ref: d74fdfc022acde11b522fcc77beed10880784cbc
dir: /sys/man/2/mach/
.TH MACH 2 .SH NAME crackhdr, machbytype, machbyname, newmap, setmap, findseg, unusemap, loadmap, attachproc, get1, get2, get4, get8, geta, put1, put2, put4, put8, puta beswab, beswal, beswav, leswab, leswal, leswav \- machine-independent access to executable files .SH SYNOPSIS .B #include <u.h> .br .B #include <libc.h> .br .B #include <bio.h> .br .B #include <mach.h> .PP .ta \w'\fLmachines 'u .B int crackhdr(int fd, Fhdr *fp) .PP .B void machbytype(int type) .PP .B int machbyname(char *name) .PP .B Map *newmap(Map *map, int n) .PP .B int setmap(Map *map, int fd, uvlong base, uvlong end, .PP .B vlong foffset, char *name) .PP .B int findseg(Map *map, char *name) .PP .B void unusemap(Map *map, int seg) .PP .B Map *loadmap(Map *map, int fd, Fhdr *fp) .PP .B Map *attachproc(int pid, int kflag, int corefd, Fhdr *fp) .PP .B int get1(Map *map, uvlong addr, uchar *buf, int n) .PP .B int get2(Map *map, uvlong addr, ushort *val) .PP .B int get4(Map *map, uvlong addr, ulong *val) .PP .B int get8(Map *map, uvlong addr, uvlong *val) .PP .B int geta(Map *map, uvlong addr, uvlong *val) .PP .B int put1(Map *map, uvlong addr, uchar *buf, int n) .PP .B int put2(Map *map, uvlong addr, ushort val) .PP .B int put4(Map *map, uvlong addr, ulong val) .PP .B int put8(Map *map, uvlong addr, uvlong val) .PP .B int puta(Map *map, uvlong addr, uvlong val) .PP .B ushort beswab(ushort val) .PP .B long beswal(ulong val) .PP .B long beswav(uvlong val) .PP .B ushort leswab(ushort val) .PP .B long leswal(ulong val) .PP .B long leswav(uvlong val) .PP .B extern Mach mach; .PP .B extern Machdata machdata; .SH DESCRIPTION These functions provide a processor-independent interface for accessing the executable files or executing images of all architectures. Related library functions described in .IR symbol (2) and .IR object (2) provide similar access to symbol tables and object files. .PP An .I executable is a file containing an executable program or the .B text file of the .B /proc file system associated with an executing process as described in .IR proc (3). After opening an executable, an application invokes a library function which parses the file header, determines the target architecture and initializes data structures with parameters and pointers to functions appropriate for that architecture. Next, the application invokes functions to construct one or more .IR maps , data structures that translate references in the address space of the executable to offsets in the file. Each .I map comprises one or more .BR segments , each associating a non-overlapping range of memory addresses with a logical section of the executable. Other library functions then use a map and the architecture-specific data structures to provide a generic interface to the processor-dependent data. .PP .I Crackhdr interprets the header of the executable associated with the open file descriptor .IR fd . It loads the data structure .I fp with a machine-independent description of the header information and points global variable .I mach to the .B Mach data structure containing processor-dependent parameters of the target architecture. .PP .I Machbytype selects architecture-specific data structures and parameter values based on the code stored in the field named .I type in the .B Fhdr data structure. .I Machbyname performs the same selection based on the name of a processor class; see .IR 2c (1) for a list of valid names. Both functions point global variables .I mach and .I machdata to the .I Mach and .I Machdata data structures appropriate for the target architecture and load global variable .I asstype with the proper disassembler type code. .PP .I Newmap creates an empty map with .I n segments. If .I map is zero, the new map is dynamically allocated, otherwise it is assumed to point to an existing dynamically allocated map whose size is adjusted, as necessary. A zero return value indicates an allocation error. .PP .I Setmap loads the first unused segment in .I map with the segment mapping parameters. .I Fd is an open file descriptor associated with an executable. .I Base and .I end contain the lowest and highest virtual addresses mapped by the segment. .I Foffset is the offset to the start of the segment in the file. .I Name is a name to be attached to the segment. .PP .I Findseg returns the index of the segment named .I name in .IR map . A return of -1 indicates that no segment matches .IR name . .PP .I Unusemap marks segment number .I seg in map .I map unused. Other segments in the map remain unaffected. .PP .I Loadmap initializes a default map containing segments named `text' and `data' that map the instruction and data segments of the executable described in the .B Fhdr structure pointed to by .IR fp . Usually that structure was loaded by .IR crackhdr and can be passed to this function without modification. If .I map is non-zero, that map, which must have been dynamically allocated, is resized to contain two segments; otherwise a new map is allocated. This function returns zero if allocation fails. .I Loadmap is usually used to build a map for accessing a static executable, for example, an executable program file. .PP .I Attachproc constructs a map for accessing a running process. It returns the address of a .I Map containing segments mapping the address space of the running process whose process ID is .BR pid . If .B kflag is non-zero, the process is assumed to be a kernel process. .B Corefd is an file descriptor opened to .BR /proc/\fIpid\fP/mem . .B Fp points to the .I Fhdr structure describing the header of the executable. For most architectures the resulting .I Map contains four segments named `text', `data', `regs' and `fpregs'. The latter two provide access to the general and floating point registers, respectively. If the executable is a kernel process (indicated by a non-zero .B kflag argument), the data segment extends to the maximum supported address, currently 0xffffffff, and the register sets are read-only. In user-level programs, the data segment extends to the top of the stack or 0x7fffffff if the stack top cannot be found, and the register sets are readable and writable. .I Attachproc returns zero if it is unable to build the map for the specified process. .PP .IR Get1 , .IR get2 , .IR get4 , and .I get8 retrieve the data stored at address .I addr in the executable associated with .IR map . .I Get1 retrieves .I n bytes of data beginning at .I addr into .IR buf . .IR Get2 , .I get4 and .I get8 retrieve 16-bit, 32-bit and 64-bit values respectively, into the location pointed to by .IR val . The value is byte-swapped if the source byte order differs from that of the current architecture. This implies that the value returned by .IR get2 , .IR get4 , and .I get8 may not be the same as the byte sequences returned by .I get1 when .I n is two, four or eight; the former may be byte-swapped, the latter reflects the byte order of the target architecture. If the file descriptor associated with the applicable segment in .I map is negative, the address itself is placed in the return location. These functions return the number of bytes read or a \-1 when there is an error. .PP .IR Put1 , .IR put2 , .IR put4 , and .I put8 write to the executable associated with .IR map . The address is translated using the map parameters and multi-byte quantities are byte-swapped, if necessary, before they are written. .I Put1 transfers .I n bytes stored at .IR buf ; .IR put2 , .IR put4 , and .I put8 write the 16-bit, 32-bit or 64-bit quantity contained in .IR val , respectively. The number of bytes transferred is returned. A \-1 return value indicates an error. .PP .IR Beswab , .IR beswal , and .I beswav return the .BR ushort , .BR long , and .B vlong big-endian representation of .IR val , respectively. .IR Leswab , .IR leswal , and .I leswav return the little-endian representation of the .BR ushort , .BR long , and .B vlong contained in .IR val . .SH SOURCE .B /sys/src/libmach .SH "SEE ALSO" .IR 2c (1), .IR symbol (2), .IR object (2), .IR errstr (2), .IR proc (3), .IR a.out (6) .SH DIAGNOSTICS These routines set .IR errstr .