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1 /*
2 * Copyright © 2013 Intel Corporation
3 *
4 * Permission is hereby granted, free of charge, to any person obtaining a
5 * copy of this software and associated documentation files (the "Software"),
6 * to deal in the Software without restriction, including without limitation
7 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8 * and/or sell copies of the Software, and to permit persons to whom the
9 * Software is furnished to do so, subject to the following conditions:
10 *
11 * The above copyright notice and this permission notice (including the next
12 * paragraph) shall be included in all copies or substantial portions of the
13 * Software.
14 *
15 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
16 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
17 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
18 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
19 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
20 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
21 * IN THE SOFTWARE.
22 *
23 * Authors:
24 * Brad Volkin <bradley.d.volkin@intel.com>
25 *
26 */
31 /**
32 * DOC: batch buffer command parser
33 *
34 * Motivation:
35 * Certain OpenGL features (e.g. transform feedback, performance monitoring)
36 * require userspace code to submit batches containing commands such as
37 * MI_LOAD_REGISTER_IMM to access various registers. Unfortunately, some
38 * generations of the hardware will noop these commands in "unsecure" batches
39 * (which includes all userspace batches submitted via i915) even though the
40 * commands may be safe and represent the intended programming model of the
41 * device.
42 *
43 * The software command parser is similar in operation to the command parsing
44 * done in hardware for unsecure batches. However, the software parser allows
45 * some operations that would be noop'd by hardware, if the parser determines
46 * the operation is safe, and submits the batch as "secure" to prevent hardware
47 * parsing.
48 *
49 * Threats:
50 * At a high level, the hardware (and software) checks attempt to prevent
51 * granting userspace undue privileges. There are three categories of privilege.
52 *
53 * First, commands which are explicitly defined as privileged or which should
54 * only be used by the kernel driver. The parser rejects such commands
55 *
56 * Second, commands which access registers. To support correct/enhanced
57 * userspace functionality, particularly certain OpenGL extensions, the parser
58 * provides a whitelist of registers which userspace may safely access
59 *
60 * Third, commands which access privileged memory (i.e. GGTT, HWS page, etc).
61 * The parser always rejects such commands.
62 *
63 * The majority of the problematic commands fall in the MI_* range, with only a
64 * few specific commands on each engine (e.g. PIPE_CONTROL and MI_FLUSH_DW).
65 *
66 * Implementation:
67 * Each engine maintains tables of commands and registers which the parser
68 * uses in scanning batch buffers submitted to that engine.
69 *
70 * Since the set of commands that the parser must check for is significantly
71 * smaller than the number of commands supported, the parser tables contain only
72 * those commands required by the parser. This generally works because command
73 * opcode ranges have standard command length encodings. So for commands that
74 * the parser does not need to check, it can easily skip them. This is
75 * implemented via a per-engine length decoding vfunc.
76 *
77 * Unfortunately, there are a number of commands that do not follow the standard
78 * length encoding for their opcode range, primarily amongst the MI_* commands.
79 * To handle this, the parser provides a way to define explicit "skip" entries
80 * in the per-engine command tables.
81 *
82 * Other command table entries map fairly directly to high level categories
83 * mentioned above: rejected, register whitelist. The parser implements a number
84 * of checks, including the privileged memory checks, via a general bitmasking
85 * mechanism.
86 */
88 /*
89 * A command that requires special handling by the command parser.
90 */
92 /*
93 * Flags describing how the command parser processes the command.
94 *
95 * CMD_DESC_FIXED: The command has a fixed length if this is set,
96 * a length mask if not set
97 * CMD_DESC_SKIP: The command is allowed but does not follow the
98 * standard length encoding for the opcode range in
99 * which it falls
100 * CMD_DESC_REJECT: The command is never allowed
101 * CMD_DESC_REGISTER: The command should be checked against the
102 * register whitelist for the appropriate ring
103 */
104 u32 flags;
105 #define CMD_DESC_FIXED (1<<0)
106 #define CMD_DESC_SKIP (1<<1)
107 #define CMD_DESC_REJECT (1<<2)
108 #define CMD_DESC_REGISTER (1<<3)
109 #define CMD_DESC_BITMASK (1<<4)
111 /*
112 * The command's unique identification bits and the bitmask to get them.
113 * This isn't strictly the opcode field as defined in the spec and may
114 * also include type, subtype, and/or subop fields.
115 */
117 u32 value;
118 u32 mask;
121 /*
122 * The command's length. The command is either fixed length (i.e. does
123 * not include a length field) or has a length field mask. The flag
124 * CMD_DESC_FIXED indicates a fixed length. Otherwise, the command has
125 * a length mask. All command entries in a command table must include
126 * length information.
127 */
129 u32 fixed;
130 u32 mask;
133 /*
134 * Describes where to find a register address in the command to check
135 * against the ring's register whitelist. Only valid if flags has the
136 * CMD_DESC_REGISTER bit set.
137 *
138 * A non-zero step value implies that the command may access multiple
139 * registers in sequence (e.g. LRI), in that case step gives the
140 * distance in dwords between individual offset fields.
141 */
143 u32 offset;
144 u32 mask;
145 u32 step;
148 #define MAX_CMD_DESC_BITMASKS 3
149 /*
150 * Describes command checks where a particular dword is masked and
151 * compared against an expected value. If the command does not match
152 * the expected value, the parser rejects it. Only valid if flags has
153 * the CMD_DESC_BITMASK bit set. Only entries where mask is non-zero
154 * are valid.
155 *
156 * If the check specifies a non-zero condition_mask then the parser
157 * only performs the check when the bits specified by condition_mask
158 * are non-zero.
159 */
161 u32 offset;
162 u32 mask;
163 u32 expected;
164 u32 condition_offset;
165 u32 condition_mask;
167 };
169 /*
170 * A table of commands requiring special handling by the command parser.
171 *
172 * Each engine has an array of tables. Each table consists of an array of
173 * command descriptors, which must be sorted with command opcodes in
174 * ascending order.
175 */
179 };
181 #define STD_MI_OPCODE_SHIFT (32 - 9)
182 #define STD_3D_OPCODE_SHIFT (32 - 16)
183 #define STD_2D_OPCODE_SHIFT (32 - 10)
184 #define STD_MFX_OPCODE_SHIFT (32 - 16)
185 #define MIN_OPCODE_SHIFT 16
187 #define CMD(op, opm, f, lm, fl, ...) \
188 { \
189 .flags = (fl) | ((f) ? CMD_DESC_FIXED : 0), \
190 .cmd = { (op & ~0u << (opm)), ~0u << (opm) }, \
191 .length = { (lm) }, \
192 __VA_ARGS__ \
193 }
195 /* Convenience macros to compress the tables */
196 #define SMI STD_MI_OPCODE_SHIFT
197 #define S3D STD_3D_OPCODE_SHIFT
198 #define S2D STD_2D_OPCODE_SHIFT
199 #define SMFX STD_MFX_OPCODE_SHIFT
200 #define F true
201 #define S CMD_DESC_SKIP
202 #define R CMD_DESC_REJECT
203 #define W CMD_DESC_REGISTER
204 #define B CMD_DESC_BITMASK
206 /* Command Mask Fixed Len Action
207 ---------------------------------------------------------- */
225 }}, ),
232 }}, ),
233 /*
234 * MI_BATCH_BUFFER_START requires some special handling. It's not
235 * really a 'skip' action but it doesn't seem like it's worth adding
236 * a new action. See i915_parse_cmds().
237 */
239 };
255 }}, ),
262 }}, ),
268 }}, ),
274 }}, ),
282 }}, ),
291 },
292 {
295 PIPE_CONTROL_STORE_DATA_INDEX),
299 }}, ),
300 };
323 };
333 }}, ),
340 },
341 {
347 },
348 {
354 }}, ),
360 }}, ),
361 /*
362 * MFX_WAIT doesn't fit the way we handle length for most commands.
363 * It has a length field but it uses a non-standard length bias.
364 * It is always 1 dword though, so just treat it as fixed length.
365 */
367 };
377 }}, ),
384 },
385 {
391 },
392 {
398 }}, ),
404 }}, ),
405 };
414 }}, ),
421 },
422 {
428 },
429 {
435 }}, ),
438 };
443 };
445 /*
446 * For Gen9 we can still rely on the h/w to enforce cmd security, and only
447 * need to re-enforce the register access checks. We therefore only need to
448 * teach the cmdparser how to find the end of each command, and identify
449 * register accesses. The table doesn't need to reject any commands, and so
450 * the only commands listed here are:
451 * 1) Those that touch registers
452 * 2) Those that do not have the default 8-bit length
453 *
454 * Note that the default MI length mask chosen for this table is 0xFF, not
455 * the 0x3F used on older devices. This is because the vast majority of MI
456 * cmds on Gen9 use a standard 8-bit Length field.
457 * All the Gen9 blitter instructions are standard 0xFF length mask, and
458 * none allow access to non-general registers, so in fact no BLT cmds are
459 * included in the table at all.
460 *
461 */
485 /*
486 * We allow BB_START but apply further checks. We just sanitize the
487 * basic fields here.
488 */
489 #define MI_BB_START_OPERAND_MASK GENMASK(SMI-1, 0)
490 #define MI_BB_START_OPERAND_EXPECT (MI_BATCH_PPGTT_HSW | 1)
496 }}, ),
497 };
502 #undef CMD
503 #undef SMI
504 #undef S3D
505 #undef S2D
506 #undef SMFX
507 #undef F
508 #undef S
509 #undef R
510 #undef W
511 #undef B
516 };
522 };
527 };
532 };
537 };
543 };
547 };
550 /*
551 * Register whitelists, sorted by increasing register offset.
552 */
554 /*
555 * An individual whitelist entry granting access to register addr. If
556 * mask is non-zero the argument of immediate register writes will be
557 * AND-ed with mask, and the command will be rejected if the result
558 * doesn't match value.
559 *
560 * Registers with non-zero mask are only allowed to be written using
561 * LRI.
562 */
564 i915_reg_t addr;
565 u32 mask;
566 u32 value;
567 };
569 /* Convenience macro for adding 32-bit registers. */
570 #define REG32(_reg, ...) \
571 { .addr = (_reg), __VA_ARGS__ }
573 /*
574 * Convenience macro for adding 64-bit registers.
575 *
576 * Some registers that userspace accesses are 64 bits. The register
577 * access commands only allow 32-bit accesses. Hence, we have to include
578 * entries for both halves of the 64-bit registers.
579 */
580 #define REG64(_reg) \
581 { .addr = _reg }, \
582 { .addr = _reg ## _UDW }
584 #define REG64_IDX(_reg, idx) \
585 { .addr = _reg(idx) }, \
586 { .addr = _reg ## _UDW(idx) }
630 };
654 HSW_ROW_CHICKEN3_L3_GLOBAL_ATOMICS_DISABLE),
656 };
663 };
686 };
688 #undef REG64
689 #undef REG32
694 };
698 };
702 };
707 };
711 };
715 };
718 {
720 u32 subclient =
728 else
730 }
734 }
737 {
739 u32 subclient =
749 else
753 }
757 }
760 {
770 }
773 {
781 }
786 {
809 }
812 }
813 }
816 }
821 {
835 }
838 }
841 }
844 {
852 }
855 }
860 };
862 /*
863 * Different command ranges have different numbers of bits for the opcode. For
864 * example, MI commands use bits 31:23 while 3D commands use bits 31:16. The
865 * problem is that, for example, MI commands use bits 22:16 for other fields
866 * such as GGTT vs PPGTT bits. If we include those bits in the mask then when
867 * we mask a command from a batch it could hash to the wrong bucket due to
868 * non-opcode bits being set. But if we don't include those bits, some 3D
869 * commands may hash to the same bucket due to not including opcode bits that
870 * make the command unique. For now, we will risk hashing to the same bucket.
871 */
873 {
882 }
883 }
888 {
908 }
909 }
912 }
915 {
923 }
924 }
926 /**
927 * intel_engine_init_cmd_parser() - set cmd parser related fields for an engine
928 * @engine: the engine to initialize
929 *
930 * Optionally initializes fields related to batch buffer command parsing in the
931 * struct intel_engine_cs based on whether the platform requires software
932 * command parsing.
933 */
935 {
948 cmd_table_count =
953 }
961 }
975 gen9_blt_get_cmd_length_mask;
977 /* BCS Engine unsafe without parser */
985 }
997 }
1002 /* VECS can use the same length_mask function as VCS */
1008 }
1014 }
1018 }
1025 }
1028 }
1030 /**
1031 * intel_engine_cleanup_cmd_parser() - clean up cmd parser related fields
1032 * @engine: the engine to clean up
1033 *
1034 * Releases any resources related to command parsing that may have been
1035 * initialized for the specified engine.
1036 */
1038 {
1043 }
1047 u32 cmd_header)
1048 {
1056 }
1059 }
1061 /*
1062 * Returns a pointer to a descriptor for the command specified by cmd_header.
1063 *
1064 * The caller must supply space for a default descriptor via the default_desc
1065 * parameter. If no descriptor for the specified command exists in the engine's
1066 * command parser tables, this function fills in default_desc based on the
1067 * engine's default length encoding and returns default_desc.
1068 */
1071 u32 cmd_header,
1074 {
1075 u32 mask;
1093 }
1097 {
1106 else
1108 }
1110 }
1114 {
1123 }
1125 /* Returns a vmap'd pointer to dst_obj, which the caller must unmap */
1128 u32 batch_start_offset,
1129 u32 batch_len,
1131 {
1145 }
1160 }
1161 }
1168 /* We can avoid clflushing partial cachelines before the write
1169 * if we only every write full cache-lines. Since we know that
1170 * both the source and destination are in multiples of
1171 * PAGE_SIZE, we can simply round up to the next cacheline.
1172 * We don't care about copying too much here as we only
1173 * validate up to the end of the batch.
1174 */
1192 }
1193 }
1195 /* dst_obj is returned with vmap pinned */
1198 unpin_dst:
1200 unpin_src:
1203 }
1208 {
1215 }
1218 /*
1219 * Get the distance between individual register offset
1220 * fields if the command can perform more than one
1221 * access at a time.
1222 */
1224 u32 offset;
1236 }
1238 /*
1239 * Check the value written to the register against the
1240 * allowed mask/value pair given in the whitelist entry.
1241 */
1245 reg_addr);
1247 }
1251 reg_addr);
1253 }
1259 reg_addr);
1261 }
1262 }
1263 }
1264 }
1270 u32 dword;
1276 u32 offset =
1283 }
1289 }
1295 DRM_DEBUG_DRIVER("CMD: Rejected command 0x%08X for bitmask 0x%08X (exp=0x%08X act=0x%08X) (%s)\n",
1301 }
1302 }
1303 }
1306 }
1310 u32 batch_len,
1311 u64 batch_start,
1312 u64 shadow_batch_start)
1313 {
1317 /* For igt compatibility on older platforms */
1321 }
1325 length);
1327 }
1332 /*
1333 * Any underflow of jump_target is guaranteed to be outside the range
1334 * of a u32, so >= test catches both too large and too small
1335 */
1338 jump_target);
1340 }
1342 /*
1343 * This cannot overflow a u32 because we already checked jump_offset
1344 * is within the BB, and the batch_len is a u32
1345 */
1359 jump_target);
1361 }
1364 }
1367 {
1379 }
1381 again:
1389 }
1394 }
1400 }
1402 #define LENGTH_BIAS 2
1404 /**
1405 * i915_parse_cmds() - parse a submitted batch buffer for privilege violations
1406 * @ctx: the context in which the batch is to execute
1407 * @engine: the engine on which the batch is to execute
1408 * @batch_obj: the batch buffer in question
1409 * @batch_start: Canonical base address of batch
1410 * @batch_start_offset: byte offset in the batch at which execution starts
1411 * @batch_len: length of the commands in batch_obj
1412 * @shadow_batch_obj: copy of the batch buffer in question
1413 * @shadow_batch_start: Canonical base address of shadow_batch_obj
1414 *
1415 * Parses the specified batch buffer looking for privilege violations as
1416 * described in the overview.
1417 *
1418 * Return: non-zero if the parser finds violations or otherwise fails; -EACCES
1419 * if the batch appears legal but should use hardware parsing
1420 */
1425 u64 batch_start,
1426 u32 batch_start_offset,
1427 u32 batch_len,
1429 u64 shadow_batch_start)
1430 {
1443 }
1447 /*
1448 * We use the batch length as size because the shadow object is as
1449 * large or larger and copy_batch() will write MI_NOPs to the extra
1450 * space. Parsing should be faster in some cases this way.
1451 */
1454 u32 length;
1465 }
1469 else
1475 length,
1479 }
1484 }
1489 shadow_batch_start);
1494 }
1505 }
1512 }
1514 err:
1517 }
1519 /**
1520 * i915_cmd_parser_get_version() - get the cmd parser version number
1521 * @dev_priv: i915 device private
1522 *
1523 * The cmd parser maintains a simple increasing integer version number suitable
1524 * for passing to userspace clients to determine what operations are permitted.
1525 *
1526 * Return: the current version number of the cmd parser
1527 */
1529 {
1534 /* If the command parser is not enabled, report 0 - unsupported */
1539 }
1540 }
1544 /*
1545 * Command parser version history
1546 *
1547 * 1. Initial version. Checks batches and reports violations, but leaves
1548 * hardware parsing enabled (so does not allow new use cases).
1549 * 2. Allow access to the MI_PREDICATE_SRC0 and
1550 * MI_PREDICATE_SRC1 registers.
1551 * 3. Allow access to the GPGPU_THREADS_DISPATCHED register.
1552 * 4. L3 atomic chicken bits of HSW_SCRATCH1 and HSW_ROW_CHICKEN3.
1553 * 5. GPGPU dispatch compute indirect registers.
1554 * 6. TIMESTAMP register and Haswell CS GPR registers
1555 * 7. Allow MI_LOAD_REGISTER_REG between whitelisted registers.
1556 * 8. Don't report cmd_check() failures as EINVAL errors to userspace;
1557 * rely on the HW to NOOP disallowed commands as it would without
1558 * the parser enabled.
1559 * 9. Don't whitelist or handle oacontrol specially, as ownership
1560 * for oacontrol state is moving to i915-perf.
1561 * 10. Support for Gen9 BCS Parsing
1562 */
1564 }