_pktcache(struct nfp_prog *nfp_prog, 2720 struct nfp_insn_meta *meta, unsigned int size) 2721 { 2722 u8 off = meta->insn.off - meta->pkt_cache.range_start; 2723 2724 if (IS_ALIGNED(off, REG_WIDTH)) 2725 return mem_ldx_data_from_pktcache_aligned(nfp_prog, meta, size); 2726 2727 return mem_ldx_data_from_pktcache_unaligned(nfp_prog, meta, size); 2728 } 2729 2730 static int 2731 mem_ldx(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2732 unsigned int size) 2733 { 2734 if (meta->ldst_gather_len) 2735 return nfp_cpp_memcpy(nfp_prog, meta); 2736 2737 if (meta->ptr.type == PTR_TO_CTX) { 2738 if (nfp_prog->type == BPF_PROG_TYPE_XDP) 2739 return mem_ldx_xdp(nfp_prog, meta, size); 2740 else 2741 return mem_ldx_skb(nfp_prog, meta, size); 2742 } 2743 2744 if (meta->ptr.type == PTR_TO_PACKET) { 2745 if (meta->pkt_cache.range_end) { 2746 if (meta->pkt_cache.do_init) 2747 mem_ldx_data_init_pktcache(nfp_prog, meta); 2748 2749 return mem_ldx_data_from_pktcache(nfp_prog, meta, size); 2750 } else { 2751 return mem_ldx_data(nfp_prog, meta, size); 2752 } 2753 } 2754 2755 if (meta->ptr.type == PTR_TO_STACK) 2756 return mem_ldx_stack(nfp_prog, meta, size, 2757 meta->ptr.off + meta->ptr.var_off.value); 2758 2759 if (meta->ptr.type == PTR_TO_MAP_VALUE) 2760 return mem_ldx_emem(nfp_prog, meta, size); 2761 2762 return -EOPNOTSUPP; 2763 } 2764 2765 static int mem_ldx1(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2766 { 2767 return mem_ldx(nfp_prog, meta, 1); 2768 } 2769 2770 static int mem_ldx2(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2771 { 2772 return mem_ldx(nfp_prog, meta, 2); 2773 } 2774 2775 static int mem_ldx4(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2776 { 2777 return mem_ldx(nfp_prog, meta, 4); 2778 } 2779 2780 static int mem_ldx8(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2781 { 2782 return mem_ldx(nfp_prog, meta, 8); 2783 } 2784 2785 static int 2786 mem_st_data(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2787 unsigned int size) 2788 { 2789 u64 imm = meta->insn.imm; /* sign extend */ 2790 swreg off_reg; 2791 2792 off_reg = re_load_imm_any(nfp_prog, meta->insn.off, imm_b(nfp_prog)); 2793 2794 return data_st_host_order(nfp_prog, meta->insn.dst_reg * 2, off_reg, 2795 imm, size); 2796 } 2797 2798 static int mem_st(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2799 unsigned int size) 2800 { 2801 if (meta->ptr.type == PTR_TO_PACKET) 2802 return mem_st_data(nfp_prog, meta, size); 2803 2804 return -EOPNOTSUPP; 2805 } 2806 2807 static int mem_st1(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2808 { 2809 return mem_st(nfp_prog, meta, 1); 2810 } 2811 2812 static int mem_st2(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2813 { 2814 return mem_st(nfp_prog, meta, 2); 2815 } 2816 2817 static int mem_st4(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2818 { 2819 return mem_st(nfp_prog, meta, 4); 2820 } 2821 2822 static int mem_st8(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2823 { 2824 return mem_st(nfp_prog, meta, 8); 2825 } 2826 2827 static int 2828 mem_stx_data(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2829 unsigned int size) 2830 { 2831 swreg off_reg; 2832 2833 off_reg = re_load_imm_any(nfp_prog, meta->insn.off, imm_b(nfp_prog)); 2834 2835 return data_stx_host_order(nfp_prog, meta->insn.dst_reg * 2, off_reg, 2836 meta->insn.src_reg * 2, size); 2837 } 2838 2839 static int 2840 mem_stx_stack(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2841 unsigned int size, unsigned int ptr_off) 2842 { 2843 return mem_op_stack(nfp_prog, meta, size, ptr_off, 2844 meta->insn.src_reg * 2, meta->insn.dst_reg * 2, 2845 false, wrp_lmem_store); 2846 } 2847 2848 static int mem_stx_xdp(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2849 { 2850 switch (meta->insn.off) { 2851 case offsetof(struct xdp_md, rx_queue_index): 2852 return nfp_queue_select(nfp_prog, meta); 2853 } 2854 2855 WARN_ON_ONCE(1); /* verifier should have rejected bad accesses */ 2856 return -EOPNOTSUPP; 2857 } 2858 2859 static int 2860 mem_stx(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, 2861 unsigned int size) 2862 { 2863 if (meta->ptr.type == PTR_TO_PACKET) 2864 return mem_stx_data(nfp_prog, meta, size); 2865 2866 if (meta->ptr.type == PTR_TO_STACK) 2867 return mem_stx_stack(nfp_prog, meta, size, 2868 meta->ptr.off + meta->ptr.var_off.value); 2869 2870 return -EOPNOTSUPP; 2871 } 2872 2873 static int mem_stx1(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2874 { 2875 return mem_stx(nfp_prog, meta, 1); 2876 } 2877 2878 static int mem_stx2(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2879 { 2880 return mem_stx(nfp_prog, meta, 2); 2881 } 2882 2883 static int mem_stx4(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2884 { 2885 if (meta->ptr.type == PTR_TO_CTX) 2886 if (nfp_prog->type == BPF_PROG_TYPE_XDP) 2887 return mem_stx_xdp(nfp_prog, meta); 2888 return mem_stx(nfp_prog, meta, 4); 2889 } 2890 2891 static int mem_stx8(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2892 { 2893 return mem_stx(nfp_prog, meta, 8); 2894 } 2895 2896 static int 2897 mem_xadd(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta, bool is64) 2898 { 2899 u8 dst_gpr = meta->insn.dst_reg * 2; 2900 u8 src_gpr = meta->insn.src_reg * 2; 2901 unsigned int full_add, out; 2902 swreg addra, addrb, off; 2903 2904 off = ur_load_imm_any(nfp_prog, meta->insn.off, imm_b(nfp_prog)); 2905 2906 /* We can fit 16 bits into command immediate, if we know the immediate 2907 * is guaranteed to either always or never fit into 16 bit we only 2908 * generate code to handle that particular case, otherwise generate 2909 * code for both. 2910 */ 2911 out = nfp_prog_current_offset(nfp_prog); 2912 full_add = nfp_prog_current_offset(nfp_prog); 2913 2914 if (meta->insn.off) { 2915 out += 2; 2916 full_add += 2; 2917 } 2918 if (meta->xadd_maybe_16bit) { 2919 out += 3; 2920 full_add += 3; 2921 } 2922 if (meta->xadd_over_16bit) 2923 out += 2 + is64; 2924 if (meta->xadd_maybe_16bit && meta->xadd_over_16bit) { 2925 out += 5; 2926 full_add += 5; 2927 } 2928 2929 /* Generate the branch for choosing add_imm vs add */ 2930 if (meta->xadd_maybe_16bit && meta->xadd_over_16bit) { 2931 swreg max_imm = imm_a(nfp_prog); 2932 2933 wrp_immed(nfp_prog, max_imm, 0xffff); 2934 emit_alu(nfp_prog, reg_none(), 2935 max_imm, ALU_OP_SUB, reg_b(src_gpr)); 2936 emit_alu(nfp_prog, reg_none(), 2937 reg_imm(0), ALU_OP_SUB_C, reg_b(src_gpr + 1)); 2938 emit_br(nfp_prog, BR_BLO, full_add, meta->insn.off ? 2 : 0); 2939 /* defer for add */ 2940 } 2941 2942 /* If insn has an offset add to the address */ 2943 if (!meta->insn.off) { 2944 addra = reg_a(dst_gpr); 2945 addrb = reg_b(dst_gpr + 1); 2946 } else { 2947 emit_alu(nfp_prog, imma_a(nfp_prog), 2948 reg_a(dst_gpr), ALU_OP_ADD, off); 2949 emit_alu(nfp_prog, imma_b(nfp_prog), 2950 reg_a(dst_gpr + 1), ALU_OP_ADD_C, reg_imm(0)); 2951 addra = imma_a(nfp_prog); 2952 addrb = imma_b(nfp_prog); 2953 } 2954 2955 /* Generate the add_imm if 16 bits are possible */ 2956 if (meta->xadd_maybe_16bit) { 2957 swreg prev_alu = imm_a(nfp_prog); 2958 2959 wrp_immed(nfp_prog, prev_alu, 2960 FIELD_PREP(CMD_OVE_DATA, 2) | 2961 CMD_OVE_LEN | 2962 FIELD_PREP(CMD_OV_LEN, 0x8 | is64 << 2)); 2963 wrp_reg_or_subpart(nfp_prog, prev_alu, reg_b(src_gpr), 2, 2); 2964 emit_cmd_indir(nfp_prog, CMD_TGT_ADD_IMM, CMD_MODE_40b_BA, 0, 2965 addra, addrb, 0, CMD_CTX_NO_SWAP); 2966 2967 if (meta->xadd_over_16bit) 2968 emit_br(nfp_prog, BR_UNC, out, 0); 2969 } 2970 2971 if (!nfp_prog_confirm_current_offset(nfp_prog, full_add)) 2972 return -EINVAL; 2973 2974 /* Generate the add if 16 bits are not guaranteed */ 2975 if (meta->xadd_over_16bit) { 2976 emit_cmd(nfp_prog, CMD_TGT_ADD, CMD_MODE_40b_BA, 0, 2977 addra, addrb, is64 << 2, 2978 is64 ? CMD_CTX_SWAP_DEFER2 : CMD_CTX_SWAP_DEFER1); 2979 2980 wrp_mov(nfp_prog, reg_xfer(0), reg_a(src_gpr)); 2981 if (is64) 2982 wrp_mov(nfp_prog, reg_xfer(1), reg_a(src_gpr + 1)); 2983 } 2984 2985 if (!nfp_prog_confirm_current_offset(nfp_prog, out)) 2986 return -EINVAL; 2987 2988 return 0; 2989 } 2990 2991 static int mem_xadd4(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2992 { 2993 return mem_xadd(nfp_prog, meta, false); 2994 } 2995 2996 static int mem_xadd8(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 2997 { 2998 return mem_xadd(nfp_prog, meta, true); 2999 } 3000 3001 static int jump(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3002 { 3003 emit_br(nfp_prog, BR_UNC, meta->insn.off, 0); 3004 3005 return 0; 3006 } 3007 3008 static int jeq_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3009 { 3010 const struct bpf_insn *insn = &meta->insn; 3011 u64 imm = insn->imm; /* sign extend */ 3012 swreg or1, or2, tmp_reg; 3013 3014 or1 = reg_a(insn->dst_reg * 2); 3015 or2 = reg_b(insn->dst_reg * 2 + 1); 3016 3017 if (imm & ~0U) { 3018 tmp_reg = ur_load_imm_any(nfp_prog, imm & ~0U, imm_b(nfp_prog)); 3019 emit_alu(nfp_prog, imm_a(nfp_prog), 3020 reg_a(insn->dst_reg * 2), ALU_OP_XOR, tmp_reg); 3021 or1 = imm_a(nfp_prog); 3022 } 3023 3024 if (imm >> 32) { 3025 tmp_reg = ur_load_imm_any(nfp_prog, imm >> 32, imm_b(nfp_prog)); 3026 emit_alu(nfp_prog, imm_b(nfp_prog), 3027 reg_a(insn->dst_reg * 2 + 1), ALU_OP_XOR, tmp_reg); 3028 or2 = imm_b(nfp_prog); 3029 } 3030 3031 emit_alu(nfp_prog, reg_none(), or1, ALU_OP_OR, or2); 3032 emit_br(nfp_prog, BR_BEQ, insn->off, 0); 3033 3034 return 0; 3035 } 3036 3037 static int jset_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3038 { 3039 const struct bpf_insn *insn = &meta->insn; 3040 u64 imm = insn->imm; /* sign extend */ 3041 swreg tmp_reg; 3042 3043 if (!imm) { 3044 meta->skip = true; 3045 return 0; 3046 } 3047 3048 if (imm & ~0U) { 3049 tmp_reg = ur_load_imm_any(nfp_prog, imm & ~0U, imm_b(nfp_prog)); 3050 emit_alu(nfp_prog, reg_none(), 3051 reg_a(insn->dst_reg * 2), ALU_OP_AND, tmp_reg); 3052 emit_br(nfp_prog, BR_BNE, insn->off, 0); 3053 } 3054 3055 if (imm >> 32) { 3056 tmp_reg = ur_load_imm_any(nfp_prog, imm >> 32, imm_b(nfp_prog)); 3057 emit_alu(nfp_prog, reg_none(), 3058 reg_a(insn->dst_reg * 2 + 1), ALU_OP_AND, tmp_reg); 3059 emit_br(nfp_prog, BR_BNE, insn->off, 0); 3060 } 3061 3062 return 0; 3063 } 3064 3065 static int jne_imm(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3066 { 3067 const struct bpf_insn *insn = &meta->insn; 3068 u64 imm = insn->imm; /* sign extend */ 3069 swreg tmp_reg; 3070 3071 if (!imm) { 3072 emit_alu(nfp_prog, reg_none(), reg_a(insn->dst_reg * 2), 3073 ALU_OP_OR, reg_b(insn->dst_reg * 2 + 1)); 3074 emit_br(nfp_prog, BR_BNE, insn->off, 0); 3075 return 0; 3076 } 3077 3078 tmp_reg = ur_load_imm_any(nfp_prog, imm & ~0U, imm_b(nfp_prog)); 3079 emit_alu(nfp_prog, reg_none(), 3080 reg_a(insn->dst_reg * 2), ALU_OP_XOR, tmp_reg); 3081 emit_br(nfp_prog, BR_BNE, insn->off, 0); 3082 3083 tmp_reg = ur_load_imm_any(nfp_prog, imm >> 32, imm_b(nfp_prog)); 3084 emit_alu(nfp_prog, reg_none(), 3085 reg_a(insn->dst_reg * 2 + 1), ALU_OP_XOR, tmp_reg); 3086 emit_br(nfp_prog, BR_BNE, insn->off, 0); 3087 3088 return 0; 3089 } 3090 3091 static int jeq_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3092 { 3093 const struct bpf_insn *insn = &meta->insn; 3094 3095 emit_alu(nfp_prog, imm_a(nfp_prog), reg_a(insn->dst_reg * 2), 3096 ALU_OP_XOR, reg_b(insn->src_reg * 2)); 3097 emit_alu(nfp_prog, imm_b(nfp_prog), reg_a(insn->dst_reg * 2 + 1), 3098 ALU_OP_XOR, reg_b(insn->src_reg * 2 + 1)); 3099 emit_alu(nfp_prog, reg_none(), 3100 imm_a(nfp_prog), ALU_OP_OR, imm_b(nfp_prog)); 3101 emit_br(nfp_prog, BR_BEQ, insn->off, 0); 3102 3103 return 0; 3104 } 3105 3106 static int jset_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3107 { 3108 return wrp_test_reg(nfp_prog, meta, ALU_OP_AND, BR_BNE); 3109 } 3110 3111 static int jne_reg(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3112 { 3113 return wrp_test_reg(nfp_prog, meta, ALU_OP_XOR, BR_BNE); 3114 } 3115 3116 static int 3117 bpf_to_bpf_call(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3118 { 3119 u32 ret_tgt, stack_depth; 3120 swreg tmp_reg; 3121 3122 stack_depth = round_up(nfp_prog->stack_frame_depth, STACK_FRAME_ALIGN); 3123 /* Space for saving the return address is accounted for by the callee, 3124 * so stack_depth can be zero for the main function. 3125 */ 3126 if (stack_depth) { 3127 tmp_reg = ur_load_imm_any(nfp_prog, stack_depth, 3128 stack_imm(nfp_prog)); 3129 emit_alu(nfp_prog, stack_reg(nfp_prog), 3130 stack_reg(nfp_prog), ALU_OP_ADD, tmp_reg); 3131 emit_csr_wr(nfp_prog, stack_reg(nfp_prog), 3132 NFP_CSR_ACT_LM_ADDR0); 3133 } 3134 3135 /* The following steps are performed: 3136 * 1. Put the start offset of the callee into imm_b(). This will 3137 * require a fixup step, as we do not necessarily know this 3138 * address yet. 3139 * 2. Put the return address from the callee to the caller into 3140 * register ret_reg(). 3141 * 3. (After defer slots are consumed) Jump to the subroutine that 3142 * pushes the registers to the stack. 3143 * The subroutine acts as a trampoline, and returns to the address in 3144 * imm_b(), i.e. jumps to the callee. 3145 * 3146 * Using ret_reg() to pass the return address to the callee is set here 3147 * as a convention. The callee can then push this address onto its 3148 * stack frame in its prologue. The advantages of passing the return 3149 * address through ret_reg(), instead of pushing it to the stack right 3150 * here, are the following: 3151 * - It looks cleaner. 3152 * - If the called function is called multiple time, we get a lower 3153 * program size. 3154 * - We save two no-op instructions that should be added just before 3155 * the emit_br() when stack depth is not null otherwise. 3156 * - If we ever find a register to hold the return address during whole 3157 * execution of the callee, we will not have to push the return 3158 * address to the stack for leaf functions. 3159 */ 3160 ret_tgt = nfp_prog_current_offset(nfp_prog) + 3; 3161 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO, 2, 3162 RELO_BR_GO_CALL_PUSH_REGS); 3163 wrp_immed_relo(nfp_prog, imm_b(nfp_prog), 0, RELO_IMMED_REL); 3164 wrp_immed_relo(nfp_prog, ret_reg(nfp_prog), ret_tgt, RELO_IMMED_REL); 3165 3166 if (!nfp_prog_confirm_current_offset(nfp_prog, ret_tgt)) 3167 return -EINVAL; 3168 3169 if (stack_depth) { 3170 tmp_reg = ur_load_imm_any(nfp_prog, stack_depth, 3171 stack_imm(nfp_prog)); 3172 emit_alu(nfp_prog, stack_reg(nfp_prog), 3173 stack_reg(nfp_prog), ALU_OP_SUB, tmp_reg); 3174 emit_csr_wr(nfp_prog, stack_reg(nfp_prog), 3175 NFP_CSR_ACT_LM_ADDR0); 3176 wrp_nops(nfp_prog, 3); 3177 } 3178 3179 return 0; 3180 } 3181 3182 static int helper_call(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3183 { 3184 switch (meta->insn.imm) { 3185 case BPF_FUNC_xdp_adjust_head: 3186 return adjust_head(nfp_prog, meta); 3187 case BPF_FUNC_xdp_adjust_tail: 3188 return adjust_tail(nfp_prog, meta); 3189 case BPF_FUNC_map_lookup_elem: 3190 case BPF_FUNC_map_update_elem: 3191 case BPF_FUNC_map_delete_elem: 3192 return map_call_stack_common(nfp_prog, meta); 3193 case BPF_FUNC_get_prandom_u32: 3194 return nfp_get_prandom_u32(nfp_prog, meta); 3195 case BPF_FUNC_perf_event_output: 3196 return nfp_perf_event_output(nfp_prog, meta); 3197 default: 3198 WARN_ONCE(1, "verifier allowed unsupported function\n"); 3199 return -EOPNOTSUPP; 3200 } 3201 } 3202 3203 static int call(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3204 { 3205 if (is_mbpf_pseudo_call(meta)) 3206 return bpf_to_bpf_call(nfp_prog, meta); 3207 else 3208 return helper_call(nfp_prog, meta); 3209 } 3210 3211 static bool nfp_is_main_function(struct nfp_insn_meta *meta) 3212 { 3213 return meta->subprog_idx == 0; 3214 } 3215 3216 static int goto_out(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3217 { 3218 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO, 0, RELO_BR_GO_OUT); 3219 3220 return 0; 3221 } 3222 3223 static int 3224 nfp_subprog_epilogue(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3225 { 3226 /* Pop R6~R9 to the stack via related subroutine. 3227 * Pop return address for BPF-to-BPF call from the stack and load it 3228 * into ret_reg() before we jump. This means that the subroutine does 3229 * not come back here, we make it jump back to the subprogram caller 3230 * directly! 3231 */ 3232 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO, 1, 3233 RELO_BR_GO_CALL_POP_REGS); 3234 wrp_mov(nfp_prog, ret_reg(nfp_prog), reg_lm(0, 0)); 3235 3236 return 0; 3237 } 3238 3239 static int jmp_exit(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3240 { 3241 if (nfp_is_main_function(meta)) 3242 return goto_out(nfp_prog, meta); 3243 else 3244 return nfp_subprog_epilogue(nfp_prog, meta); 3245 } 3246 3247 static const instr_cb_t instr_cb[256] = { 3248 [BPF_ALU64 | BPF_MOV | BPF_X] = mov_reg64, 3249 [BPF_ALU64 | BPF_MOV | BPF_K] = mov_imm64, 3250 [BPF_ALU64 | BPF_XOR | BPF_X] = xor_reg64, 3251 [BPF_ALU64 | BPF_XOR | BPF_K] = xor_imm64, 3252 [BPF_ALU64 | BPF_AND | BPF_X] = and_reg64, 3253 [BPF_ALU64 | BPF_AND | BPF_K] = and_imm64, 3254 [BPF_ALU64 | BPF_OR | BPF_X] = or_reg64, 3255 [BPF_ALU64 | BPF_OR | BPF_K] = or_imm64, 3256 [BPF_ALU64 | BPF_ADD | BPF_X] = add_reg64, 3257 [BPF_ALU64 | BPF_ADD | BPF_K] = add_imm64, 3258 [BPF_ALU64 | BPF_SUB | BPF_X] = sub_reg64, 3259 [BPF_ALU64 | BPF_SUB | BPF_K] = sub_imm64, 3260 [BPF_ALU64 | BPF_MUL | BPF_X] = mul_reg64, 3261 [BPF_ALU64 | BPF_MUL | BPF_K] = mul_imm64, 3262 [BPF_ALU64 | BPF_DIV | BPF_X] = div_reg64, 3263 [BPF_ALU64 | BPF_DIV | BPF_K] = div_imm64, 3264 [BPF_ALU64 | BPF_NEG] = neg_reg64, 3265 [BPF_ALU64 | BPF_LSH | BPF_X] = shl_reg64, 3266 [BPF_ALU64 | BPF_LSH | BPF_K] = shl_imm64, 3267 [BPF_ALU64 | BPF_RSH | BPF_X] = shr_reg64, 3268 [BPF_ALU64 | BPF_RSH | BPF_K] = shr_imm64, 3269 [BPF_ALU64 | BPF_ARSH | BPF_X] = ashr_reg64, 3270 [BPF_ALU64 | BPF_ARSH | BPF_K] = ashr_imm64, 3271 [BPF_ALU | BPF_MOV | BPF_X] = mov_reg, 3272 [BPF_ALU | BPF_MOV | BPF_K] = mov_imm, 3273 [BPF_ALU | BPF_XOR | BPF_X] = xor_reg, 3274 [BPF_ALU | BPF_XOR | BPF_K] = xor_imm, 3275 [BPF_ALU | BPF_AND | BPF_X] = and_reg, 3276 [BPF_ALU | BPF_AND | BPF_K] = and_imm, 3277 [BPF_ALU | BPF_OR | BPF_X] = or_reg, 3278 [BPF_ALU | BPF_OR | BPF_K] = or_imm, 3279 [BPF_ALU | BPF_ADD | BPF_X] = add_reg, 3280 [BPF_ALU | BPF_ADD | BPF_K] = add_imm, 3281 [BPF_ALU | BPF_SUB | BPF_X] = sub_reg, 3282 [BPF_ALU | BPF_SUB | BPF_K] = sub_imm, 3283 [BPF_ALU | BPF_MUL | BPF_X] = mul_reg, 3284 [BPF_ALU | BPF_MUL | BPF_K] = mul_imm, 3285 [BPF_ALU | BPF_DIV | BPF_X] = div_reg, 3286 [BPF_ALU | BPF_DIV | BPF_K] = div_imm, 3287 [BPF_ALU | BPF_NEG] = neg_reg, 3288 [BPF_ALU | BPF_LSH | BPF_K] = shl_imm, 3289 [BPF_ALU | BPF_END | BPF_X] = end_reg32, 3290 [BPF_LD | BPF_IMM | BPF_DW] = imm_ld8, 3291 [BPF_LD | BPF_ABS | BPF_B] = data_ld1, 3292 [BPF_LD | BPF_ABS | BPF_H] = data_ld2, 3293 [BPF_LD | BPF_ABS | BPF_W] = data_ld4, 3294 [BPF_LD | BPF_IND | BPF_B] = data_ind_ld1, 3295 [BPF_LD | BPF_IND | BPF_H] = data_ind_ld2, 3296 [BPF_LD | BPF_IND | BPF_W] = data_ind_ld4, 3297 [BPF_LDX | BPF_MEM | BPF_B] = mem_ldx1, 3298 [BPF_LDX | BPF_MEM | BPF_H] = mem_ldx2, 3299 [BPF_LDX | BPF_MEM | BPF_W] = mem_ldx4, 3300 [BPF_LDX | BPF_MEM | BPF_DW] = mem_ldx8, 3301 [BPF_STX | BPF_MEM | BPF_B] = mem_stx1, 3302 [BPF_STX | BPF_MEM | BPF_H] = mem_stx2, 3303 [BPF_STX | BPF_MEM | BPF_W] = mem_stx4, 3304 [BPF_STX | BPF_MEM | BPF_DW] = mem_stx8, 3305 [BPF_STX | BPF_XADD | BPF_W] = mem_xadd4, 3306 [BPF_STX | BPF_XADD | BPF_DW] = mem_xadd8, 3307 [BPF_ST | BPF_MEM | BPF_B] = mem_st1, 3308 [BPF_ST | BPF_MEM | BPF_H] = mem_st2, 3309 [BPF_ST | BPF_MEM | BPF_W] = mem_st4, 3310 [BPF_ST | BPF_MEM | BPF_DW] = mem_st8, 3311 [BPF_JMP | BPF_JA | BPF_K] = jump, 3312 [BPF_JMP | BPF_JEQ | BPF_K] = jeq_imm, 3313 [BPF_JMP | BPF_JGT | BPF_K] = cmp_imm, 3314 [BPF_JMP | BPF_JGE | BPF_K] = cmp_imm, 3315 [BPF_JMP | BPF_JLT | BPF_K] = cmp_imm, 3316 [BPF_JMP | BPF_JLE | BPF_K] = cmp_imm, 3317 [BPF_JMP | BPF_JSGT | BPF_K] = cmp_imm, 3318 [BPF_JMP | BPF_JSGE | BPF_K] = cmp_imm, 3319 [BPF_JMP | BPF_JSLT | BPF_K] = cmp_imm, 3320 [BPF_JMP | BPF_JSLE | BPF_K] = cmp_imm, 3321 [BPF_JMP | BPF_JSET | BPF_K] = jset_imm, 3322 [BPF_JMP | BPF_JNE | BPF_K] = jne_imm, 3323 [BPF_JMP | BPF_JEQ | BPF_X] = jeq_reg, 3324 [BPF_JMP | BPF_JGT | BPF_X] = cmp_reg, 3325 [BPF_JMP | BPF_JGE | BPF_X] = cmp_reg, 3326 [BPF_JMP | BPF_JLT | BPF_X] = cmp_reg, 3327 [BPF_JMP | BPF_JLE | BPF_X] = cmp_reg, 3328 [BPF_JMP | BPF_JSGT | BPF_X] = cmp_reg, 3329 [BPF_JMP | BPF_JSGE | BPF_X] = cmp_reg, 3330 [BPF_JMP | BPF_JSLT | BPF_X] = cmp_reg, 3331 [BPF_JMP | BPF_JSLE | BPF_X] = cmp_reg, 3332 [BPF_JMP | BPF_JSET | BPF_X] = jset_reg, 3333 [BPF_JMP | BPF_JNE | BPF_X] = jne_reg, 3334 [BPF_JMP | BPF_CALL] = call, 3335 [BPF_JMP | BPF_EXIT] = jmp_exit, 3336 }; 3337 3338 /* --- Assembler logic --- */ 3339 static int nfp_fixup_branches(struct nfp_prog *nfp_prog) 3340 { 3341 struct nfp_insn_meta *meta, *jmp_dst; 3342 u32 idx, br_idx; 3343 3344 list_for_each_entry(meta, &nfp_prog->insns, l) { 3345 if (meta->skip) 3346 continue; 3347 if (meta->insn.code == (BPF_JMP | BPF_CALL)) 3348 continue; 3349 if (BPF_CLASS(meta->insn.code) != BPF_JMP) 3350 continue; 3351 3352 if (list_is_last(&meta->l, &nfp_prog->insns)) 3353 br_idx = nfp_prog->last_bpf_off; 3354 else 3355 br_idx = list_next_entry(meta, l)->off - 1; 3356 3357 if (!nfp_is_br(nfp_prog->prog[br_idx])) { 3358 pr_err("Fixup found block not ending in branch %d %02x %016llx!!\n", 3359 br_idx, meta->insn.code, nfp_prog->prog[br_idx]); 3360 return -ELOOP; 3361 } 3362 /* Leave special branches for later */ 3363 if (FIELD_GET(OP_RELO_TYPE, nfp_prog->prog[br_idx]) != 3364 RELO_BR_REL) 3365 continue; 3366 3367 if (!meta->jmp_dst) { 3368 pr_err("Non-exit jump doesn't have destination info recorded!!\n"); 3369 return -ELOOP; 3370 } 3371 3372 jmp_dst = meta->jmp_dst; 3373 3374 if (jmp_dst->skip) { 3375 pr_err("Branch landing on removed instruction!!\n"); 3376 return -ELOOP; 3377 } 3378 3379 for (idx = meta->off; idx <= br_idx; idx++) { 3380 if (!nfp_is_br(nfp_prog->prog[idx])) 3381 continue; 3382 br_set_offset(&nfp_prog->prog[idx], jmp_dst->off); 3383 } 3384 } 3385 3386 return 0; 3387 } 3388 3389 static void nfp_intro(struct nfp_prog *nfp_prog) 3390 { 3391 wrp_immed(nfp_prog, plen_reg(nfp_prog), GENMASK(13, 0)); 3392 emit_alu(nfp_prog, plen_reg(nfp_prog), 3393 plen_reg(nfp_prog), ALU_OP_AND, pv_len(nfp_prog)); 3394 } 3395 3396 static void 3397 nfp_subprog_prologue(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3398 { 3399 /* Save return address into the stack. */ 3400 wrp_mov(nfp_prog, reg_lm(0, 0), ret_reg(nfp_prog)); 3401 } 3402 3403 static void 3404 nfp_start_subprog(struct nfp_prog *nfp_prog, struct nfp_insn_meta *meta) 3405 { 3406 unsigned int depth = nfp_prog->subprog[meta->subprog_idx].stack_depth; 3407 3408 nfp_prog->stack_frame_depth = round_up(depth, 4); 3409 nfp_subprog_prologue(nfp_prog, meta); 3410 } 3411 3412 bool nfp_is_subprog_start(struct nfp_insn_meta *meta) 3413 { 3414 return meta->flags & FLAG_INSN_IS_SUBPROG_START; 3415 } 3416 3417 static void nfp_outro_tc_da(struct nfp_prog *nfp_prog) 3418 { 3419 /* TC direct-action mode: 3420 * 0,1 ok NOT SUPPORTED[1] 3421 * 2 drop 0x22 -> drop, count as stat1 3422 * 4,5 nuke 0x02 -> drop 3423 * 7 redir 0x44 -> redir, count as stat2 3424 * * unspec 0x11 -> pass, count as stat0 3425 * 3426 * [1] We can't support OK and RECLASSIFY because we can't tell TC 3427 * the exact decision made. We are forced to support UNSPEC 3428 * to handle aborts so that's the only one we handle for passing 3429 * packets up the stack. 3430 */ 3431 /* Target for aborts */ 3432 nfp_prog->tgt_abort = nfp_prog_current_offset(nfp_prog); 3433 3434 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO, 2, RELO_BR_NEXT_PKT); 3435 3436 wrp_mov(nfp_prog, reg_a(0), NFP_BPF_ABI_FLAGS); 3437 emit_ld_field(nfp_prog, reg_a(0), 0xc, reg_imm(0x11), SHF_SC_L_SHF, 16); 3438 3439 /* Target for normal exits */ 3440 nfp_prog->tgt_out = nfp_prog_current_offset(nfp_prog); 3441 3442 /* if R0 > 7 jump to abort */ 3443 emit_alu(nfp_prog, reg_none(), reg_imm(7), ALU_OP_SUB, reg_b(0)); 3444 emit_br(nfp_prog, BR_BLO, nfp_prog->tgt_abort, 0); 3445 wrp_mov(nfp_prog, reg_a(0), NFP_BPF_ABI_FLAGS); 3446 3447 wrp_immed(nfp_prog, reg_b(2), 0x41221211); 3448 wrp_immed(nfp_prog, reg_b(3), 0x41001211); 3449 3450 emit_shf(nfp_prog, reg_a(1), 3451 reg_none(), SHF_OP_NONE, reg_b(0), SHF_SC_L_SHF, 2); 3452 3453 emit_alu(nfp_prog, reg_none(), reg_a(1), ALU_OP_OR, reg_imm(0)); 3454 emit_shf(nfp_prog, reg_a(2), 3455 reg_imm(0xf), SHF_OP_AND, reg_b(2), SHF_SC_R_SHF, 0); 3456 3457 emit_alu(nfp_prog, reg_none(), reg_a(1), ALU_OP_OR, reg_imm(0)); 3458 emit_shf(nfp_prog, reg_b(2), 3459 reg_imm(0xf), SHF_OP_AND, reg_b(3), SHF_SC_R_SHF, 0); 3460 3461 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO, 2, RELO_BR_NEXT_PKT); 3462 3463 emit_shf(nfp_prog, reg_b(2), 3464 reg_a(2), SHF_OP_OR, reg_b(2), SHF_SC_L_SHF, 4); 3465 emit_ld_field(nfp_prog, reg_a(0), 0xc, reg_b(2), SHF_SC_L_SHF, 16); 3466 } 3467 3468 static void nfp_outro_xdp(struct nfp_prog *nfp_prog) 3469 { 3470 /* XDP return codes: 3471 * 0 aborted 0x82 -> drop, count as stat3 3472 * 1 drop 0x22 -> drop, count as stat1 3473 * 2 pass 0x11 -> pass, count as stat0 3474 * 3 tx 0x44 -> redir, count as stat2 3475 * * unknown 0x82 -> drop, count as stat3 3476 */ 3477 /* Target for aborts */ 3478 nfp_prog->tgt_abort = nfp_prog_current_offset(nfp_prog); 3479 3480 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO, 2, RELO_BR_NEXT_PKT); 3481 3482 wrp_mov(nfp_prog, reg_a(0), NFP_BPF_ABI_FLAGS); 3483 emit_ld_field(nfp_prog, reg_a(0), 0xc, reg_imm(0x82), SHF_SC_L_SHF, 16); 3484 3485 /* Target for normal exits */ 3486 nfp_prog->tgt_out = nfp_prog_current_offset(nfp_prog); 3487 3488 /* if R0 > 3 jump to abort */ 3489 emit_alu(nfp_prog, reg_none(), reg_imm(3), ALU_OP_SUB, reg_b(0)); 3490 emit_br(nfp_prog, BR_BLO, nfp_prog->tgt_abort, 0); 3491 3492 wrp_immed(nfp_prog, reg_b(2), 0x44112282); 3493 3494 emit_shf(nfp_prog, reg_a(1), 3495 reg_none(), SHF_OP_NONE, reg_b(0), SHF_SC_L_SHF, 3); 3496 3497 emit_alu(nfp_prog, reg_none(), reg_a(1), ALU_OP_OR, reg_imm(0)); 3498 emit_shf(nfp_prog, reg_b(2), 3499 reg_imm(0xff), SHF_OP_AND, reg_b(2), SHF_SC_R_SHF, 0); 3500 3501 emit_br_relo(nfp_prog, BR_UNC, BR_OFF_RELO, 2, RELO_BR_NEXT_PKT); 3502 3503 wrp_mov(nfp_prog, reg_a(0), NFP_BPF_ABI_FLAGS); 3504 emit_ld_field(nfp_prog, reg_a(0), 0xc, reg_b(2), SHF_SC_L_SHF, 16); 3505 } 3506 3507 static void nfp_push_callee_registers(struct nfp_prog *nfp_prog) 3508 { 3509 u8 reg; 3510 3511 /* Subroutine: Save all callee saved registers (R6 ~ R9). 3512 * imm_b() holds the return address. 3513 */ 3514 nfp_prog->tgt_call_push_regs = nfp_prog_current_offset(nfp_prog); 3515 for (reg = BPF_REG_6; reg <= BPF_REG_9; reg++) { 3516 u8 adj = (reg - BPF_REG_0) * 2; 3517 u8 idx = (reg - BPF_REG_6) * 2; 3518 3519 /* The first slot in the stack frame is used to push the return 3520 * address in bpf_to_bpf_call(), start just after. 3521 */ 3522 wrp_mov(nfp_prog, reg_lm(0, 1 + idx), reg_b(adj)); 3523 3524 if (reg == BPF_REG_8) 3525 /* Prepare to jump back, last 3 insns use defer slots */ 3526 emit_rtn(nfp_prog, imm_b(nfp_prog), 3); 3527 3528 wrp_mov(nfp_prog, reg_lm(0, 1 + idx + 1), reg_b(adj + 1)); 3529 } 3530 } 3531 3532 static void nfp_pop_callee_registers(struct nfp_prog *nfp_prog) 3533 { 3534 u8 reg; 3535 3536 /* Subroutine: Restore all callee saved registers (R6 ~ R9). 3537 * ret_reg() holds the return address. 3538 */ 3539 nfp_prog->tgt_call_pop_regs = nfp_prog_current_offset(nfp_prog); 3540 for (reg = BPF_REG_6; reg <= BPF_REG_9; reg++) { 3541 u8 adj = (reg - BPF_REG_0) * 2; 3542 u8 idx = (reg - BPF_REG_6) * 2; 3543 3544 /* The first slot in the stack frame holds the return address, 3545 * start popping just after that. 3546 */ 3547 wrp_mov(nfp_prog, reg_both(adj), reg_lm(0, 1 + idx)); 3548 3549 if (reg == BPF_REG_8) 3550 /* Prepare to jump back, last 3 insns use defer slots */ 3551 emit_rtn(nfp_prog, ret_reg(nfp_prog), 3); 3552 3553 wrp_mov(nfp_prog, reg_both(adj + 1), reg_lm(0, 1 + idx + 1)); 3554 } 3555 } 3556 3557 static void nfp_outro(struct nfp_prog *nfp_prog) 3558 { 3559 switch (nfp_prog->type) { 3560 case BPF_PROG_TYPE_SCHED_CLS: 3561 nfp_outro_tc_da(nfp_prog); 3562 break; 3563 case BPF_PROG_TYPE_XDP: 3564 nfp_outro_xdp(nfp_prog); 3565 break; 3566 default: 3567 WARN_ON(1); 3568 } 3569 3570 if (nfp_prog->subprog_cnt == 1) 3571 return; 3572 3573 nfp_push_callee_registers(nfp_prog); 3574 nfp_pop_callee_registers(nfp_prog); 3575 } 3576 3577 static int nfp_translate(struct nfp_prog *nfp_prog) 3578 { 3579 struct nfp_insn_meta *meta; 3580 unsigned int depth; 3581 int err; 3582 3583 depth = nfp_prog->subprog[0].stack_depth; 3584 nfp_prog->stack_frame_depth = round_up(depth, 4); 3585 3586 nfp_intro(nfp_prog); 3587 if (nfp_prog->error) 3588 return nfp_prog->error; 3589 3590 list_for_each_entry(meta, &nfp_prog->insns, l) { 3591 instr_cb_t cb = instr_cb[meta->insn.code]; 3592 3593 meta->off = nfp_prog_current_offset(nfp_prog); 3594 3595 if (nfp_is_subprog_start(meta)) { 3596 nfp_start_subprog(nfp_prog, meta); 3597 if (nfp_prog->error) 3598 return nfp_prog->error; 3599 } 3600 3601 if (meta->skip) { 3602 nfp_prog->n_translated++; 3603 continue; 3604 } 3605 3606 if (nfp_meta_has_prev(nfp_prog, meta) && 3607 nfp_meta_prev(meta)->double_cb) 3608 cb = nfp_meta_prev(meta)->double_cb; 3609 if (!cb) 3610 return -ENOENT; 3611 err = cb(nfp_prog, meta); 3612 if (err) 3613 return err; 3614 if (nfp_prog->error) 3615 return nfp_prog->error; 3616 3617 nfp_prog->n_translated++; 3618 } 3619 3620 nfp_prog->last_bpf_off = nfp_prog_current_offset(nfp_prog) - 1; 3621 3622 nfp_outro(nfp_prog); 3623 if (nfp_prog->error) 3624 return nfp_prog->error; 3625 3626 wrp_nops(nfp_prog, NFP_USTORE_PREFETCH_WINDOW); 3627 if (nfp_prog->error) 3628 return nfp_prog->error; 3629 3630 return nfp_fixup_branches(nfp_prog); 3631 } 3632 3633 /* --- Optimizations --- */ 3634 static void nfp_bpf_opt_reg_init(struct nfp_prog *nfp_prog) 3635 { 3636 struct nfp_insn_meta *meta; 3637 3638 list_for_each_entry(meta, &nfp_prog->insns, l) { 3639 struct bpf_insn insn = meta->insn; 3640 3641 /* Programs converted from cBPF start with register xoring */ 3642 if (insn.code == (BPF_ALU64 | BPF_XOR | BPF_X) && 3643 insn.src_reg == insn.dst_reg) 3644 continue; 3645 3646 /* Programs start with R6 = R1 but we ignore the skb pointer */ 3647 if (insn.code == (BPF_ALU64 | BPF_MOV | BPF_X) && 3648 insn.src_reg == 1 && insn.dst_reg == 6) 3649 meta->skip = true; 3650 3651 /* Return as soon as something doesn't match */ 3652 if (!meta->skip) 3653 return; 3654 } 3655 } 3656 3657 /* abs(insn.imm) will fit better into unrestricted reg immediate - 3658 * convert add/sub of a negative number into a sub/add of a positive one. 3659 */ 3660 static void nfp_bpf_opt_neg_add_sub(struct nfp_prog *nfp_prog) 3661 { 3662 struct nfp_insn_meta *meta; 3663 3664 list_for_each_entry(meta, &nfp_prog->insns, l) { 3665 struct bpf_insn insn = meta->insn; 3666 3667 if (meta->skip) 3668 continue; 3669 3670 if (BPF_CLASS(insn.code) != BPF_ALU && 3671 BPF_CLASS(insn.code) != BPF_ALU64 && 3672 BPF_CLASS(insn.code) != BPF_JMP) 3673 continue; 3674 if (BPF_SRC(insn.code) != BPF_K) 3675 continue; 3676 if (insn.imm >= 0) 3677 continue; 3678 3679 if (BPF_CLASS(insn.code) == BPF_JMP) { 3680 switch (BPF_OP(insn.code)) { 3681 case BPF_JGE: 3682 case BPF_JSGE: 3683 case BPF_JLT: 3684 case BPF_JSLT: 3685 meta->jump_neg_op = true; 3686 break; 3687 default: 3688 continue; 3689 } 3690 } else { 3691 if (BPF_OP(insn.code) == BPF_ADD) 3692 insn.code = BPF_CLASS(insn.code) | BPF_SUB; 3693 else if (BPF_OP(insn.code) == BPF_SUB) 3694 insn.code = BPF_CLASS(insn.code) | BPF_ADD; 3695 else 3696 continue; 3697 3698 meta->insn.code = insn.code | BPF_K; 3699 } 3700 3701 meta->insn.imm = -insn.imm; 3702 } 3703 } 3704 3705 /* Remove masking after load since our load guarantees this is not needed */ 3706 static void nfp_bpf_opt_ld_mask(struct nfp_prog *nfp_prog) 3707 { 3708 struct nfp_insn_meta *meta1, *meta2; 3709 const s32 exp_mask[] = { 3710 [BPF_B] = 0x000000ffU, 3711 [BPF_H] = 0x0000ffffU, 3712 [BPF_W] = 0xffffffffU, 3713 }; 3714 3715 nfp_for_each_insn_walk2(nfp_prog, meta1, meta2) { 3716 struct bpf_insn insn, next; 3717 3718 insn = meta1->insn; 3719 next = meta2->insn; 3720 3721 if (BPF_CLASS(insn.code) != BPF_LD) 3722 continue; 3723 if (BPF_MODE(insn.code) != BPF_ABS && 3724 BPF_MODE(insn.code) != BPF_IND) 3725 continue; 3726 3727 if (next.code != (BPF_ALU64 | BPF_AND | BPF_K)) 3728 continue; 3729 3730 if (!exp_mask[BPF_SIZE(insn.code)]) 3731 continue; 3732 if (exp_mask[BPF_SIZE(insn.code)] != next.imm) 3733 continue; 3734 3735 if (next.src_reg || next.dst_reg) 3736 continue; 3737 3738 if (meta2->flags & FLAG_INSN_IS_JUMP_DST) 3739 continue; 3740 3741 meta2->skip = true; 3742 } 3743 } 3744 3745 static void nfp_bpf_opt_ld_shift(struct nfp_prog *nfp_prog) 3746 { 3747 struct nfp_insn_meta *meta1, *meta2, *meta3; 3748 3749 nfp_for_each_insn_walk3(nfp_prog, meta1, meta2, meta3) { 3750 struct bpf_insn insn, next1, next2; 3751 3752 insn = meta1->insn; 3753 next1 = meta2->insn; 3754 next2 = meta3->insn; 3755 3756 if (BPF_CLASS(insn.code) != BPF_LD) 3757 continue; 3758 if (BPF_MODE(insn.code) != BPF_ABS && 3759 BPF_MODE(insn.code) != BPF_IND) 3760 continue; 3761 if (BPF_SIZE(insn.code) != BPF_W) 3762 continue; 3763 3764 if (!(next1.code == (BPF_LSH | BPF_K | BPF_ALU64) && 3765 next2.code == (BPF_RSH | BPF_K | BPF_ALU64)) && 3766 !(next1.code == (BPF_RSH | BPF_K | BPF_ALU64) && 3767 next2.code == (BPF_LSH | BPF_K | BPF_ALU64))) 3768 continue; 3769 3770 if (next1.src_reg || next1.dst_reg || 3771 next2.src_reg || next2.dst_reg) 3772 continue; 3773 3774 if (next1.imm != 0x20 || next2.imm != 0x20) 3775 continue; 3776 3777 if (meta2->flags & FLAG_INSN_IS_JUMP_DST || 3778 meta3->flags & FLAG_INSN_IS_JUMP_DST) 3779 continue; 3780 3781 meta2->skip = true; 3782 meta3->skip = true; 3783 } 3784 } 3785 3786 /* load/store pair that forms memory copy sould look like the following: 3787 * 3788 * ld_width R, [addr_src + offset_src] 3789 * st_width [addr_dest + offset_dest], R 3790 * 3791 * The destination register of load and source register of store should 3792 * be the same, load and store should also perform at the same width. 3793 * If either of addr_src or addr_dest is stack pointer, we don't do the 3794 * CPP optimization as stack is modelled by registers on NFP. 3795 */ 3796 static bool 3797 curr_pair_is_memcpy(struct nfp_insn_meta *ld_meta, 3798 struct nfp_insn_meta *st_meta) 3799 { 3800 struct bpf_insn *ld = &ld_meta->insn; 3801 struct bpf_insn *st = &st_meta->insn; 3802 3803 if (!is_mbpf_load(ld_meta) || !is_mbpf_store(st_meta)) 3804 return false; 3805 3806 if (ld_meta->ptr.type != PTR_TO_PACKET && 3807 ld_meta->ptr.type != PTR_TO_MAP_VALUE) 3808 return false; 3809 3810 if (st_meta->ptr.type != PTR_TO_PACKET) 3811 return false; 3812 3813 if (BPF_SIZE(ld->code) != BPF_SIZE(st->code)) 3814 return false; 3815 3816 if (ld->dst_reg != st->src_reg) 3817 return false; 3818 3819 /* There is jump to the store insn in this pair. */ 3820 if (st_meta->flags & FLAG_INSN_IS_JUMP_DST) 3821 return false; 3822 3823 return true; 3824 } 3825 3826 /* Currently, we only support chaining load/store pairs if: 3827 * 3828 * - Their address base registers are the same. 3829 * - Their address offsets are in the same order. 3830 * - They operate at the same memory width. 3831 * - There is no jump into the middle of them. 3832 */ 3833 static bool 3834 curr_pair_chain_with_previous(struct nfp_insn_meta *ld_meta, 3835 struct nfp_insn_meta *st_meta, 3836 struct bpf_insn *prev_ld, 3837 struct bpf_insn *prev_st) 3838 { 3839 u8 prev_size, curr_size, prev_ld_base, prev_st_base, prev_ld_dst; 3840 struct bpf_insn *ld = &ld_meta->insn; 3841 struct bpf_insn *st = &st_meta->insn; 3842 s16 prev_ld_off, prev_st_off; 3843 3844 /* This pair is the start pair. */ 3845 if (!prev_ld) 3846 return true; 3847 3848 prev_size = BPF_LDST_BYTES(prev_ld); 3849 curr_size = BPF_LDST_BYTES(ld); 3850 prev_ld_base = prev_ld->src_reg; 3851 prev_st_base = prev_st->dst_reg; 3852 prev_ld_dst = prev_ld->dst_reg; 3853 prev_ld_off = prev_ld->off; 3854 prev_st_off = prev_st->off; 3855 3856 if (ld->dst_reg != prev_ld_dst) 3857 return false; 3858 3859 if (ld->src_reg != prev_ld_base || st->dst_reg != prev_st_base) 3860 return false; 3861 3862 if (curr_size != prev_size) 3863 return false; 3864 3865 /* There is jump to the head of this pair. */ 3866 if (ld_meta->flags & FLAG_INSN_IS_JUMP_DST) 3867 return false; 3868 3869 /* Both in ascending order. */ 3870 if (prev_ld_off + prev_size == ld->off && 3871 prev_st_off + prev_size == st->off) 3872 return true; 3873 3874 /* Both in descending order. */ 3875 if (ld->off + curr_size == prev_ld_off && 3876 st->off + curr_size == prev_st_off) 3877 return true; 3878 3879 return false; 3880 } 3881 3882 /* Return TRUE if cross memory access happens. Cross memory access means 3883 * store area is overlapping with load area that a later load might load 3884 * the value from previous store, for this case we can't treat the sequence 3885 * as an memory copy. 3886 */ 3887 static bool 3888 cross_mem_access(struct bpf_insn *ld, struct nfp_insn_meta *head_ld_meta, 3889 struct nfp_insn_meta *head_st_meta) 3890 { 3891 s16 head_ld_off, head_st_off, ld_off; 3892 3893 /* Different pointer types does not overlap. */ 3894 if (head_ld_meta->ptr.type != head_st_meta->ptr.type) 3895 return false; 3896 3897 /* load and store are both PTR_TO_PACKET, check ID info. */ 3898 if (head_ld_meta->ptr.id != head_st_meta->ptr.id) 3899 return true; 3900 3901 /* Canonicalize the offsets. Turn all of them against the original 3902 * base register. 3903 */ 3904 head_ld_off = head_ld_meta->insn.off + head_ld_meta->ptr.off; 3905 head_st_off = head_st_meta->insn.off + head_st_meta->ptr.off; 3906 ld_off = ld->off + head_ld_meta->ptr.off; 3907 3908 /* Ascending order cross. */ 3909 if (ld_off > head_ld_off && 3910 head_ld_off < head_st_off && ld_off >= head_st_off) 3911 return true; 3912 3913 /* Descending order cross. */ 3914 if (ld_off < head_ld_off && 3915 head_ld_off > head_st_off && ld_off <= head_st_off) 3916 return true; 3917 3918 return false; 3919 } 3920 3921 /* This pass try to identify the following instructoin sequences. 3922 * 3923 * load R, [regA + offA] 3924 * store [regB + offB], R 3925 * load R, [regA + offA + const_imm_A] 3926 * store [regB + offB + const_imm_A], R 3927 * load R, [regA + offA + 2 * const_imm_A] 3928 * store [regB + offB + 2 * const_imm_A], R 3929 * ... 3930 * 3931 * Above sequence is typically generated by compiler when lowering 3932 * memcpy. NFP prefer using CPP instructions to accelerate it. 3933 */ 3934 static void nfp_bpf_opt_ldst_gather(struct nfp_prog *nfp_prog) 3935 { 3936 struct nfp_insn_meta *head_ld_meta = NULL; 3937 struct nfp_insn_meta *head_st_meta = NULL; 3938 struct nfp_insn_meta *meta1, *meta2; 3939 struct bpf_insn *prev_ld = NULL; 3940 struct bpf_insn *prev_st = NULL; 3941 u8 count = 0; 3942 3943 nfp_for_each_insn_walk2(nfp_prog, meta1, meta2) { 3944 struct bpf_insn *ld = &meta1->insn; 3945 struct bpf_insn *st = &meta2->insn; 3946 3947 /* Reset record status if any of the following if true: 3948 * - The current insn pair is not load/store. 3949 * - The load/store pair doesn't chain with previous one. 3950 * - The chained load/store pair crossed with previous pair. 3951 * - The chained load/store pair has a total size of memory 3952 * copy beyond 128 bytes which is the maximum length a 3953 * single NFP CPP command can transfer. 3954 */ 3955 if (!curr_pair_is_memcpy(meta1, meta2) || 3956 !curr_pair_chain_with_previous(meta1, meta2, prev_ld, 3957 prev_st) || 3958 (head_ld_meta && (cross_mem_access(ld, head_ld_meta, 3959 head_st_meta) || 3960 head_ld_meta->ldst_gather_len >= 128))) { 3961 if (!count) 3962 continue; 3963 3964 if (count > 1) { 3965 s16 prev_ld_off = prev_ld->off; 3966 s16 prev_st_off = prev_st->off; 3967 s16 head_ld_off = head_ld_meta->insn.off; 3968 3969 if (prev_ld_off < head_ld_off) { 3970 head_ld_meta->insn.off = prev_ld_off; 3971 head_st_meta->insn.off = prev_st_off; 3972 head_ld_meta->ldst_gather_len = 3973 -head_ld_meta->ldst_gather_len; 3974 } 3975 3976 head_ld_meta->paired_st = &head_st_meta->insn; 3977 head_st_meta->skip = true; 3978 } else { 3979 head_ld_meta->ldst_gather_len = 0; 3980 } 3981 3982 /* If the chain is ended by an load/store pair then this 3983 * could serve as the new head of the the next chain. 3984 */ 3985 if (curr_pair_is_memcpy(meta1, meta2)) { 3986 head_ld_meta = meta1; 3987 head_st_meta = meta2; 3988 head_ld_meta->ldst_gather_len = 3989 BPF_LDST_BYTES(ld); 3990 meta1 = nfp_meta_next(meta1); 3991 meta2 = nfp_meta_next(meta2); 3992 prev_ld = ld; 3993 prev_st = st; 3994 count = 1; 3995 } else { 3996 head_ld_meta = NULL; 3997 head_st_meta = NULL; 3998 prev_ld = NULL; 3999 prev_st = NULL; 4000 count = 0; 4001 } 4002 4003 continue; 4004 } 4005 4006 if (!head_ld_meta) { 4007 head_ld_meta = meta1; 4008 head_st_meta = meta2; 4009 } else { 4010 meta1->skip = true; 4011 meta2->skip = true; 4012 } 4013 4014 head_ld_meta->ldst_gather_len += BPF_LDST_BYTES(ld); 4015 meta1 = nfp_meta_next(meta1); 4016 meta2 = nfp_meta_next(meta2); 4017 prev_ld = ld; 4018 prev_st = st; 4019 count++; 4020 } 4021 } 4022 4023 static void nfp_bpf_opt_pkt_cache(struct nfp_prog *nfp_prog) 4024 { 4025 struct nfp_insn_meta *meta, *range_node = NULL; 4026 s16 range_start = 0, range_end = 0; 4027 bool cache_avail = false; 4028 struct bpf_insn *insn; 4029 s32 range_ptr_off = 0; 4030 u32 range_ptr_id = 0; 4031 4032 list_for_each_entry(meta, &nfp_prog->insns, l) { 4033 if (meta->flags & FLAG_INSN_IS_JUMP_DST) 4034 cache_avail = false; 4035 4036 if (meta->skip) 4037 continue; 4038 4039 insn = &meta->insn; 4040 4041 if (is_mbpf_store_pkt(meta) || 4042 insn->code == (BPF_JMP | BPF_CALL) || 4043 is_mbpf_classic_store_pkt(meta) || 4044 is_mbpf_classic_load(meta)) { 4045 cache_avail = false; 4046 continue; 4047 } 4048 4049 if (!is_mbpf_load(meta)) 4050 continue; 4051 4052 if (meta->ptr.type != PTR_TO_PACKET || meta->ldst_gather_len) { 4053 cache_avail = false; 4054 continue; 4055 } 4056 4057 if (!cache_avail) { 4058 cache_avail = true; 4059 if (range_node) 4060 goto end_current_then_start_new; 4061 goto start_new; 4062 } 4063 4064 /* Check ID to make sure two reads share the same 4065 * variable offset against PTR_TO_PACKET, and check OFF 4066 * to make sure they also share the same constant 4067 * offset. 4068 * 4069 * OFFs don't really need to be the same, because they 4070 * are the constant offsets against PTR_TO_PACKET, so 4071 * for different OFFs, we could canonicalize them to 4072 * offsets against original packet pointer. We don't 4073 * support this. 4074 */ 4075 if (meta->ptr.id == range_ptr_id && 4076 meta->ptr.off == range_ptr_off) { 4077 s16 new_start = range_start; 4078 s16 end, off = insn->off; 4079 s16 new_end = range_end; 4080 bool changed = false; 4081 4082 if (off < range_start) { 4083 new_start = off; 4084 changed = true; 4085 } 4086 4087 end = off + BPF_LDST_BYTES(insn); 4088 if (end > range_end) { 4089 new_end = end; 4090 changed = true; 4091 } 4092 4093 if (!changed) 4094 continue; 4095 4096 if (new_end - new_start <= 64) { 4097 /* Install new range. */ 4098 range_start = new_start; 4099 range_end = new_end; 4100 continue; 4101 } 4102 } 4103 4104 end_current_then_start_new: 4105 range_node->pkt_cache.range_start = range_start; 4106 range_node->pkt_cache.range_end = range_end; 4107 start_new: 4108 range_node = meta; 4109 range_node->pkt_cache.do_init = true; 4110 range_ptr_id = range_node->ptr.id; 4111 range_ptr_off = range_node->ptr.off; 4112 range_start = insn->off; 4113 range_end = insn->off + BPF_LDST_BYTES(insn); 4114 } 4115 4116 if (range_node) { 4117 range_node->pkt_cache.range_start = range_start; 4118 range_node->pkt_cache.range_end = range_end; 4119 } 4120 4121 list_for_each_entry(meta, &nfp_prog->insns, l) { 4122 if (meta->skip) 4123 continue; 4124 4125 if (is_mbpf_load_pkt(meta) && !meta->ldst_gather_len) { 4126 if (meta->pkt_cache.do_init) { 4127 range_start = meta->pkt_cache.range_start; 4128 range_end = meta->pkt_cache.range_end; 4129 } else { 4130 meta->pkt_cache.range_start = range_start; 4131 meta->pkt_cache.range_end = range_end; 4132 } 4133 } 4134 } 4135 } 4136 4137 static int nfp_bpf_optimize(struct nfp_prog *nfp_prog) 4138 { 4139 nfp_bpf_opt_reg_init(nfp_prog); 4140 4141 nfp_bpf_opt_neg_add_sub(nfp_prog); 4142 nfp_bpf_opt_ld_mask(nfp_prog); 4143 nfp_bpf_opt_ld_shift(nfp_prog); 4144 nfp_bpf_opt_ldst_gather(nfp_prog); 4145 nfp_bpf_opt_pkt_cache(nfp_prog); 4146 4147 return 0; 4148 } 4149 4150 static int nfp_bpf_replace_map_ptrs(struct nfp_prog *nfp_prog) 4151 { 4152 struct nfp_insn_meta *meta1, *meta2; 4153 struct nfp_bpf_map *nfp_map; 4154 struct bpf_map *map; 4155 u32 id; 4156 4157 nfp_for_each_insn_walk2(nfp_prog, meta1, meta2) { 4158 if (meta1->skip || meta2->skip) 4159 continue; 4160 4161 if (meta1->insn.code != (BPF_LD | BPF_IMM | BPF_DW) || 4162 meta1->insn.src_reg != BPF_PSEUDO_MAP_FD) 4163 continue; 4164 4165 map = (void *)(unsigned long)((u32)meta1->insn.imm | 4166 (u64)meta2->insn.imm << 32); 4167 if (bpf_map_offload_neutral(map)) { 4168 id = map->id; 4169 } else { 4170 nfp_map = map_to_offmap(map)->dev_priv; 4171 id = nfp_map->tid; 4172 } 4173 4174 meta1->insn.imm = id; 4175 meta2->insn.imm = 0; 4176 } 4177 4178 return 0; 4179 } 4180 4181 static int nfp_bpf_ustore_calc(u64 *prog, unsigned int len) 4182 { 4183 __le64 *ustore = (__force __le64 *)prog; 4184 int i; 4185 4186 for (i = 0; i < len; i++) { 4187 int err; 4188 4189 err = nfp_ustore_check_valid_no_ecc(prog[i]); 4190 if (err) 4191 return err; 4192 4193 ustore[i] = cpu_to_le64(nfp_ustore_calc_ecc_insn(prog[i])); 4194 } 4195 4196 return 0; 4197 } 4198 4199 static void nfp_bpf_prog_trim(struct nfp_prog *nfp_prog) 4200 { 4201 void *prog; 4202 4203 prog = kvmalloc_array(nfp_prog->prog_len, sizeof(u64), GFP_KERNEL); 4204 if (!prog) 4205 return; 4206 4207 nfp_prog->__prog_alloc_len = nfp_prog->prog_len * sizeof(u64); 4208 memcpy(prog, nfp_prog->prog, nfp_prog->__prog_alloc_len); 4209 kvfree(nfp_prog->prog); 4210 nfp_prog->prog = prog; 4211 } 4212 4213 int nfp_bpf_jit(struct nfp_prog *nfp_prog) 4214 { 4215 int ret; 4216 4217 ret = nfp_bpf_replace_map_ptrs(nfp_prog); 4218 if (ret) 4219 return ret; 4220 4221 ret = nfp_bpf_optimize(nfp_prog); 4222 if (ret) 4223 return ret; 4224 4225 ret = nfp_translate(nfp_prog); 4226 if (ret) { 4227 pr_err("Translation failed with error %d (translated: %u)\n", 4228 ret, nfp_prog->n_translated); 4229 return -EINVAL; 4230 } 4231 4232 nfp_bpf_prog_trim(nfp_prog); 4233 4234 return ret; 4235 } 4236 4237 void nfp_bpf_jit_prepare(struct nfp_prog *nfp_prog, unsigned int cnt) 4238 { 4239 struct nfp_insn_meta *meta; 4240 4241 /* Another pass to record jump information. */ 4242 list_for_each_entry(meta, &nfp_prog->insns, l) { 4243 struct nfp_insn_meta *dst_meta; 4244 u64 code = meta->insn.code; 4245 unsigned int dst_idx; 4246 bool pseudo_call; 4247 4248 if (BPF_CLASS(code) != BPF_JMP) 4249 continue; 4250 if (BPF_OP(code) == BPF_EXIT) 4251 continue; 4252 if (is_mbpf_helper_call(meta)) 4253 continue; 4254 4255 /* If opcode is BPF_CALL at this point, this can only be a 4256 * BPF-to-BPF call (a.k.a pseudo call). 4257 */ 4258 pseudo_call = BPF_OP(code) == BPF_CALL; 4259 4260 if (pseudo_call) 4261 dst_idx = meta->n + 1 + meta->insn.imm; 4262 else 4263 dst_idx = meta->n + 1 + meta->insn.off; 4264 4265 dst_meta = nfp_bpf_goto_meta(nfp_prog, meta, dst_idx, cnt); 4266 4267 if (pseudo_call) 4268 dst_meta->flags |= FLAG_INSN_IS_SUBPROG_START; 4269 4270 dst_meta->flags |= FLAG_INSN_IS_JUMP_DST; 4271 meta->jmp_dst = dst_meta; 4272 } 4273 } 4274 4275 bool nfp_bpf_supported_opcode(u8 code) 4276 { 4277 return !!instr_cb[code]; 4278 } 4279 4280 void *nfp_bpf_relo_for_vnic(struct nfp_prog *nfp_prog, struct nfp_bpf_vnic *bv) 4281 { 4282 unsigned int i; 4283 u64 *prog; 4284 int err; 4285 4286 prog = kmemdup(nfp_prog->prog, nfp_prog->prog_len * sizeof(u64), 4287 GFP_KERNEL); 4288 if (!prog) 4289 return ERR_PTR(-ENOMEM); 4290 4291 for (i = 0; i < nfp_prog->prog_len; i++) { 4292 enum nfp_relo_type special; 4293 u32 val; 4294 u16 off; 4295 4296 special = FIELD_GET(OP_RELO_TYPE, prog[i]); 4297 switch (special) { 4298 case RELO_NONE: 4299 continue; 4300 case RELO_BR_REL: 4301 br_add_offset(&prog[i], bv->start_off); 4302 break; 4303 case RELO_BR_GO_OUT: 4304 br_set_offset(&prog[i], 4305 nfp_prog->tgt_out + bv->start_off); 4306 break; 4307 case RELO_BR_GO_ABORT: 4308 br_set_offset(&prog[i], 4309 nfp_prog->tgt_abort + bv->start_off); 4310 break; 4311 case RELO_BR_GO_CALL_PUSH_REGS: 4312 off = nfp_prog->tgt_call_push_regs + bv->start_off; 4313 br_set_offset(&prog[i], off); 4314 break; 4315 case RELO_BR_GO_CALL_POP_REGS: 4316 off = nfp_prog->tgt_call_pop_regs + bv->start_off; 4317 br_set_offset(&prog[i], off); 4318 break; 4319 case RELO_BR_NEXT_PKT: 4320 br_set_offset(&prog[i], bv->tgt_done); 4321 break; 4322 case RELO_BR_HELPER: 4323 val = br_get_offset(prog[i]); 4324 val -= BR_OFF_RELO; 4325 switch (val) { 4326 case BPF_FUNC_map_lookup_elem: 4327 val = nfp_prog->bpf->helpers.map_lookup; 4328 break; 4329 case BPF_FUNC_map_update_elem: 4330 val = nfp_prog->bpf->helpers.map_update; 4331 break; 4332 case BPF_FUNC_map_delete_elem: 4333 val = nfp_prog->bpf->helpers.map_delete; 4334 break; 4335 case BPF_FUNC_perf_event_output: 4336 val = nfp_prog->bpf->helpers.perf_event_output; 4337 break; 4338 default: 4339 pr_err("relocation of unknown helper %d\n", 4340 val); 4341 err = -EINVAL; 4342 goto err_free_prog; 4343 } 4344 br_set_offset(&prog[i], val); 4345 break; 4346 case RELO_IMMED_REL: 4347 immed_add_value(&prog[i], bv->start_off); 4348 break; 4349 } 4350 4351 prog[i] &= ~OP_RELO_TYPE; 4352 } 4353 4354 err = nfp_bpf_ustore_calc(prog, nfp_prog->prog_len); 4355 if (err) 4356 goto err_free_prog; 4357 4358 return prog; 4359 4360 err_free_prog: 4361 kfree(prog); 4362 return ERR_PTR(err); 4363 } 4364