Opis: The CERT C Coding Standard - Robert Seacord

"At Cisco, we have adopted the CERT C Coding Standard as the internal secure coding standard for all C developers. It is a core component of our secure development lifecycle. The coding standard described in this book breaks down complex software security topics into easy-to-follow rules with excellent real-world examples. It is an essential reference for any developer who wishes to write secure and resilient software in C and C++." -Edward D. Paradise, vice president, engineering, threat response, intelligence, and development, Cisco Systems Secure programming in C can be more difficult than even many experienced programmers realize. To help programmers write more secure code, The CERT(R) C Coding Standard, Second Edition, fully documents the second official release of the CERT standard for secure coding in C. The rules laid forth in this new edition will help ensure that programmers' code fully complies with the new C11 standard; it also addresses earlier versions, including C99. The new standard itemizes those coding errors that are the root causes of current software vulnerabilities in C, prioritizing them by severity, likelihood of exploitation, and remediation costs. Each of the text's 98 guidelines includes examples of insecure code as well as secure, C11-conforming, alternative implementations. If uniformly applied, these guidelines will eliminate critical coding errors that lead to buffer overflows, format-string vulnerabilities, integer overflow, and other common vulnerabilities. This book reflects numerous experts' contributions to the open development and review of the rules and recommendations that comprise this standard. Coverage includes * Preprocessor * Declarations and Initialization * Expressions * Integers * Floating Point * Arrays * Characters and Strings * Memory Management * Input/Output * Environment * Signals * Error Handling * Concurrency * Miscellaneous IssuesPreface xiii Acknowledgments xxxvii Contributors xxxix About the Author xliii Chapter 1: Preprocessor (PRE) 1 PRE30-C. Do not create a universal character name through concatenation 2 PRE31-C. Avoid side effects in arguments to unsafe macros 3 PRE32-C. Do not use preprocessor directives in invocations of function-like macros 8 Chapter 2: Declarations and Initialization (DCL) 11 DCL30-C. Declare objects with appropriate storage durations 12 DCL31-C. Declare identifiers before using them 16 DCL36-C. Do not declare an identifier with conflicting linkage classifications 20 DCL37-C. Do not declare or define a reserved identifier 23 DCL38-C. Use the correct syntax when declaring a flexible array member 29 DCL39-C. Avoid information leakage in structure padding 32 DCL40-C. Do not create incompatible declarations of the same function or object 37 DCL41-C. Do not declare variables inside a switch statement before the first case label 43 Chapter 3: Expressions (EXP) 47 EXP30-C. Do not depend on the order of evaluation for side effects 48 EXP32-C. Do not access a volatile object through a nonvolatile reference 54 EXP33-C. Do not read uninitialized memory 56 EXP34-C. Do not dereference null pointers 65 EXP35-C. Do not modify objects with temporary lifetime 70 EXP36-C. Do not cast pointers into more strictly aligned pointer types 73 EXP37-C. Call functions with the correct number and type of arguments 77 EXP39-C. Do not access a variable through a pointer of an incompatible type 83 EXP40-C. Do not modify constant objects 89 EXP42-C. Do not compare padding data 91 EXP43-C. Avoid undefined behavior when using restrict-qualified pointers 93 EXP44-C. Do not rely on side effects in operands to sizeof, _Alignof, or _Generic 102 EXP45-C. Do not perform assignments in selection statements 105 Chapter 4: Integers (INT) 111 INT30-C. Ensure that unsigned integer operations do not wrap 112 INT31-C. Ensure that integer conversions do not result in lost or misinterpreted data 118 INT32-C. Ensure that operations on signed integers do not result in overflow 126 INT33-C. Ensure that division and remainder operations do not result in divide-by-zero errors 135 INT34-C. Do not shift an expression by a negative number of bits or by greater than or equal to the number of bits that exist in the operand 138 INT35-C. Use correct integer precisions 143 INT36-C. Converting a pointer to integer or integer to pointer 145 Chapter 5: Floating Point (FLP) 151 FLP30-C. Do not use floating-point variables as loop counters 152 FLP32-C. Prevent or detect domain and range errors in math functions 154 FLP34-C. Ensure that floating-point conversions are within range of the new type 163 FLP36-C. Preserve precision when converting integral values to floating-point type 166 Chapter 6: Arrays (ARR) 169 ARR30-C. Do not form or use out-of-bounds pointers or array subscripts 170 ARR32-C. Ensure size arguments for variable length arrays are in a valid range 180 ARR36-C. Do not subtract or compare two pointers that do not refer to the same array 182 ARR37-C. Do not add or subtract an integer to a pointer to a non-array object 184 ARR38-C. Guarantee that library functions do not form invalid pointers 187 ARR39-C. Do not add or subtract a scaled integer to a pointer 196 Chapter 7: Characters and Strings (STR) 201 STR30-C. Do not attempt to modify string literals 202 STR31-C. Guarantee that storage for strings has sufficient space for character data and the null terminator 205 STR32-C. Do not pass a non-null-terminated character sequence to a library function that expects a string 218 STR34-C. Cast characters to unsigned char before converting to larger integer sizes 223 STR37-C. Arguments to character handling functions must be representable as an unsigned char 227 STR38-C. Do not confuse narrow and wide character strings and functions 229 Chapter 8: Memory Management (MEM) 233 MEM30-C. Do not access freed memory 234 MEM31-C. Free dynamically allocated memory when no longer needed 239 MEM33-C. Allocate and copy structures containing a flexible array member dynamically 241 MEM34-C. Only free memory allocated dynamically 246 MEM35-C. Allocate sufficient memory for an object 250 MEM36-C. Do not modify the alignment of objects by calling realloc() 253 Chapter 9: Input/Output (FIO) 257 FIO30-C. Exclude user input from format strings 258 FIO31-C. Do not open a file that is already open 263 FIO32-C. Do not perform operations on devices that are only appropriate for files 265 FIO34-C. Distinguish between characters read from a file and EOF or WEOF 272 FIO37-C. Do not assume that fgets() or fgetws() returns a nonempty string when successful 277 FIO38-C. Do not copy a FILE object 279 FIO39-C. Do not alternately input and output from a stream without an intervening flush or positioning call 280 FIO40-C. Reset strings on fgets() or fgetws() failure 283 FIO41-C. Do not call getc(), putc(), getwc(), or putwc() with a stream argument that has side effects 284 FIO42-C. Close files when they are no longer needed 288 FIO44-C. Only use values for fsetpos() that are returned from fgetpos() 292 FIO45-C. Avoid TOCTOU race conditions while accessing files 294 FIO46-C. Do not access a closed file 298 FIO47-C. Use valid format strings 299 Chapter 10: Environment (ENV) 305 ENV30-C. Do not modify the object referenced by the return value of certain functions 306 ENV31-C. Do not rely on an environment pointer following an operation that may invalidate it 311 ENV32-C. All exit handlers must return normally 315 ENV33-C. Do not call system() 319 ENV34-C. Do not store pointers returned by certain functions 325 Chapter 11: Signals (SIG) 333 SIG30-C. Call only asynchronous-safe functions within signal handlers 334 SIG31-C. Do not access shared objects in signal handlers 342 SIG34-C. Do not call signal() from within interruptible signal handlers 345 SIG35-C. Do not return from a computational exception signal handler 349 Chapter 12: Error Handling (ERR) 353 ERR30-C. Set errno to zero before calling a library function known to set errno, and check errno only after the function returns a value indicating failure 354 ERR32-C. Do not rely on indeterminate values of errno 361 ERR33-C. Detect and handle standard library errors 365 Chapter 13: Concurrency (CON) 383 CON30-C. Clean up thread-specific storage 384 CON31-C. Do not destroy a mutex while it is locked 388 CON32-C. Prevent data races when accessing bit-fields from multiple threads 391 CON33-C. Avoid race conditions when using library functions 394 CON34-C. Declare objects shared between threads with appropriate storage durations 398 CON35-C. Avoid deadlock by locking in a predefined order 406 CON36-C. Wrap functions that can spuriously wake up in a loop 411 CON37-C. Do not call signal() in a multithreaded program 414 CON38-C. Preserve thread-safety and liveness when using condition variables 416 CON39-C. Do not join or detach a thread that was previously joined or detached 424 CON40-C. Do not refer to an atomic variable twice in an expression 426 CON41-C. Wrap functions that can fail spuriously in a loop 430 Chapter 14: Miscellaneous (MSC) 435 MSC30-C. Do not use the rand() function for generating pseudorandom numbers 436 MSC32-C. Properly seed pseudorandom number generators 439 MSC33-C. Do not pass invalid data to the asctime() function 443 MSC37-C. Ensure that control never reaches the end of a non-void function 446 MSC38-C. Do not treat a predefined identifier as an object if it might only be implemented as a macro 449 MSC39-C. Do not call va_arg() on a va_list that has an indeterminate value 451 MSC40-C. Do not violate constraints 453 Appendix A: Glossary 459 Appendix B: Undefined Behavior 465 Appendix C: Unspecified Behavior 481 Bibliography 487 Index 495

Szczegóły: The CERT C Coding Standard - Robert Seacord

Tytuł: The CERT C Coding Standard
Autor: Robert Seacord
Producent: Addison Wesley Publishing Company
ISBN: 9780321984043
Rok produkcji: 2014
Ilość stron: 576
Oprawa: Miękka
Waga: 0.9 kg

Recenzje: The CERT C Coding Standard - Robert Seacord