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gerrit-public.fairphone.software / toolchain / llvm-project / 33de00cf5970f11437aef58f452fdc6d84f02074 / . / llvm / lib / ExecutionEngine / RuntimeDyld / RuntimeDyldChecker.cpp
blob: 02504a9cefcd3d3c7b9a3e995cee908bad9c6560 [file] [log] [blame]
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]1//===--- RuntimeDyldChecker.cpp - RuntimeDyld tester framework --*- C++ -*-===//
2//
3// The LLVM Compiler Infrastructure
4//
5// This file is distributed under the University of Illinois Open Source
6// License. See LICENSE.TXT for details.
7//
8//===----------------------------------------------------------------------===//
9
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]10#include "llvm/ADT/STLExtras.h"
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]11#include "llvm/ExecutionEngine/RuntimeDyldChecker.h"
12#include "llvm/MC/MCContext.h"
13#include "llvm/MC/MCDisassembler.h"
14#include "llvm/MC/MCInst.h"
15#include "llvm/Support/StringRefMemoryObject.h"
Lang Hames480763f2014-07-29 20:40:37 +0000[diff] [blame]16#include "llvm/Support/Path.h"
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]17#include "RuntimeDyldCheckerImpl.h"
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]18#include "RuntimeDyldImpl.h"
Lang Hames3b7ffd62014-06-27 20:37:39 +0000[diff] [blame]19#include <cctype>
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]20#include <memory>
21
22#define DEBUG_TYPE "rtdyld"
23
24using namespace llvm;
25
26namespace llvm {
27
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]28// Helper class that implements the language evaluated by RuntimeDyldChecker.
29class RuntimeDyldCheckerExprEval {
30public:
31 RuntimeDyldCheckerExprEval(const RuntimeDyldCheckerImpl &Checker,
32 raw_ostream &ErrStream)
33 : Checker(Checker) {}
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]34
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]35 bool evaluate(StringRef Expr) const {
36 // Expect equality expression of the form 'LHS = RHS'.
37 Expr = Expr.trim();
38 size_t EQIdx = Expr.find('=');
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]39
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]40 ParseContext OutsideLoad(false);
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]41
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]42 // Evaluate LHS.
43 StringRef LHSExpr = Expr.substr(0, EQIdx).rtrim();
44 StringRef RemainingExpr;
45 EvalResult LHSResult;
46 std::tie(LHSResult, RemainingExpr) =
47 evalComplexExpr(evalSimpleExpr(LHSExpr, OutsideLoad), OutsideLoad);
48 if (LHSResult.hasError())
49 return handleError(Expr, LHSResult);
50 if (RemainingExpr != "")
51 return handleError(Expr, unexpectedToken(RemainingExpr, LHSExpr, ""));
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]52
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]53 // Evaluate RHS.
54 StringRef RHSExpr = Expr.substr(EQIdx + 1).ltrim();
55 EvalResult RHSResult;
56 std::tie(RHSResult, RemainingExpr) =
57 evalComplexExpr(evalSimpleExpr(RHSExpr, OutsideLoad), OutsideLoad);
58 if (RHSResult.hasError())
59 return handleError(Expr, RHSResult);
60 if (RemainingExpr != "")
61 return handleError(Expr, unexpectedToken(RemainingExpr, RHSExpr, ""));
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]62
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]63 if (LHSResult.getValue() != RHSResult.getValue()) {
64 Checker.ErrStream << "Expression '" << Expr << "' is false: "
Lang Hamesb2eb4922014-07-29 21:38:20 +0000[diff] [blame]65 << format("0x%" PRIx64, LHSResult.getValue())
66 << " != " << format("0x%" PRIx64, RHSResult.getValue())
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]67 << "\n";
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]68 return false;
69 }
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]70 return true;
71 }
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]72
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]73private:
74 // RuntimeDyldCheckerExprEval requires some context when parsing exprs. In
75 // particular, it needs to know whether a symbol is being evaluated in the
76 // context of a load, in which case we want the linker's local address for
77 // the symbol, or outside of a load, in which case we want the symbol's
78 // address in the remote target.
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]79
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]80 struct ParseContext {
81 bool IsInsideLoad;
82 ParseContext(bool IsInsideLoad) : IsInsideLoad(IsInsideLoad) {}
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]83 };
84
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]85 const RuntimeDyldCheckerImpl &Checker;
86
87 enum class BinOpToken : unsigned {
88 Invalid,
89 Add,
90 Sub,
91 BitwiseAnd,
92 BitwiseOr,
93 ShiftLeft,
94 ShiftRight
95 };
96
97 class EvalResult {
98 public:
99 EvalResult() : Value(0), ErrorMsg("") {}
100 EvalResult(uint64_t Value) : Value(Value), ErrorMsg("") {}
101 EvalResult(std::string ErrorMsg) : Value(0), ErrorMsg(ErrorMsg) {}
102 uint64_t getValue() const { return Value; }
103 bool hasError() const { return ErrorMsg != ""; }
104 const std::string &getErrorMsg() const { return ErrorMsg; }
105
106 private:
107 uint64_t Value;
108 std::string ErrorMsg;
109 };
110
111 StringRef getTokenForError(StringRef Expr) const {
112 if (Expr.empty())
113 return "";
114
115 StringRef Token, Remaining;
116 if (isalpha(Expr[0]))
117 std::tie(Token, Remaining) = parseSymbol(Expr);
118 else if (isdigit(Expr[0]))
119 std::tie(Token, Remaining) = parseNumberString(Expr);
120 else {
121 unsigned TokLen = 1;
122 if (Expr.startswith("<<") || Expr.startswith(">>"))
123 TokLen = 2;
124 Token = Expr.substr(0, TokLen);
125 }
126 return Token;
127 }
128
129 EvalResult unexpectedToken(StringRef TokenStart, StringRef SubExpr,
130 StringRef ErrText) const {
131 std::string ErrorMsg("Encountered unexpected token '");
132 ErrorMsg += getTokenForError(TokenStart);
133 if (SubExpr != "") {
134 ErrorMsg += "' while parsing subexpression '";
135 ErrorMsg += SubExpr;
136 }
137 ErrorMsg += "'";
138 if (ErrText != "") {
139 ErrorMsg += " ";
140 ErrorMsg += ErrText;
141 }
142 return EvalResult(std::move(ErrorMsg));
143 }
144
145 bool handleError(StringRef Expr, const EvalResult &R) const {
146 assert(R.hasError() && "Not an error result.");
147 Checker.ErrStream << "Error evaluating expression '" << Expr
148 << "': " << R.getErrorMsg() << "\n";
149 return false;
150 }
151
152 std::pair<BinOpToken, StringRef> parseBinOpToken(StringRef Expr) const {
153 if (Expr.empty())
154 return std::make_pair(BinOpToken::Invalid, "");
155
156 // Handle the two 2-character tokens.
157 if (Expr.startswith("<<"))
158 return std::make_pair(BinOpToken::ShiftLeft, Expr.substr(2).ltrim());
159 if (Expr.startswith(">>"))
160 return std::make_pair(BinOpToken::ShiftRight, Expr.substr(2).ltrim());
161
162 // Handle one-character tokens.
163 BinOpToken Op;
164 switch (Expr[0]) {
165 default:
166 return std::make_pair(BinOpToken::Invalid, Expr);
167 case '+':
168 Op = BinOpToken::Add;
169 break;
170 case '-':
171 Op = BinOpToken::Sub;
172 break;
173 case '&':
174 Op = BinOpToken::BitwiseAnd;
175 break;
176 case '|':
177 Op = BinOpToken::BitwiseOr;
178 break;
179 }
180
181 return std::make_pair(Op, Expr.substr(1).ltrim());
182 }
183
184 EvalResult computeBinOpResult(BinOpToken Op, const EvalResult &LHSResult,
185 const EvalResult &RHSResult) const {
186 switch (Op) {
187 default:
188 llvm_unreachable("Tried to evaluate unrecognized operation.");
189 case BinOpToken::Add:
190 return EvalResult(LHSResult.getValue() + RHSResult.getValue());
191 case BinOpToken::Sub:
192 return EvalResult(LHSResult.getValue() - RHSResult.getValue());
193 case BinOpToken::BitwiseAnd:
194 return EvalResult(LHSResult.getValue() & RHSResult.getValue());
195 case BinOpToken::BitwiseOr:
196 return EvalResult(LHSResult.getValue() | RHSResult.getValue());
197 case BinOpToken::ShiftLeft:
198 return EvalResult(LHSResult.getValue() << RHSResult.getValue());
199 case BinOpToken::ShiftRight:
200 return EvalResult(LHSResult.getValue() >> RHSResult.getValue());
201 }
202 }
203
204 // Parse a symbol and return a (string, string) pair representing the symbol
205 // name and expression remaining to be parsed.
206 std::pair<StringRef, StringRef> parseSymbol(StringRef Expr) const {
207 size_t FirstNonSymbol = Expr.find_first_not_of("0123456789"
208 "abcdefghijklmnopqrstuvwxyz"
209 "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
210 ":_.");
211 return std::make_pair(Expr.substr(0, FirstNonSymbol),
212 Expr.substr(FirstNonSymbol).ltrim());
213 }
214
215 // Evaluate a call to decode_operand. Decode the instruction operand at the
216 // given symbol and get the value of the requested operand.
217 // Returns an error if the instruction cannot be decoded, or the requested
218 // operand is not an immediate.
219 // On success, retuns a pair containing the value of the operand, plus
220 // the expression remaining to be evaluated.
221 std::pair<EvalResult, StringRef> evalDecodeOperand(StringRef Expr) const {
222 if (!Expr.startswith("("))
223 return std::make_pair(unexpectedToken(Expr, Expr, "expected '('"), "");
224 StringRef RemainingExpr = Expr.substr(1).ltrim();
225 StringRef Symbol;
226 std::tie(Symbol, RemainingExpr) = parseSymbol(RemainingExpr);
227
228 if (!Checker.isSymbolValid(Symbol))
229 return std::make_pair(
230 EvalResult(("Cannot decode unknown symbol '" + Symbol + "'").str()),
231 "");
232
233 if (!RemainingExpr.startswith(","))
234 return std::make_pair(
235 unexpectedToken(RemainingExpr, RemainingExpr, "expected ','"), "");
236 RemainingExpr = RemainingExpr.substr(1).ltrim();
237
238 EvalResult OpIdxExpr;
239 std::tie(OpIdxExpr, RemainingExpr) = evalNumberExpr(RemainingExpr);
240 if (OpIdxExpr.hasError())
241 return std::make_pair(OpIdxExpr, "");
242
243 if (!RemainingExpr.startswith(")"))
244 return std::make_pair(
245 unexpectedToken(RemainingExpr, RemainingExpr, "expected ')'"), "");
246 RemainingExpr = RemainingExpr.substr(1).ltrim();
247
248 MCInst Inst;
249 uint64_t Size;
250 if (!decodeInst(Symbol, Inst, Size))
251 return std::make_pair(
252 EvalResult(("Couldn't decode instruction at '" + Symbol + "'").str()),
253 "");
254
255 unsigned OpIdx = OpIdxExpr.getValue();
256 if (OpIdx >= Inst.getNumOperands()) {
257 std::string ErrMsg;
258 raw_string_ostream ErrMsgStream(ErrMsg);
259 ErrMsgStream << "Invalid operand index '" << format("%i", OpIdx)
260 << "' for instruction '" << Symbol
261 << "'. Instruction has only "
262 << format("%i", Inst.getNumOperands())
263 << " operands.\nInstruction is:\n ";
264 Inst.dump_pretty(ErrMsgStream,
265 Checker.Disassembler->getContext().getAsmInfo(),
266 Checker.InstPrinter);
267 return std::make_pair(EvalResult(ErrMsgStream.str()), "");
268 }
269
270 const MCOperand &Op = Inst.getOperand(OpIdx);
271 if (!Op.isImm()) {
272 std::string ErrMsg;
273 raw_string_ostream ErrMsgStream(ErrMsg);
274 ErrMsgStream << "Operand '" << format("%i", OpIdx) << "' of instruction '"
275 << Symbol << "' is not an immediate.\nInstruction is:\n ";
276 Inst.dump_pretty(ErrMsgStream,
277 Checker.Disassembler->getContext().getAsmInfo(),
278 Checker.InstPrinter);
279
280 return std::make_pair(EvalResult(ErrMsgStream.str()), "");
281 }
282
283 return std::make_pair(EvalResult(Op.getImm()), RemainingExpr);
284 }
285
286 // Evaluate a call to next_pc.
287 // Decode the instruction at the given symbol and return the following program
288 // counter.
289 // Returns an error if the instruction cannot be decoded.
290 // On success, returns a pair containing the next PC, plus of the
291 // expression remaining to be evaluated.
292 std::pair<EvalResult, StringRef> evalNextPC(StringRef Expr,
293 ParseContext PCtx) const {
294 if (!Expr.startswith("("))
295 return std::make_pair(unexpectedToken(Expr, Expr, "expected '('"), "");
296 StringRef RemainingExpr = Expr.substr(1).ltrim();
297 StringRef Symbol;
298 std::tie(Symbol, RemainingExpr) = parseSymbol(RemainingExpr);
299
300 if (!Checker.isSymbolValid(Symbol))
301 return std::make_pair(
302 EvalResult(("Cannot decode unknown symbol '" + Symbol + "'").str()),
303 "");
304
305 if (!RemainingExpr.startswith(")"))
306 return std::make_pair(
307 unexpectedToken(RemainingExpr, RemainingExpr, "expected ')'"), "");
308 RemainingExpr = RemainingExpr.substr(1).ltrim();
309
310 MCInst Inst;
311 uint64_t InstSize;
312 if (!decodeInst(Symbol, Inst, InstSize))
313 return std::make_pair(
314 EvalResult(("Couldn't decode instruction at '" + Symbol + "'").str()),
315 "");
316
317 uint64_t SymbolAddr = PCtx.IsInsideLoad
318 ? Checker.getSymbolLinkerAddr(Symbol)
319 : Checker.getSymbolRemoteAddr(Symbol);
320 uint64_t NextPC = SymbolAddr + InstSize;
321
322 return std::make_pair(EvalResult(NextPC), RemainingExpr);
323 }
324
325 // Evaluate a call to stub_addr.
326 // Look up and return the address of the stub for the given
327 // (<file name>, <section name>, <symbol name>) tuple.
328 // On success, returns a pair containing the stub address, plus the expression
329 // remaining to be evaluated.
330 std::pair<EvalResult, StringRef> evalStubAddr(StringRef Expr,
331 ParseContext PCtx) const {
332 if (!Expr.startswith("("))
333 return std::make_pair(unexpectedToken(Expr, Expr, "expected '('"), "");
334 StringRef RemainingExpr = Expr.substr(1).ltrim();
335
336 // Handle file-name specially, as it may contain characters that aren't
337 // legal for symbols.
338 StringRef FileName;
339 size_t ComaIdx = RemainingExpr.find(',');
340 FileName = RemainingExpr.substr(0, ComaIdx).rtrim();
341 RemainingExpr = RemainingExpr.substr(ComaIdx).ltrim();
342
343 if (!RemainingExpr.startswith(","))
344 return std::make_pair(
345 unexpectedToken(RemainingExpr, Expr, "expected ','"), "");
346 RemainingExpr = RemainingExpr.substr(1).ltrim();
347
348 StringRef SectionName;
349 std::tie(SectionName, RemainingExpr) = parseSymbol(RemainingExpr);
350
351 if (!RemainingExpr.startswith(","))
352 return std::make_pair(
353 unexpectedToken(RemainingExpr, Expr, "expected ','"), "");
354 RemainingExpr = RemainingExpr.substr(1).ltrim();
355
356 StringRef Symbol;
357 std::tie(Symbol, RemainingExpr) = parseSymbol(RemainingExpr);
358
359 if (!RemainingExpr.startswith(")"))
360 return std::make_pair(
361 unexpectedToken(RemainingExpr, Expr, "expected ')'"), "");
362 RemainingExpr = RemainingExpr.substr(1).ltrim();
363
364 uint64_t StubAddr;
365 std::string ErrorMsg = "";
366 std::tie(StubAddr, ErrorMsg) = Checker.getStubAddrFor(
367 FileName, SectionName, Symbol, PCtx.IsInsideLoad);
368
369 if (ErrorMsg != "")
370 return std::make_pair(EvalResult(ErrorMsg), "");
371
372 return std::make_pair(EvalResult(StubAddr), RemainingExpr);
373 }
374
375 // Evaluate an identiefer expr, which may be a symbol, or a call to
376 // one of the builtin functions: get_insn_opcode or get_insn_length.
377 // Return the result, plus the expression remaining to be parsed.
378 std::pair<EvalResult, StringRef> evalIdentifierExpr(StringRef Expr,
379 ParseContext PCtx) const {
380 StringRef Symbol;
381 StringRef RemainingExpr;
382 std::tie(Symbol, RemainingExpr) = parseSymbol(Expr);
383
384 // Check for builtin function calls.
385 if (Symbol == "decode_operand")
386 return evalDecodeOperand(RemainingExpr);
387 else if (Symbol == "next_pc")
388 return evalNextPC(RemainingExpr, PCtx);
389 else if (Symbol == "stub_addr")
390 return evalStubAddr(RemainingExpr, PCtx);
391
392 if (!Checker.isSymbolValid(Symbol)) {
393 std::string ErrMsg("No known address for symbol '");
394 ErrMsg += Symbol;
395 ErrMsg += "'";
396 if (Symbol.startswith("L"))
397 ErrMsg += " (this appears to be an assembler local label - "
398 " perhaps drop the 'L'?)";
399
400 return std::make_pair(EvalResult(ErrMsg), "");
401 }
402
403 // The value for the symbol depends on the context we're evaluating in:
404 // Inside a load this is the address in the linker's memory, outside a
405 // load it's the address in the target processes memory.
406 uint64_t Value = PCtx.IsInsideLoad ? Checker.getSymbolLinkerAddr(Symbol)
407 : Checker.getSymbolRemoteAddr(Symbol);
408
409 // Looks like a plain symbol reference.
410 return std::make_pair(EvalResult(Value), RemainingExpr);
411 }
412
413 // Parse a number (hexadecimal or decimal) and return a (string, string)
414 // pair representing the number and the expression remaining to be parsed.
415 std::pair<StringRef, StringRef> parseNumberString(StringRef Expr) const {
416 size_t FirstNonDigit = StringRef::npos;
417 if (Expr.startswith("0x")) {
418 FirstNonDigit = Expr.find_first_not_of("0123456789abcdefABCDEF", 2);
419 if (FirstNonDigit == StringRef::npos)
420 FirstNonDigit = Expr.size();
421 } else {
422 FirstNonDigit = Expr.find_first_not_of("0123456789");
423 if (FirstNonDigit == StringRef::npos)
424 FirstNonDigit = Expr.size();
425 }
426 return std::make_pair(Expr.substr(0, FirstNonDigit),
427 Expr.substr(FirstNonDigit));
428 }
429
430 // Evaluate a constant numeric expression (hexidecimal or decimal) and
431 // return a pair containing the result, and the expression remaining to be
432 // evaluated.
433 std::pair<EvalResult, StringRef> evalNumberExpr(StringRef Expr) const {
434 StringRef ValueStr;
435 StringRef RemainingExpr;
436 std::tie(ValueStr, RemainingExpr) = parseNumberString(Expr);
437
438 if (ValueStr.empty() || !isdigit(ValueStr[0]))
439 return std::make_pair(
440 unexpectedToken(RemainingExpr, RemainingExpr, "expected number"), "");
441 uint64_t Value;
442 ValueStr.getAsInteger(0, Value);
443 return std::make_pair(EvalResult(Value), RemainingExpr);
444 }
445
446 // Evaluate an expression of the form "(<expr>)" and return a pair
447 // containing the result of evaluating <expr>, plus the expression
448 // remaining to be parsed.
449 std::pair<EvalResult, StringRef> evalParensExpr(StringRef Expr,
450 ParseContext PCtx) const {
451 assert(Expr.startswith("(") && "Not a parenthesized expression");
452 EvalResult SubExprResult;
453 StringRef RemainingExpr;
454 std::tie(SubExprResult, RemainingExpr) =
455 evalComplexExpr(evalSimpleExpr(Expr.substr(1).ltrim(), PCtx), PCtx);
456 if (SubExprResult.hasError())
457 return std::make_pair(SubExprResult, "");
458 if (!RemainingExpr.startswith(")"))
459 return std::make_pair(
460 unexpectedToken(RemainingExpr, Expr, "expected ')'"), "");
461 RemainingExpr = RemainingExpr.substr(1).ltrim();
462 return std::make_pair(SubExprResult, RemainingExpr);
463 }
464
465 // Evaluate an expression in one of the following forms:
466 // *{<number>}<expr>
467 // Return a pair containing the result, plus the expression remaining to be
468 // parsed.
469 std::pair<EvalResult, StringRef> evalLoadExpr(StringRef Expr) const {
470 assert(Expr.startswith("*") && "Not a load expression");
471 StringRef RemainingExpr = Expr.substr(1).ltrim();
472
473 // Parse read size.
474 if (!RemainingExpr.startswith("{"))
475 return std::make_pair(EvalResult("Expected '{' following '*'."), "");
476 RemainingExpr = RemainingExpr.substr(1).ltrim();
477 EvalResult ReadSizeExpr;
478 std::tie(ReadSizeExpr, RemainingExpr) = evalNumberExpr(RemainingExpr);
479 if (ReadSizeExpr.hasError())
480 return std::make_pair(ReadSizeExpr, RemainingExpr);
481 uint64_t ReadSize = ReadSizeExpr.getValue();
482 if (ReadSize < 1 || ReadSize > 8)
483 return std::make_pair(EvalResult("Invalid size for dereference."), "");
484 if (!RemainingExpr.startswith("}"))
485 return std::make_pair(EvalResult("Missing '}' for dereference."), "");
486 RemainingExpr = RemainingExpr.substr(1).ltrim();
487
488 // Evaluate the expression representing the load address.
489 ParseContext LoadCtx(true);
490 EvalResult LoadAddrExprResult;
491 std::tie(LoadAddrExprResult, RemainingExpr) =
492 evalComplexExpr(evalSimpleExpr(RemainingExpr, LoadCtx), LoadCtx);
493
494 if (LoadAddrExprResult.hasError())
495 return std::make_pair(LoadAddrExprResult, "");
496
497 uint64_t LoadAddr = LoadAddrExprResult.getValue();
498
499 return std::make_pair(
500 EvalResult(Checker.readMemoryAtAddr(LoadAddr, ReadSize)),
501 RemainingExpr);
502 }
503
504 // Evaluate a "simple" expression. This is any expression that _isn't_ an
505 // un-parenthesized binary expression.
506 //
507 // "Simple" expressions can be optionally bit-sliced. See evalSlicedExpr.
508 //
509 // Returns a pair containing the result of the evaluation, plus the
510 // expression remaining to be parsed.
511 std::pair<EvalResult, StringRef> evalSimpleExpr(StringRef Expr,
512 ParseContext PCtx) const {
513 EvalResult SubExprResult;
514 StringRef RemainingExpr;
515
516 if (Expr.empty())
517 return std::make_pair(EvalResult("Unexpected end of expression"), "");
518
519 if (Expr[0] == '(')
520 std::tie(SubExprResult, RemainingExpr) = evalParensExpr(Expr, PCtx);
521 else if (Expr[0] == '*')
522 std::tie(SubExprResult, RemainingExpr) = evalLoadExpr(Expr);
Lang Hamesc90a85ff2014-07-22 23:17:21 +0000[diff] [blame]523 else if (isalpha(Expr[0]) || Expr[0] == '_')
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]524 std::tie(SubExprResult, RemainingExpr) = evalIdentifierExpr(Expr, PCtx);
525 else if (isdigit(Expr[0]))
526 std::tie(SubExprResult, RemainingExpr) = evalNumberExpr(Expr);
527
528 if (SubExprResult.hasError())
529 return std::make_pair(SubExprResult, RemainingExpr);
530
531 // Evaluate bit-slice if present.
532 if (RemainingExpr.startswith("["))
533 std::tie(SubExprResult, RemainingExpr) =
534 evalSliceExpr(std::make_pair(SubExprResult, RemainingExpr));
535
536 return std::make_pair(SubExprResult, RemainingExpr);
537 }
538
539 // Evaluate a bit-slice of an expression.
540 // A bit-slice has the form "<expr>[high:low]". The result of evaluating a
541 // slice is the bits between high and low (inclusive) in the original
542 // expression, right shifted so that the "low" bit is in position 0 in the
543 // result.
544 // Returns a pair containing the result of the slice operation, plus the
545 // expression remaining to be parsed.
546 std::pair<EvalResult, StringRef>
547 evalSliceExpr(std::pair<EvalResult, StringRef> Ctx) const {
548 EvalResult SubExprResult;
549 StringRef RemainingExpr;
550 std::tie(SubExprResult, RemainingExpr) = Ctx;
551
552 assert(RemainingExpr.startswith("[") && "Not a slice expr.");
553 RemainingExpr = RemainingExpr.substr(1).ltrim();
554
555 EvalResult HighBitExpr;
556 std::tie(HighBitExpr, RemainingExpr) = evalNumberExpr(RemainingExpr);
557
558 if (HighBitExpr.hasError())
559 return std::make_pair(HighBitExpr, RemainingExpr);
560
561 if (!RemainingExpr.startswith(":"))
562 return std::make_pair(
563 unexpectedToken(RemainingExpr, RemainingExpr, "expected ':'"), "");
564 RemainingExpr = RemainingExpr.substr(1).ltrim();
565
566 EvalResult LowBitExpr;
567 std::tie(LowBitExpr, RemainingExpr) = evalNumberExpr(RemainingExpr);
568
569 if (LowBitExpr.hasError())
570 return std::make_pair(LowBitExpr, RemainingExpr);
571
572 if (!RemainingExpr.startswith("]"))
573 return std::make_pair(
574 unexpectedToken(RemainingExpr, RemainingExpr, "expected ']'"), "");
575 RemainingExpr = RemainingExpr.substr(1).ltrim();
576
577 unsigned HighBit = HighBitExpr.getValue();
578 unsigned LowBit = LowBitExpr.getValue();
579 uint64_t Mask = ((uint64_t)1 << (HighBit - LowBit + 1)) - 1;
580 uint64_t SlicedValue = (SubExprResult.getValue() >> LowBit) & Mask;
581 return std::make_pair(EvalResult(SlicedValue), RemainingExpr);
582 }
583
584 // Evaluate a "complex" expression.
585 // Takes an already evaluated subexpression and checks for the presence of a
586 // binary operator, computing the result of the binary operation if one is
587 // found. Used to make arithmetic expressions left-associative.
588 // Returns a pair containing the ultimate result of evaluating the
589 // expression, plus the expression remaining to be evaluated.
590 std::pair<EvalResult, StringRef>
591 evalComplexExpr(std::pair<EvalResult, StringRef> LHSAndRemaining,
592 ParseContext PCtx) const {
593 EvalResult LHSResult;
594 StringRef RemainingExpr;
595 std::tie(LHSResult, RemainingExpr) = LHSAndRemaining;
596
597 // If there was an error, or there's nothing left to evaluate, return the
598 // result.
599 if (LHSResult.hasError() || RemainingExpr == "")
600 return std::make_pair(LHSResult, RemainingExpr);
601
602 // Otherwise check if this is a binary expressioan.
603 BinOpToken BinOp;
604 std::tie(BinOp, RemainingExpr) = parseBinOpToken(RemainingExpr);
605
606 // If this isn't a recognized expression just return.
607 if (BinOp == BinOpToken::Invalid)
608 return std::make_pair(LHSResult, RemainingExpr);
609
610 // This is a recognized bin-op. Evaluate the RHS, then evaluate the binop.
611 EvalResult RHSResult;
612 std::tie(RHSResult, RemainingExpr) = evalSimpleExpr(RemainingExpr, PCtx);
613
614 // If there was an error evaluating the RHS, return it.
615 if (RHSResult.hasError())
616 return std::make_pair(RHSResult, RemainingExpr);
617
618 // This is a binary expression - evaluate and try to continue as a
619 // complex expr.
620 EvalResult ThisResult(computeBinOpResult(BinOp, LHSResult, RHSResult));
621
622 return evalComplexExpr(std::make_pair(ThisResult, RemainingExpr), PCtx);
623 }
624
625 bool decodeInst(StringRef Symbol, MCInst &Inst, uint64_t &Size) const {
626 MCDisassembler *Dis = Checker.Disassembler;
627 StringRef SectionMem = Checker.getSubsectionStartingAt(Symbol);
628 StringRefMemoryObject SectionBytes(SectionMem, 0);
629
630 MCDisassembler::DecodeStatus S =
631 Dis->getInstruction(Inst, Size, SectionBytes, 0, nulls(), nulls());
632
633 return (S == MCDisassembler::Success);
634 }
635};
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]636}
637
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]638RuntimeDyldCheckerImpl::RuntimeDyldCheckerImpl(RuntimeDyld &RTDyld,
639 MCDisassembler *Disassembler,
640 MCInstPrinter *InstPrinter,
641 raw_ostream &ErrStream)
642 : RTDyld(RTDyld), Disassembler(Disassembler), InstPrinter(InstPrinter),
643 ErrStream(ErrStream) {
644 RTDyld.Checker = this;
645}
646
647bool RuntimeDyldCheckerImpl::check(StringRef CheckExpr) const {
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]648 CheckExpr = CheckExpr.trim();
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]649 DEBUG(dbgs() << "RuntimeDyldChecker: Checking '" << CheckExpr << "'...\n");
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]650 RuntimeDyldCheckerExprEval P(*this, ErrStream);
651 bool Result = P.evaluate(CheckExpr);
652 (void)Result;
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]653 DEBUG(dbgs() << "RuntimeDyldChecker: '" << CheckExpr << "' "
654 << (Result ? "passed" : "FAILED") << ".\n");
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]655 return Result;
656}
657
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]658bool RuntimeDyldCheckerImpl::checkAllRulesInBuffer(StringRef RulePrefix,
659 MemoryBuffer *MemBuf) const {
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]660 bool DidAllTestsPass = true;
661 unsigned NumRules = 0;
662
663 const char *LineStart = MemBuf->getBufferStart();
664
665 // Eat whitespace.
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]666 while (LineStart != MemBuf->getBufferEnd() && std::isspace(*LineStart))
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]667 ++LineStart;
668
669 while (LineStart != MemBuf->getBufferEnd() && *LineStart != '\0') {
670 const char *LineEnd = LineStart;
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]671 while (LineEnd != MemBuf->getBufferEnd() && *LineEnd != '\r' &&
672 *LineEnd != '\n')
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]673 ++LineEnd;
674
675 StringRef Line(LineStart, LineEnd - LineStart);
676 if (Line.startswith(RulePrefix)) {
677 DidAllTestsPass &= check(Line.substr(RulePrefix.size()));
678 ++NumRules;
679 }
680
681 // Eat whitespace.
682 LineStart = LineEnd;
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]683 while (LineStart != MemBuf->getBufferEnd() && std::isspace(*LineStart))
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]684 ++LineStart;
685 }
686 return DidAllTestsPass && (NumRules != 0);
687}
688
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]689bool RuntimeDyldCheckerImpl::isSymbolValid(StringRef Symbol) const {
690 return getRTDyld().getSymbolAddress(Symbol) != nullptr;
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]691}
692
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]693uint64_t RuntimeDyldCheckerImpl::getSymbolLinkerAddr(StringRef Symbol) const {
694 return static_cast<uint64_t>(
695 reinterpret_cast<uintptr_t>(getRTDyld().getSymbolAddress(Symbol)));
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]696}
697
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]698uint64_t RuntimeDyldCheckerImpl::getSymbolRemoteAddr(StringRef Symbol) const {
699 return getRTDyld().getAnySymbolRemoteAddress(Symbol);
700}
701
702uint64_t RuntimeDyldCheckerImpl::readMemoryAtAddr(uint64_t SrcAddr,
703 unsigned Size) const {
704 uintptr_t PtrSizedAddr = static_cast<uintptr_t>(SrcAddr);
705 assert(PtrSizedAddr == SrcAddr && "Linker memory pointer out-of-range.");
706 uint8_t *Src = reinterpret_cast<uint8_t *>(PtrSizedAddr);
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]707 uint64_t Result = 0;
Lang Hames4f867bf2014-08-18 21:43:16 +0000[diff] [blame]708
709 // If host and target endianness match use memcpy, otherwise copy in reverse
710 // order.
711 if (getRTDyld().IsTargetLittleEndian == sys::IsLittleEndianHost)
712 memcpy(&Result, Src, Size);
713 else {
714 uint8_t *Dst = reinterpret_cast<uint8_t*>(&Result) + Size - 1;
715 for (unsigned i = 0; i < Size; ++i)
716 *Dst-- = *Src++;
717 }
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]718 return Result;
719}
720
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]721std::pair<uint64_t, std::string> RuntimeDyldCheckerImpl::getStubAddrFor(
722 StringRef FileName, StringRef SectionName, StringRef SymbolName,
723 bool IsInsideLoad) const {
724
725 auto SI1 = Stubs.find(FileName);
Lang Hamescce313b2014-07-22 23:07:52 +0000[diff] [blame]726 if (SI1 == Stubs.end()) {
727 std::string ErrorMsg = "File '";
728 ErrorMsg += FileName;
729 ErrorMsg += "' not found. ";
730 if (Stubs.empty())
731 ErrorMsg += "No stubs registered.";
732 else {
733 ErrorMsg += "Available files are:";
734 for (const auto& StubEntry : Stubs) {
735 ErrorMsg += " '";
736 ErrorMsg += StubEntry.first;
737 ErrorMsg += "'";
738 }
739 }
740 ErrorMsg += "\n";
741 return std::make_pair(0, ErrorMsg);
742 }
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]743
744 const SectionStubMap &SectionStubs = SI1->second;
745 auto SI2 = SectionStubs.find(SectionName);
746 if (SI2 == SectionStubs.end())
747 return std::make_pair(0,
748 ("Section '" + SectionName + "' not found.\n").str());
749
750 const SymbolStubMap &SymbolStubs = SI2->second;
751 auto SI3 = SymbolStubs.find(SymbolName);
752 if (SI3 == SymbolStubs.end())
753 return std::make_pair(0,
754 ("Symbol '" + SymbolName + "' not found.\n").str());
755
756 unsigned SectionID = SI3->second.first;
757 uint64_t StubOffset = SI3->second.second;
758
759 uint64_t Addr;
760 if (IsInsideLoad) {
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]761 uintptr_t SectionBase =
762 reinterpret_cast<uintptr_t>(getRTDyld().Sections[SectionID].Address);
763 Addr = static_cast<uint64_t>(SectionBase) + StubOffset;
Lang Hames9cb73532014-07-29 23:43:13 +0000[diff] [blame]764 } else {
765 uint64_t SectionBase = getRTDyld().Sections[SectionID].LoadAddress;
766 Addr = SectionBase + StubOffset;
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]767 }
768
769 return std::make_pair(Addr, std::string(""));
770}
771
772StringRef
773RuntimeDyldCheckerImpl::getSubsectionStartingAt(StringRef Name) const {
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]774 RuntimeDyldImpl::SymbolTableMap::const_iterator pos =
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]775 getRTDyld().GlobalSymbolTable.find(Name);
776 if (pos == getRTDyld().GlobalSymbolTable.end())
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]777 return StringRef();
778 RuntimeDyldImpl::SymbolLoc Loc = pos->second;
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]779 uint8_t *SectionAddr = getRTDyld().getSectionAddress(Loc.first);
780 return StringRef(reinterpret_cast<const char *>(SectionAddr) + Loc.second,
781 getRTDyld().Sections[Loc.first].Size - Loc.second);
782}
783
784void RuntimeDyldCheckerImpl::registerStubMap(
Lang Hames480763f2014-07-29 20:40:37 +0000[diff] [blame]785 StringRef FilePath, unsigned SectionID,
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]786 const RuntimeDyldImpl::StubMap &RTDyldStubs) {
Lang Hames480763f2014-07-29 20:40:37 +0000[diff] [blame]787 StringRef FileName = sys::path::filename(FilePath);
Lang Hamesf7acddd2014-07-22 22:47:39 +0000[diff] [blame]788 const SectionEntry &Section = getRTDyld().Sections[SectionID];
789 StringRef SectionName = Section.Name;
790 for (auto &StubMapEntry : RTDyldStubs) {
791 std::string SymbolName = "";
792
793 if (StubMapEntry.first.SymbolName)
794 SymbolName = StubMapEntry.first.SymbolName;
795 else {
796 // If this is a (Section, Offset) pair, do a reverse lookup in the
797 // global symbol table to find the name.
798 for (auto &GSTEntry : getRTDyld().GlobalSymbolTable) {
799 if (GSTEntry.second.first == StubMapEntry.first.SectionID &&
800 GSTEntry.second.second ==
801 static_cast<uint64_t>(StubMapEntry.first.Addend)) {
802 SymbolName = GSTEntry.first();
803 break;
804 }
805 }
806 }
807
808 if (SymbolName != "")
809 Stubs[FileName][SectionName][SymbolName] =
810 StubLoc(SectionID, StubMapEntry.second);
811 }
812}
813
814RuntimeDyldChecker::RuntimeDyldChecker(RuntimeDyld &RTDyld,
815 MCDisassembler *Disassembler,
816 MCInstPrinter *InstPrinter,
817 raw_ostream &ErrStream)
818 : Impl(make_unique<RuntimeDyldCheckerImpl>(RTDyld, Disassembler,
819 InstPrinter, ErrStream)) {}
820
821RuntimeDyldChecker::~RuntimeDyldChecker() {}
822
823bool RuntimeDyldChecker::check(StringRef CheckExpr) const {
824 return Impl->check(CheckExpr);
825}
826
827bool RuntimeDyldChecker::checkAllRulesInBuffer(StringRef RulePrefix,
828 MemoryBuffer *MemBuf) const {
829 return Impl->checkAllRulesInBuffer(RulePrefix, MemBuf);
Lang Hamese1c11382014-06-27 20:20:57 +0000[diff] [blame]830}