/* GNU/Linux on ARM native support. Copyright 1999, 2000 Free Software Foundation, Inc. This file is part of GDB. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include "defs.h" #include "inferior.h" #include "gdbcore.h" #include "gdb_string.h" #include #include #include extern int arm_apcs_32; #define typeNone 0x00 #define typeSingle 0x01 #define typeDouble 0x02 #define typeExtended 0x03 #define FPWORDS 28 #define CPSR_REGNUM 16 typedef union tagFPREG { unsigned int fSingle; unsigned int fDouble[2]; unsigned int fExtended[3]; } FPREG; typedef struct tagFPA11 { FPREG fpreg[8]; /* 8 floating point registers */ unsigned int fpsr; /* floating point status register */ unsigned int fpcr; /* floating point control register */ unsigned char fType[8]; /* type of floating point value held in floating point registers. */ int initflag; /* NWFPE initialization flag. */ } FPA11; /* The following variables are used to determine the version of the underlying Linux operating system. Examples: Linux 2.0.35 Linux 2.2.12 os_version = 0x00020023 os_version = 0x0002020c os_major = 2 os_major = 2 os_minor = 0 os_minor = 2 os_release = 35 os_release = 12 Note: os_version = (os_major << 16) | (os_minor << 8) | os_release These are initialized using get_linux_version() from _initialize_arm_linux_nat(). */ static unsigned int os_version, os_major, os_minor, os_release; static void fetch_nwfpe_single (unsigned int fn, FPA11 * fpa11) { unsigned int mem[3]; mem[0] = fpa11->fpreg[fn].fSingle; mem[1] = 0; mem[2] = 0; supply_register (F0_REGNUM + fn, (char *) &mem[0]); } static void fetch_nwfpe_double (unsigned int fn, FPA11 * fpa11) { unsigned int mem[3]; mem[0] = fpa11->fpreg[fn].fDouble[1]; mem[1] = fpa11->fpreg[fn].fDouble[0]; mem[2] = 0; supply_register (F0_REGNUM + fn, (char *) &mem[0]); } static void fetch_nwfpe_none (unsigned int fn) { unsigned int mem[3] = {0, 0, 0}; supply_register (F0_REGNUM + fn, (char *) &mem[0]); } static void fetch_nwfpe_extended (unsigned int fn, FPA11 * fpa11) { unsigned int mem[3]; mem[0] = fpa11->fpreg[fn].fExtended[0]; /* sign & exponent */ mem[1] = fpa11->fpreg[fn].fExtended[2]; /* ls bits */ mem[2] = fpa11->fpreg[fn].fExtended[1]; /* ms bits */ supply_register (F0_REGNUM + fn, (char *) &mem[0]); } static void store_nwfpe_single (unsigned int fn, FPA11 * fpa11) { unsigned int mem[3]; read_register_gen (F0_REGNUM + fn, (char *) &mem[0]); fpa11->fpreg[fn].fSingle = mem[0]; fpa11->fType[fn] = typeSingle; } static void store_nwfpe_double (unsigned int fn, FPA11 * fpa11) { unsigned int mem[3]; read_register_gen (F0_REGNUM + fn, (char *) &mem[0]); fpa11->fpreg[fn].fDouble[1] = mem[0]; fpa11->fpreg[fn].fDouble[0] = mem[1]; fpa11->fType[fn] = typeDouble; } void store_nwfpe_extended (unsigned int fn, FPA11 * fpa11) { unsigned int mem[3]; read_register_gen (F0_REGNUM + fn, (char *) &mem[0]); fpa11->fpreg[fn].fExtended[0] = mem[0]; /* sign & exponent */ fpa11->fpreg[fn].fExtended[2] = mem[1]; /* ls bits */ fpa11->fpreg[fn].fExtended[1] = mem[2]; /* ms bits */ fpa11->fType[fn] = typeDouble; } /* Get the whole floating point state of the process and store the floating point stack into registers[]. */ static void fetch_fpregs (void) { int ret, regno; FPA11 fp; /* Read the floating point state. */ ret = ptrace (PT_GETFPREGS, inferior_pid, 0, &fp); if (ret < 0) { warning ("Unable to fetch the floating point state."); return; } /* Fetch fpsr. */ supply_register (FPS_REGNUM, (char *) &fp.fpsr); /* Fetch the floating point registers. */ for (regno = F0_REGNUM; regno <= F7_REGNUM; regno++) { int fn = regno - F0_REGNUM; switch (fp.fType[fn]) { case typeSingle: fetch_nwfpe_single (fn, &fp); break; case typeDouble: fetch_nwfpe_double (fn, &fp); break; case typeExtended: fetch_nwfpe_extended (fn, &fp); break; default: fetch_nwfpe_none (fn); } } } /* Save the whole floating point state of the process using the contents from registers[]. */ static void store_fpregs (void) { int ret, regno; FPA11 fp; /* Store fpsr. */ if (register_valid[FPS_REGNUM]) read_register_gen (FPS_REGNUM, (char *) &fp.fpsr); /* Store the floating point registers. */ for (regno = F0_REGNUM; regno <= F7_REGNUM; regno++) { if (register_valid[regno]) { unsigned int fn = regno - F0_REGNUM; switch (fp.fType[fn]) { case typeSingle: store_nwfpe_single (fn, &fp); break; case typeDouble: store_nwfpe_double (fn, &fp); break; case typeExtended: store_nwfpe_extended (fn, &fp); break; } } } ret = ptrace (PTRACE_SETFPREGS, inferior_pid, 0, &fp); if (ret < 0) { warning ("Unable to store floating point state."); return; } } /* Fetch all general registers of the process and store into registers[]. */ static void fetch_regs (void) { int ret, regno; struct pt_regs regs; ret = ptrace (PTRACE_GETREGS, inferior_pid, 0, ®s); if (ret < 0) { warning ("Unable to fetch general registers."); return; } for (regno = A1_REGNUM; regno < PC_REGNUM; regno++) supply_register (regno, (char *) ®s.uregs[regno]); if (arm_apcs_32) supply_register (PS_REGNUM, (char *) ®s.uregs[CPSR_REGNUM]); else supply_register (PS_REGNUM, (char *) ®s.uregs[PC_REGNUM]); regs.uregs[PC_REGNUM] = ADDR_BITS_REMOVE (regs.uregs[PC_REGNUM]); supply_register (PC_REGNUM, (char *) ®s.uregs[PC_REGNUM]); } /* Store all general registers of the process from the values in registers[]. */ static void store_regs (void) { int ret, regno; struct pt_regs regs; ret = ptrace (PTRACE_GETREGS, inferior_pid, 0, ®s); if (ret < 0) { warning ("Unable to fetch general registers."); return; } for (regno = A1_REGNUM; regno <= PC_REGNUM; regno++) { if (register_valid[regno]) read_register_gen (regno, (char *) ®s.uregs[regno]); } ret = ptrace (PTRACE_SETREGS, inferior_pid, 0, ®s); if (ret < 0) { warning ("Unable to store general registers."); return; } } /* Fetch registers from the child process. Fetch all registers if regno == -1, otherwise fetch all general registers or all floating point registers depending upon the value of regno. */ void fetch_inferior_registers (int regno) { if ((regno < F0_REGNUM) || (regno > FPS_REGNUM)) fetch_regs (); if (((regno >= F0_REGNUM) && (regno <= FPS_REGNUM)) || (regno == -1)) fetch_fpregs (); } /* Store registers back into the inferior. Store all registers if regno == -1, otherwise store all general registers or all floating point registers depending upon the value of regno. */ void store_inferior_registers (int regno) { if ((regno < F0_REGNUM) || (regno > FPS_REGNUM)) store_regs (); if (((regno >= F0_REGNUM) && (regno <= FPS_REGNUM)) || (regno == -1)) store_fpregs (); } /* Dynamic Linking on ARM Linux ---------------------------- Note: PLT = procedure linkage table GOT = global offset table As much as possible, ELF dynamic linking defers the resolution of jump/call addresses until the last minute. The technique used is inspired by the i386 ELF design, and is based on the following constraints. 1) The calling technique should not force a change in the assembly code produced for apps; it MAY cause changes in the way assembly code is produced for position independent code (i.e. shared libraries). 2) The technique must be such that all executable areas must not be modified; and any modified areas must not be executed. To do this, there are three steps involved in a typical jump: 1) in the code 2) through the PLT 3) using a pointer from the GOT When the executable or library is first loaded, each GOT entry is initialized to point to the code which implements dynamic name resolution and code finding. This is normally a function in the program interpreter (on ARM Linux this is usually ld-linux.so.2, but it does not have to be). On the first invocation, the function is located and the GOT entry is replaced with the real function address. Subsequent calls go through steps 1, 2 and 3 and end up calling the real code. 1) In the code: b function_call bl function_call This is typical ARM code using the 26 bit relative branch or branch and link instructions. The target of the instruction (function_call is usually the address of the function to be called. In position independent code, the target of the instruction is actually an entry in the PLT when calling functions in a shared library. Note that this call is identical to a normal function call, only the target differs. 2) In the PLT: The PLT is a synthetic area, created by the linker. It exists in both executables and libraries. It is an array of stubs, one per imported function call. It looks like this: PLT[0]: str lr, [sp, #-4]! @push the return address (lr) ldr lr, [pc, #16] @load from 6 words ahead add lr, pc, lr @form an address for GOT[0] ldr pc, [lr, #8]! @jump to the contents of that addr The return address (lr) is pushed on the stack and used for calculations. The load on the second line loads the lr with &GOT[3] - . - 20. The addition on the third leaves: lr = (&GOT[3] - . - 20) + (. + 8) lr = (&GOT[3] - 12) lr = &GOT[0] On the fourth line, the pc and lr are both updated, so that: pc = GOT[2] lr = &GOT[0] + 8 = &GOT[2] NOTE: PLT[0] borrows an offset .word from PLT[1]. This is a little "tight", but allows us to keep all the PLT entries the same size. PLT[n+1]: ldr ip, [pc, #4] @load offset from gotoff add ip, pc, ip @add the offset to the pc ldr pc, [ip] @jump to that address gotoff: .word GOT[n+3] - . The load on the first line, gets an offset from the fourth word of the PLT entry. The add on the second line makes ip = &GOT[n+3], which contains either a pointer to PLT[0] (the fixup trampoline) or a pointer to the actual code. 3) In the GOT: The GOT contains helper pointers for both code (PLT) fixups and data fixups. The first 3 entries of the GOT are special. The next M entries (where M is the number of entries in the PLT) belong to the PLT fixups. The next D (all remaining) entries belong to various data fixups. The actual size of the GOT is 3 + M + D. The GOT is also a synthetic area, created by the linker. It exists in both executables and libraries. When the GOT is first initialized , all the GOT entries relating to PLT fixups are pointing to code back at PLT[0]. The special entries in the GOT are: GOT[0] = linked list pointer used by the dynamic loader GOT[1] = pointer to the reloc table for this module GOT[2] = pointer to the fixup/resolver code The first invocation of function call comes through and uses the fixup/resolver code. On the entry to the fixup/resolver code: ip = &GOT[n+3] lr = &GOT[2] stack[0] = return address (lr) of the function call [r0, r1, r2, r3] are still the arguments to the function call This is enough information for the fixup/resolver code to work with. Before the fixup/resolver code returns, it actually calls the requested function and repairs &GOT[n+3]. */ CORE_ADDR arm_skip_solib_resolver (CORE_ADDR pc) { /* FIXME */ return 0; } int arm_linux_register_u_addr (int blockend, int regnum) { return blockend + REGISTER_BYTE (regnum); } int arm_linux_kernel_u_size (void) { return (sizeof (struct user)); } static unsigned int get_linux_version (unsigned int *vmajor, unsigned int *vminor, unsigned int *vrelease) { struct utsname info; char *pmajor, *pminor, *prelease, *tail; if (-1 == uname (&info)) { warning ("Unable to determine Linux version."); return -1; } pmajor = strtok (info.release, "."); pminor = strtok (NULL, "."); prelease = strtok (NULL, "."); *vmajor = (unsigned int) strtoul (pmajor, &tail, 0); *vminor = (unsigned int) strtoul (pminor, &tail, 0); *vrelease = (unsigned int) strtoul (prelease, &tail, 0); return ((*vmajor << 16) | (*vminor << 8) | *vrelease); } void _initialize_arm_linux_nat (void) { os_version = get_linux_version (&os_major, &os_minor, &os_release); }