/*********************************************************** Copyright 1991-1995 by Stichting Mathematisch Centrum, Amsterdam, The Netherlands. All Rights Reserved Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the names of Stichting Mathematisch Centrum or CWI not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. STICHTING MATHEMATISCH CENTRUM DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL STICHTING MATHEMATISCH CENTRUM BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. ******************************************************************/ /* Execute compiled code */ #include "allobjects.h" #include "import.h" #include "sysmodule.h" #include "bltinmodule.h" #include "compile.h" #include "frameobject.h" #include "eval.h" #include "ceval.h" #include "opcode.h" #include "traceback.h" #include "graminit.h" #include "pythonrun.h" #include extern int suppress_print; /* Declared in pythonrun.c, set in pythonmain.c */ /* Turn this on if your compiler chokes on the big switch: */ /* #define CASE_TOO_BIG 1 */ /* Turn this on if you want to debug the interpreter: */ /* (This can be on even if NDEBUG is defined) */ /* #define DEBUG 1 */ #if defined(DEBUG) || !defined(NDEBUG) /* For debugging the interpreter: */ #define LLTRACE 1 /* Low-level trace feature */ #define CHECKEXC 1 /* Double-check exception checking */ #endif /* Forward declarations */ #ifdef LLTRACE static int prtrace PROTO((object *, char *)); #endif static void call_exc_trace PROTO((object **, object**, frameobject *)); static int call_trace PROTO((object **, object **, frameobject *, char *, object *)); static object *add PROTO((object *, object *)); static object *sub PROTO((object *, object *)); static object *mul PROTO((object *, object *)); static object *divide PROTO((object *, object *)); static object *mod PROTO((object *, object *)); static object *neg PROTO((object *)); static object *pos PROTO((object *)); static object *not PROTO((object *)); static object *invert PROTO((object *)); static object *lshift PROTO((object *, object *)); static object *rshift PROTO((object *, object *)); static object *and PROTO((object *, object *)); static object *xor PROTO((object *, object *)); static object *or PROTO((object *, object *)); static object *call_builtin PROTO((object *, object *)); static object *call_function PROTO((object *, object *)); static object *apply_subscript PROTO((object *, object *)); static object *loop_subscript PROTO((object *, object *)); static int slice_index PROTO((object *, int, int *)); static object *apply_slice PROTO((object *, object *, object *)); static int assign_subscript PROTO((object *, object *, object *)); static int assign_slice PROTO((object *, object *, object *, object *)); static int cmp_exception PROTO((object *, object *)); static int cmp_member PROTO((object *, object *)); static object *cmp_outcome PROTO((int, object *, object *)); static int import_from PROTO((object *, object *, object *)); static object *build_class PROTO((object *, object *, object *)); static int access_statement PROTO((object *, object *, frameobject *)); static int exec_statement PROTO((object *, object *, object *)); /* Pointer to current frame, used to link new frames to */ static frameobject *current_frame; #ifdef WITH_THREAD #include #include "thread.h" static type_lock interpreter_lock = 0; static long main_thread = 0; void init_save_thread() { if (interpreter_lock) return; interpreter_lock = allocate_lock(); acquire_lock(interpreter_lock, 1); main_thread = get_thread_ident(); } #endif /* Functions save_thread and restore_thread are always defined so dynamically loaded modules needn't be compiled separately for use with and without threads: */ object * save_thread() { #ifdef WITH_THREAD if (interpreter_lock) { object *res; res = (object *)current_frame; current_frame = NULL; release_lock(interpreter_lock); return res; } #endif return NULL; } void restore_thread(x) object *x; { #ifdef WITH_THREAD if (interpreter_lock) { int err; err = errno; acquire_lock(interpreter_lock, 1); errno = err; current_frame = (frameobject *)x; } #endif } /* Mechanism whereby asynchronously executing callbacks (e.g. UNIX signal handlers or Mac I/O completion routines) can schedule calls to a function to be called synchronously. The synchronous function is called with one void* argument. It should return 0 for success or -1 for failure -- failure should be accompanied by an exception. If registry succeeds, the registry function returns 0; if it fails (e.g. due to too many pending calls) it returns -1 (without setting an exception condition). Note that because registry may occur from within signal handlers, or other asynchronous events, calling malloc() is unsafe! #ifdef WITH_THREAD Any thread can schedule pending calls, but only the main thread will execute them. #endif XXX WARNING! ASYNCHRONOUSLY EXECUTING CODE! There are two possible race conditions: (1) nested asynchronous registry calls; (2) registry calls made while pending calls are being processed. While (1) is very unlikely, (2) is a real possibility. The current code is safe against (2), but not against (1). The safety against (2) is derived from the fact that only one thread (the main thread) ever takes things out of the queue. */ #define NPENDINGCALLS 32 static struct { int (*func) PROTO((ANY *)); ANY *arg; } pendingcalls[NPENDINGCALLS]; static volatile int pendingfirst = 0; static volatile int pendinglast = 0; int Py_AddPendingCall(func, arg) int (*func) PROTO((ANY *)); ANY *arg; { static int busy = 0; int i, j; /* XXX Begin critical section */ /* XXX If you want this to be safe against nested XXX asynchronous calls, you'll have to work harder! */ if (busy) return -1; busy = 1; i = pendinglast; j = (i + 1) % NPENDINGCALLS; if (j == pendingfirst) return -1; /* Queue full */ pendingcalls[i].func = func; pendingcalls[i].arg = arg; pendinglast = j; busy = 0; /* XXX End critical section */ return 0; } int Py_MakePendingCalls() { static int busy = 0; #ifdef WITH_THREAD if (get_thread_ident() != main_thread) return 0; #endif if (busy) return 0; busy = 1; for (;;) { int i; int (*func) PROTO((ANY *)); ANY *arg; i = pendingfirst; if (i == pendinglast) break; /* Queue empty */ func = pendingcalls[i].func; arg = pendingcalls[i].arg; pendingfirst = (i + 1) % NPENDINGCALLS; if (func(arg) < 0) { busy = 0; return -1; } } busy = 0; return 0; } /* Status code for main loop (reason for stack unwind) */ enum why_code { WHY_NOT, /* No error */ WHY_EXCEPTION, /* Exception occurred */ WHY_RERAISE, /* Exception re-raised by 'finally' */ WHY_RETURN, /* 'return' statement */ WHY_BREAK /* 'break' statement */ }; /* Interpreter main loop */ object * eval_code(co, globals, locals, owner, arg) codeobject *co; object *globals; object *locals; object *owner; object *arg; { register unsigned char *next_instr; register int opcode; /* Current opcode */ register int oparg; /* Current opcode argument, if any */ register object **stack_pointer; register enum why_code why; /* Reason for block stack unwind */ register int err; /* Error status -- nonzero if error */ register object *x; /* Result object -- NULL if error */ register object *v; /* Temporary objects popped off stack */ register object *w; register object *u; register object *t; register frameobject *f; /* Current frame */ register listobject *fastlocals = NULL; object *retval; /* Return value iff why == WHY_RETURN */ char *name; /* Name used by some instructions */ int needmerge = 0; /* Set if need to merge locals back at end */ int defmode = 0; /* Default access mode for new variables */ #ifdef LLTRACE int lltrace; #endif #ifdef DEBUG /* Make it easier to find out where we are with dbx */ char *filename = getstringvalue(co->co_filename); #endif /* Code access macros */ #define GETCONST(i) Getconst(f, i) #define GETNAME(i) Getname(f, i) #define GETNAMEV(i) Getnamev(f, i) #define FIRST_INSTR() (GETUSTRINGVALUE(f->f_code->co_code)) #define INSTR_OFFSET() (next_instr - FIRST_INSTR()) #define NEXTOP() (*next_instr++) #define NEXTARG() (next_instr += 2, (next_instr[-1]<<8) + next_instr[-2]) #define JUMPTO(x) (next_instr = FIRST_INSTR() + (x)) #define JUMPBY(x) (next_instr += (x)) /* Stack manipulation macros */ #define STACK_LEVEL() (stack_pointer - f->f_valuestack) #define EMPTY() (STACK_LEVEL() == 0) #define TOP() (stack_pointer[-1]) #define BASIC_PUSH(v) (*stack_pointer++ = (v)) #define BASIC_POP() (*--stack_pointer) #define CHECK_STACK(n) (STACK_LEVEL() + (n) < f->f_nvalues || \ (stack_pointer = extend_stack(f, STACK_LEVEL(), n))) #ifdef LLTRACE #define PUSH(v) (BASIC_PUSH(v), lltrace && prtrace(TOP(), "push")) #define POP() (lltrace && prtrace(TOP(), "pop"), BASIC_POP()) #else #define PUSH(v) BASIC_PUSH(v) #define POP() BASIC_POP() #endif if (globals == NULL || locals == NULL) { err_setstr(SystemError, "eval_code: NULL globals or locals"); return NULL; } #ifdef LLTRACE lltrace = dictlookup(globals, "__lltrace__") != NULL; #endif f = newframeobject( current_frame, /*back*/ co, /*code*/ globals, /*globals*/ locals, /*locals*/ owner, /*owner*/ 50, /*nvalues*/ 20); /*nblocks*/ if (f == NULL) return NULL; current_frame = f; if (sys_trace != NULL) { /* sys_trace, if defined, is a function that will be called on *every* entry to a code block. Its return value, if not None, is a function that will be called at the start of each executed line of code. (Actually, the function must return itself in order to continue tracing.) The trace functions are called with three arguments: a pointer to the current frame, a string indicating why the function is called, and an argument which depends on the situation. The global trace function (sys.trace) is also called whenever an exception is detected. */ if (call_trace(&sys_trace, &f->f_trace, f, "call", arg)) { /* Trace function raised an error */ current_frame = f->f_back; DECREF(f); return NULL; } } if (sys_profile != NULL) { /* Similar for sys_profile, except it needn't return itself and isn't called for "line" events */ if (call_trace(&sys_profile, (object**)0, f, "call", arg)) { current_frame = f->f_back; DECREF(f); return NULL; } } next_instr = GETUSTRINGVALUE(f->f_code->co_code); stack_pointer = f->f_valuestack; if (arg != NULL) { INCREF(arg); PUSH(arg); } why = WHY_NOT; err = 0; x = None; /* Not a reference, just anything non-NULL */ for (;;) { static int ticker; /* Do periodic things. Doing this every time through the loop would add too much overhead (a function call per instruction). So we do it only every Nth instruction. */ if (pendingfirst != pendinglast) { if (Py_MakePendingCalls() < 0) { why = WHY_EXCEPTION; goto on_error; } } if (--ticker < 0) { ticker = sys_checkinterval; if (sigcheck()) { why = WHY_EXCEPTION; goto on_error; } #ifdef WITH_THREAD if (interpreter_lock) { /* Give another thread a chance */ current_frame = NULL; release_lock(interpreter_lock); /* Other threads may run now */ acquire_lock(interpreter_lock, 1); current_frame = f; } #endif } /* Extract opcode and argument */ #ifdef DEBUG f->f_lasti = INSTR_OFFSET(); #endif opcode = NEXTOP(); if (HAS_ARG(opcode)) oparg = NEXTARG(); #ifdef LLTRACE /* Instruction tracing */ if (lltrace) { if (HAS_ARG(opcode)) { printf("%d: %d, %d\n", (int) (INSTR_OFFSET() - 3), opcode, oparg); } else { printf("%d: %d\n", (int) (INSTR_OFFSET() - 1), opcode); } } #endif if (!CHECK_STACK(3)) { x = NULL; break; } /* Main switch on opcode */ switch (opcode) { /* BEWARE! It is essential that any operation that fails sets either x to NULL, err to nonzero, or why to anything but WHY_NOT, and that no operation that succeeds does this! */ /* case STOP_CODE: this is an error! */ case POP_TOP: v = POP(); DECREF(v); break; case ROT_TWO: v = POP(); w = POP(); PUSH(v); PUSH(w); break; case ROT_THREE: v = POP(); w = POP(); x = POP(); PUSH(v); PUSH(x); PUSH(w); break; case DUP_TOP: v = TOP(); INCREF(v); PUSH(v); break; case UNARY_POSITIVE: v = POP(); x = pos(v); DECREF(v); PUSH(x); break; case UNARY_NEGATIVE: v = POP(); x = neg(v); DECREF(v); PUSH(x); break; case UNARY_NOT: v = POP(); x = not(v); DECREF(v); PUSH(x); break; case UNARY_CONVERT: v = POP(); x = reprobject(v); DECREF(v); PUSH(x); break; case UNARY_CALL: v = POP(); f->f_lasti = INSTR_OFFSET() - 1; /* For tracing */ x = call_object(v, (object *)NULL); DECREF(v); PUSH(x); break; case UNARY_INVERT: v = POP(); x = invert(v); DECREF(v); PUSH(x); break; case BINARY_MULTIPLY: w = POP(); v = POP(); x = mul(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_DIVIDE: w = POP(); v = POP(); x = divide(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_MODULO: w = POP(); v = POP(); x = mod(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_ADD: w = POP(); v = POP(); x = add(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_SUBTRACT: w = POP(); v = POP(); x = sub(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_SUBSCR: w = POP(); v = POP(); x = apply_subscript(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_CALL: w = POP(); v = POP(); f->f_lasti = INSTR_OFFSET() - 1; /* For tracing */ x = call_object(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_LSHIFT: w = POP(); v = POP(); x = lshift(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_RSHIFT: w = POP(); v = POP(); x = rshift(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_AND: w = POP(); v = POP(); x = and(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_XOR: w = POP(); v = POP(); x = xor(v, w); DECREF(v); DECREF(w); PUSH(x); break; case BINARY_OR: w = POP(); v = POP(); x = or(v, w); DECREF(v); DECREF(w); PUSH(x); break; case SLICE+0: case SLICE+1: case SLICE+2: case SLICE+3: if ((opcode-SLICE) & 2) w = POP(); else w = NULL; if ((opcode-SLICE) & 1) v = POP(); else v = NULL; u = POP(); x = apply_slice(u, v, w); DECREF(u); XDECREF(v); XDECREF(w); PUSH(x); break; case STORE_SLICE+0: case STORE_SLICE+1: case STORE_SLICE+2: case STORE_SLICE+3: if ((opcode-STORE_SLICE) & 2) w = POP(); else w = NULL; if ((opcode-STORE_SLICE) & 1) v = POP(); else v = NULL; u = POP(); t = POP(); err = assign_slice(u, v, w, t); /* u[v:w] = t */ DECREF(t); DECREF(u); XDECREF(v); XDECREF(w); break; case DELETE_SLICE+0: case DELETE_SLICE+1: case DELETE_SLICE+2: case DELETE_SLICE+3: if ((opcode-DELETE_SLICE) & 2) w = POP(); else w = NULL; if ((opcode-DELETE_SLICE) & 1) v = POP(); else v = NULL; u = POP(); err = assign_slice(u, v, w, (object *)NULL); /* del u[v:w] */ DECREF(u); XDECREF(v); XDECREF(w); break; case STORE_SUBSCR: w = POP(); v = POP(); u = POP(); /* v[w] = u */ err = assign_subscript(v, w, u); DECREF(u); DECREF(v); DECREF(w); break; case DELETE_SUBSCR: w = POP(); v = POP(); /* del v[w] */ err = assign_subscript(v, w, (object *)NULL); DECREF(v); DECREF(w); break; case PRINT_EXPR: v = POP(); /* Print value except if procedure result */ /* Before printing, also assign to '_' */ if (v != None && (err = dictinsert(f->f_builtins, "_", v)) == 0 && !suppress_print) { flushline(); x = sysget("stdout"); err = writeobject(v, x, 0); softspace(x, 1); flushline(); } DECREF(v); break; case PRINT_ITEM: v = POP(); w = sysget("stdout"); if (softspace(w, 1)) writestring(" ", w); err = writeobject(v, w, PRINT_RAW); if (err == 0 && is_stringobject(v)) { /* XXX move into writeobject() ? */ char *s = getstringvalue(v); int len = getstringsize(v); if (len > 0 && isspace(s[len-1]) && s[len-1] != ' ') softspace(w, 0); } DECREF(v); break; case PRINT_NEWLINE: x = sysget("stdout"); if (x == NULL) err_setstr(RuntimeError, "lost sys.stdout"); else { writestring("\n", x); softspace(x, 0); } break; case BREAK_LOOP: why = WHY_BREAK; break; case RAISE_EXCEPTION: v = POP(); w = POP(); /* A tuple is equivalent to its first element here */ while (is_tupleobject(w) && gettuplesize(w) > 0) { u = w; w = gettupleitem(u, 0); INCREF(w); INCREF(w); DECREF(u); } if (is_stringobject(w)) { err_setval(w, v); } else if (is_classobject(w)) { if (!is_instanceobject(v) || !issubclass((object*)((instanceobject*)v)->in_class, w)) err_setstr(TypeError, "a class exception must have a value that is an instance of the class"); else err_setval(w,v); } else if (is_instanceobject(w)) { if (v != None) err_setstr(TypeError, "an instance exception may not have a separate value"); else { DECREF(v); v = w; w = (object*) ((instanceobject*)w)->in_class; INCREF(w); err_setval(w, v); } } else err_setstr(TypeError, "exceptions must be strings, classes, or instances"); DECREF(v); DECREF(w); why = WHY_EXCEPTION; break; case LOAD_LOCALS: v = f->f_locals; INCREF(v); PUSH(v); break; case RETURN_VALUE: retval = POP(); why = WHY_RETURN; break; case LOAD_GLOBALS: v = f->f_locals; INCREF(v); PUSH(v); break; case EXEC_STMT: w = POP(); v = POP(); u = POP(); err = exec_statement(u, v, w); DECREF(u); DECREF(v); DECREF(w); break; case BUILD_FUNCTION: v = POP(); x = newfuncobject(v, f->f_globals); DECREF(v); PUSH(x); break; case SET_FUNC_ARGS: v = POP(); /* The function */ w = POP(); /* The argument list */ err = setfuncargstuff(v, oparg, w); PUSH(v); DECREF(w); break; case POP_BLOCK: { block *b = pop_block(f); while (STACK_LEVEL() > b->b_level) { v = POP(); DECREF(v); } } break; case END_FINALLY: v = POP(); if (is_intobject(v)) { why = (enum why_code) getintvalue(v); if (why == WHY_RETURN) retval = POP(); } else if (is_stringobject(v)) { w = POP(); err_setval(v, w); DECREF(w); w = POP(); tb_store(w); DECREF(w); why = WHY_RERAISE; } else if (v != None) { err_setstr(SystemError, "'finally' pops bad exception"); why = WHY_EXCEPTION; } DECREF(v); break; case BUILD_CLASS: u = POP(); v = POP(); w = POP(); x = build_class(u, v, w); PUSH(x); DECREF(u); DECREF(v); DECREF(w); break; case STORE_NAME: w = GETNAMEV(oparg); v = POP(); u = dict2lookup(f->f_locals, w); if (u == NULL) { if (defmode != 0) { if (v != None) u = (object *)v->ob_type; else u = NULL; x = newaccessobject(v, f->f_locals, (typeobject *)u, defmode); DECREF(v); if (x == NULL) break; v = x; } } else if (is_accessobject(u)) { err = setaccessvalue(u, f->f_locals, v); DECREF(v); break; } err = dict2insert(f->f_locals, w, v); DECREF(v); break; case DELETE_NAME: w = GETNAMEV(oparg); u = dict2lookup(f->f_locals, w); if (u != NULL && is_accessobject(u)) { err = setaccessvalue(u, f->f_locals, (object *)NULL); break; } if ((err = dict2remove(f->f_locals, w)) != 0) err_setval(NameError, w); break; #ifdef CASE_TOO_BIG default: switch (opcode) { #endif case UNPACK_VARARG: if (EMPTY()) { err_setstr(TypeError, "no argument list"); why = WHY_EXCEPTION; break; } v = POP(); if (!is_tupleobject(v)) { err_setstr(TypeError, "bad argument list"); why = WHY_EXCEPTION; } else if (gettuplesize(v) < oparg) { err_setstr(TypeError, "not enough arguments"); why = WHY_EXCEPTION; } else if (oparg == 0) { PUSH(v); break; } else { x = gettupleslice(v, oparg, gettuplesize(v)); if (x != NULL) { PUSH(x); if (!CHECK_STACK(oparg)) { x = NULL; break; } for (; --oparg >= 0; ) { w = gettupleitem(v, oparg); INCREF(w); PUSH(w); } } } DECREF(v); break; case UNPACK_ARG: { int n; if (EMPTY()) { err_setstr(TypeError, "no argument list"); why = WHY_EXCEPTION; break; } v = POP(); if (!is_tupleobject(v)) { err_setstr(TypeError, "bad argument list"); why = WHY_EXCEPTION; break; } n = gettuplesize(v); #ifdef COMPAT_HACKS /* Implement various compatibility hacks (for 0.9.4 or earlier): (a) f(a,b,...) accepts f((1,2,...)) (b) f((a,b,...)) accepts f(1,2,...) (c) f(self,(a,b,...)) accepts f(x,1,2,...) */ if (n == 1 && oparg != 1) { /* Rule (a) */ w = gettupleitem(v, 0); if (is_tupleobject(w)) { INCREF(w); DECREF(v); v = w; n = gettuplesize(v); } } else if (n != 1 && oparg == 1) { /* Rule (b) */ PUSH(v); break; /* Don't fall through */ } else if (n > 2 && oparg == 2) { /* Rule (c) */ int i; w = newtupleobject(n-1); u = newtupleobject(2); if (u == NULL || w == NULL) { XDECREF(w); XDECREF(u); DECREF(v); why = WHY_EXCEPTION; break; } t = gettupleitem(v, 0); INCREF(t); settupleitem(u, 0, t); for (i = 1; i < n; i++) { t = gettupleitem(v, i); INCREF(t); settupleitem(w, i-1, t); } settupleitem(u, 1, w); DECREF(v); v = u; n = 2; } #endif /* Disabled compatibility hacks */ if (n != oparg) { err_setstr(TypeError, "arg count mismatch"); why = WHY_EXCEPTION; DECREF(v); break; } PUSH(v); } /* Fall through */ case UNPACK_TUPLE: v = POP(); if (!is_tupleobject(v)) { err_setstr(TypeError, "unpack non-tuple"); why = WHY_EXCEPTION; } else if (gettuplesize(v) != oparg) { err_setstr(ValueError, "unpack tuple of wrong size"); why = WHY_EXCEPTION; } else { if (!CHECK_STACK(oparg)) { x = NULL; break; } for (; --oparg >= 0; ) { w = gettupleitem(v, oparg); INCREF(w); PUSH(w); } } DECREF(v); break; case UNPACK_LIST: v = POP(); if (!is_listobject(v)) { err_setstr(TypeError, "unpack non-list"); why = WHY_EXCEPTION; } else if (getlistsize(v) != oparg) { err_setstr(ValueError, "unpack list of wrong size"); why = WHY_EXCEPTION; } else { if (!CHECK_STACK(oparg)) { x = NULL; break; } for (; --oparg >= 0; ) { w = getlistitem(v, oparg); INCREF(w); PUSH(w); } } DECREF(v); break; case STORE_ATTR: w = GETNAMEV(oparg); v = POP(); u = POP(); err = setattro(v, w, u); /* v.w = u */ DECREF(v); DECREF(u); break; case DELETE_ATTR: w = GETNAMEV(oparg); v = POP(); err = setattro(v, w, (object *)NULL); /* del v.w */ DECREF(v); break; case STORE_GLOBAL: w = GETNAMEV(oparg); v = POP(); u = dict2lookup(f->f_locals, w); if (u != NULL && is_accessobject(u)) { err = setaccessvalue(u, f->f_globals, v); DECREF(v); break; } err = dict2insert(f->f_globals, w, v); DECREF(v); break; case DELETE_GLOBAL: w = GETNAMEV(oparg); u = dict2lookup(f->f_locals, w); if (u != NULL && is_accessobject(u)) { err = setaccessvalue(u, f->f_globals, (object *)NULL); break; } if ((err = dict2remove(f->f_globals, w)) != 0) err_setval(NameError, w); break; case LOAD_CONST: x = GETCONST(oparg); INCREF(x); PUSH(x); break; case LOAD_NAME: w = GETNAMEV(oparg); x = dict2lookup(f->f_locals, w); if (x == NULL) { err_clear(); x = dict2lookup(f->f_globals, w); if (x == NULL) { err_clear(); x = dict2lookup(f->f_builtins, w); if (x == NULL) { err_setval(NameError, w); break; } } } if (is_accessobject(x)) { x = getaccessvalue(x, f->f_globals /* XXX */); if (x == NULL) break; } else INCREF(x); PUSH(x); break; case LOAD_GLOBAL: w = GETNAMEV(oparg); x = dict2lookup(f->f_globals, w); if (x == NULL) { err_clear(); x = dict2lookup(f->f_builtins, w); if (x == NULL) { err_setval(NameError, w); break; } } if (is_accessobject(x)) { x = getaccessvalue(x, f->f_globals); if (x == NULL) break; } else INCREF(x); PUSH(x); break; case LOAD_LOCAL: w = GETNAMEV(oparg); x = dict2lookup(f->f_locals, w); if (x == NULL) { err_setval(NameError, w); break; } if (is_accessobject(x)) { x = getaccessvalue(x, f->f_locals); if (x == NULL) break; } else INCREF(x); PUSH(x); break; case RESERVE_FAST: x = GETCONST(oparg); if (x == None) break; if (x == NULL || !is_tupleobject(x)) { err_setstr(SystemError, "bad RESERVE_FAST"); x = NULL; break; } XDECREF(f->f_fastlocals); XDECREF(f->f_localmap); INCREF(x); f->f_localmap = x; f->f_fastlocals = x = newlistobject(gettuplesize(x)); fastlocals = (listobject *) x; break; case LOAD_FAST: x = GETLISTITEM(fastlocals, oparg); if (x == NULL) { err_setval(NameError, gettupleitem(f->f_localmap, oparg)); break; } if (is_accessobject(x)) { x = getaccessvalue(x, f->f_locals); if (x == NULL) break; } else INCREF(x); PUSH(x); break; case STORE_FAST: v = POP(); w = GETLISTITEM(fastlocals, oparg); if (w != NULL && is_accessobject(w)) { err = setaccessvalue(w, f->f_locals, v); DECREF(v); break; } GETLISTITEM(fastlocals, oparg) = v; XDECREF(w); break; case DELETE_FAST: x = GETLISTITEM(fastlocals, oparg); if (x == NULL) { err_setval(NameError, gettupleitem(f->f_localmap, oparg)); break; } if (x != NULL && is_accessobject(x)) { err = setaccessvalue(x, f->f_locals, (object *)NULL); break; } GETLISTITEM(fastlocals, oparg) = NULL; DECREF(x); break; case BUILD_TUPLE: x = newtupleobject(oparg); if (x != NULL) { for (; --oparg >= 0;) { w = POP(); err = settupleitem(x, oparg, w); if (err != 0) break; } PUSH(x); } break; case BUILD_LIST: x = newlistobject(oparg); if (x != NULL) { for (; --oparg >= 0;) { w = POP(); err = setlistitem(x, oparg, w); if (err != 0) break; } PUSH(x); } break; case BUILD_MAP: x = newdictobject(); PUSH(x); break; case LOAD_ATTR: w = GETNAMEV(oparg); v = POP(); x = getattro(v, w); DECREF(v); PUSH(x); break; case COMPARE_OP: w = POP(); v = POP(); x = cmp_outcome(oparg, v, w); DECREF(v); DECREF(w); PUSH(x); break; case IMPORT_NAME: w = GETNAMEV(oparg); x = dictlookup(f->f_builtins, "__import__"); if (x == NULL) { err_setstr(ImportError, "__import__ not found"); break; } w = mkvalue("(O)", w); if (w == NULL) { x = NULL; break; } x = call_object(x, w); DECREF(w); if (x) PUSH(x); break; case IMPORT_FROM: w = GETNAMEV(oparg); v = TOP(); err = import_from(f->f_locals, v, w); locals_2_fast(f, 0); break; case ACCESS_MODE: v = POP(); w = GETNAMEV(oparg); if (getstringvalue(w)[0] == '*') defmode = getintvalue(v); else err = access_statement(w, v, f); DECREF(v); break; case JUMP_FORWARD: JUMPBY(oparg); break; case JUMP_IF_FALSE: err = testbool(TOP()); if (err > 0) err = 0; else if (err == 0) JUMPBY(oparg); break; case JUMP_IF_TRUE: err = testbool(TOP()); if (err > 0) { err = 0; JUMPBY(oparg); } break; case JUMP_ABSOLUTE: JUMPTO(oparg); break; case FOR_LOOP: /* for v in s: ... On entry: stack contains s, i. On exit: stack contains s, i+1, s[i]; but if loop exhausted: s, i are popped, and we jump */ w = POP(); /* Loop index */ v = POP(); /* Sequence object */ u = loop_subscript(v, w); if (u != NULL) { PUSH(v); x = newintobject(getintvalue(w)+1); PUSH(x); DECREF(w); PUSH(u); } else { DECREF(v); DECREF(w); /* A NULL can mean "s exhausted" but also an error: */ if (err_occurred()) why = WHY_EXCEPTION; else JUMPBY(oparg); } break; case SETUP_LOOP: case SETUP_EXCEPT: case SETUP_FINALLY: setup_block(f, opcode, INSTR_OFFSET() + oparg, STACK_LEVEL()); break; case SET_LINENO: #ifdef LLTRACE if (lltrace) printf("--- %s:%d \n", filename, oparg); #endif f->f_lineno = oparg; if (f->f_trace != NULL) { /* Trace each line of code reached */ f->f_lasti = INSTR_OFFSET(); err = call_trace(&f->f_trace, &f->f_trace, f, "line", None); } break; default: fprintf(stderr, "XXX lineno: %d, opcode: %d\n", f->f_lineno, opcode); err_setstr(SystemError, "eval_code: unknown opcode"); why = WHY_EXCEPTION; break; #ifdef CASE_TOO_BIG } #endif } /* switch */ on_error: /* Quickly continue if no error occurred */ if (why == WHY_NOT) { if (err == 0 && x != NULL) continue; /* Normal, fast path */ why = WHY_EXCEPTION; x = None; err = 0; } #ifdef CHECKEXC /* Double-check exception status */ if (why == WHY_EXCEPTION || why == WHY_RERAISE) { if (!err_occurred()) { fprintf(stderr, "XXX ghost error\n"); err_setstr(SystemError, "ghost error"); why = WHY_EXCEPTION; } } else { if (err_occurred()) fatal("XXX undetected error"); } #endif /* Log traceback info if this is a real exception */ if (why == WHY_EXCEPTION) { f->f_lasti = INSTR_OFFSET() - 1; if (HAS_ARG(opcode)) f->f_lasti -= 2; tb_here(f); if (f->f_trace) call_exc_trace(&f->f_trace, &f->f_trace, f); if (sys_profile) call_exc_trace(&sys_profile, (object**)0, f); } /* For the rest, treat WHY_RERAISE as WHY_EXCEPTION */ if (why == WHY_RERAISE) why = WHY_EXCEPTION; /* Unwind stacks if a (pseudo) exception occurred */ while (why != WHY_NOT && f->f_iblock > 0) { block *b = pop_block(f); while (STACK_LEVEL() > b->b_level) { v = POP(); XDECREF(v); } if (b->b_type == SETUP_LOOP && why == WHY_BREAK) { why = WHY_NOT; JUMPTO(b->b_handler); break; } if (b->b_type == SETUP_FINALLY || b->b_type == SETUP_EXCEPT && why == WHY_EXCEPTION) { if (why == WHY_EXCEPTION) { object *exc, *val, *tb; err_fetch(&exc, &val, &tb); if (val == NULL) { val = None; INCREF(val); } /* Make the raw exception data available to the handler, so a program can emulate the Python main loop. Don't do this for 'finally'. */ if (b->b_type == SETUP_EXCEPT) { sysset("exc_traceback", tb); sysset("exc_value", val); sysset("exc_type", exc); } PUSH(tb); PUSH(val); PUSH(exc); } else { if (why == WHY_RETURN) PUSH(retval); v = newintobject((long)why); PUSH(v); } why = WHY_NOT; JUMPTO(b->b_handler); break; } } /* unwind stack */ /* End the loop if we still have an error (or return) */ if (why != WHY_NOT) break; } /* main loop */ /* Pop remaining stack entries */ while (!EMPTY()) { v = POP(); XDECREF(v); } if (why != WHY_RETURN) retval = NULL; if (f->f_trace) { if (why == WHY_RETURN) { if (call_trace(&f->f_trace, &f->f_trace, f, "return", retval)) { XDECREF(retval); retval = NULL; why = WHY_EXCEPTION; } } } if (sys_profile && why == WHY_RETURN) { if (call_trace(&sys_profile, (object**)0, f, "return", retval)) { XDECREF(retval); retval = NULL; why = WHY_EXCEPTION; } } /* Restore previous frame and release the current one */ current_frame = f->f_back; DECREF(f); if (needmerge) locals_2_fast(current_frame, 1); return retval; } #ifdef LLTRACE static int prtrace(v, str) object *v; char *str; { printf("%s ", str); if (printobject(v, stdout, 0) != 0) err_clear(); /* Don't know what else to do */ printf("\n"); } #endif static void call_exc_trace(p_trace, p_newtrace, f) object **p_trace, **p_newtrace; frameobject *f; { object *type, *value, *traceback, *arg; int err; err_fetch(&type, &value, &traceback); if (value == NULL) { value = None; INCREF(value); } arg = mkvalue("(OOO)", type, value, traceback); if (arg == NULL) { err_restore(type, value, traceback); return; } err = call_trace(p_trace, p_newtrace, f, "exception", arg); DECREF(arg); if (err == 0) err_restore(type, value, traceback); else { XDECREF(type); XDECREF(value); XDECREF(traceback); } } static int call_trace(p_trace, p_newtrace, f, msg, arg) object **p_trace; /* in/out; may not be NULL; may not point to NULL variable initially */ object **p_newtrace; /* in/out; may be NULL; may point to NULL variable; may be same variable as p_newtrace */ frameobject *f; char *msg; object *arg; { object *arglist, *what; object *res = NULL; static int tracing = 0; if (tracing) { /* Don't do recursive traces */ if (p_newtrace) { XDECREF(*p_newtrace); *p_newtrace = NULL; } return 0; } arglist = newtupleobject(3); if (arglist == NULL) goto cleanup; what = newstringobject(msg); if (what == NULL) goto cleanup; INCREF(f); settupleitem(arglist, 0, (object *)f); settupleitem(arglist, 1, what); if (arg == NULL) arg = None; INCREF(arg); settupleitem(arglist, 2, arg); tracing++; fast_2_locals(f); res = call_object(*p_trace, arglist); /* May clear *p_trace! */ locals_2_fast(f, 1); tracing--; cleanup: XDECREF(arglist); if (res == NULL) { /* The trace proc raised an exception */ tb_here(f); XDECREF(*p_trace); *p_trace = NULL; if (p_newtrace) { XDECREF(*p_newtrace); *p_newtrace = NULL; } return -1; } else { if (p_newtrace) { XDECREF(*p_newtrace); if (res == None) *p_newtrace = NULL; else { INCREF(res); *p_newtrace = res; } } DECREF(res); return 0; } } object * getbuiltins() { if (current_frame == NULL) return getbuiltinmod(); else return current_frame->f_builtins; } object * getlocals() { if (current_frame == NULL) return NULL; fast_2_locals(current_frame); return current_frame->f_locals; } object * getglobals() { if (current_frame == NULL) return NULL; else return current_frame->f_globals; } object * getowner() { if (current_frame == NULL) return NULL; else return current_frame->f_owner; } object * getframe() { return (object *)current_frame; } int getrestricted() { return current_frame == NULL ? 0 : current_frame->f_restricted; } void flushline() { object *f = sysget("stdout"); if (softspace(f, 0)) writestring("\n", f); } #define BINOP(opname, ropname, thisfunc) \ if (!is_instanceobject(v) && !is_instanceobject(w)) \ ; \ else \ return instancebinop(v, w, opname, ropname, thisfunc) static object * or(v, w) object *v, *w; { BINOP("__or__", "__ror__", or); if (v->ob_type->tp_as_number != NULL) { object *x; object * (*f) FPROTO((object *, object *)); if (coerce(&v, &w) != 0) return NULL; if ((f = v->ob_type->tp_as_number->nb_or) != NULL) x = (*f)(v, w); DECREF(v); DECREF(w); if (f != NULL) return x; } err_setstr(TypeError, "bad operand type(s) for |"); return NULL; } static object * xor(v, w) object *v, *w; { BINOP("__xor__", "__rxor__", xor); if (v->ob_type->tp_as_number != NULL) { object *x; object * (*f) FPROTO((object *, object *)); if (coerce(&v, &w) != 0) return NULL; if ((f = v->ob_type->tp_as_number->nb_xor) != NULL) x = (*f)(v, w); DECREF(v); DECREF(w); if (f != NULL) return x; } err_setstr(TypeError, "bad operand type(s) for ^"); return NULL; } static object * and(v, w) object *v, *w; { BINOP("__and__", "__rand__", and); if (v->ob_type->tp_as_number != NULL) { object *x; object * (*f) FPROTO((object *, object *)); if (coerce(&v, &w) != 0) return NULL; if ((f = v->ob_type->tp_as_number->nb_and) != NULL) x = (*f)(v, w); DECREF(v); DECREF(w); if (f != NULL) return x; } err_setstr(TypeError, "bad operand type(s) for &"); return NULL; } static object * lshift(v, w) object *v, *w; { BINOP("__lshift__", "__rlshift__", lshift); if (v->ob_type->tp_as_number != NULL) { object *x; object * (*f) FPROTO((object *, object *)); if (coerce(&v, &w) != 0) return NULL; if ((f = v->ob_type->tp_as_number->nb_lshift) != NULL) x = (*f)(v, w); DECREF(v); DECREF(w); if (f != NULL) return x; } err_setstr(TypeError, "bad operand type(s) for <<"); return NULL; } static object * rshift(v, w) object *v, *w; { BINOP("__rshift__", "__rrshift__", rshift); if (v->ob_type->tp_as_number != NULL) { object *x; object * (*f) FPROTO((object *, object *)); if (coerce(&v, &w) != 0) return NULL; if ((f = v->ob_type->tp_as_number->nb_rshift) != NULL) x = (*f)(v, w); DECREF(v); DECREF(w); if (f != NULL) return x; } err_setstr(TypeError, "bad operand type(s) for >>"); return NULL; } static object * add(v, w) object *v, *w; { BINOP("__add__", "__radd__", add); if (v->ob_type->tp_as_sequence != NULL) return (*v->ob_type->tp_as_sequence->sq_concat)(v, w); else if (v->ob_type->tp_as_number != NULL) { object *x; if (coerce(&v, &w) != 0) return NULL; x = (*v->ob_type->tp_as_number->nb_add)(v, w); DECREF(v); DECREF(w); return x; } err_setstr(TypeError, "bad operand type(s) for +"); return NULL; } static object * sub(v, w) object *v, *w; { BINOP("__sub__", "__rsub__", sub); if (v->ob_type->tp_as_number != NULL) { object *x; if (coerce(&v, &w) != 0) return NULL; x = (*v->ob_type->tp_as_number->nb_subtract)(v, w); DECREF(v); DECREF(w); return x; } err_setstr(TypeError, "bad operand type(s) for -"); return NULL; } static object * mul(v, w) object *v, *w; { typeobject *tp; tp = v->ob_type; BINOP("__mul__", "__rmul__", mul); if (tp->tp_as_number != NULL && w->ob_type->tp_as_sequence != NULL && !is_instanceobject(v)) { /* number*sequence -- swap v and w */ object *tmp = v; v = w; w = tmp; tp = v->ob_type; } if (tp->tp_as_number != NULL) { object *x; if (is_instanceobject(v)) { /* Instances of user-defined classes get their other argument uncoerced, so they may implement sequence*number as well as number*number. */ INCREF(v); INCREF(w); } else if (coerce(&v, &w) != 0) return NULL; x = (*v->ob_type->tp_as_number->nb_multiply)(v, w); DECREF(v); DECREF(w); return x; } if (tp->tp_as_sequence != NULL) { if (!is_intobject(w)) { err_setstr(TypeError, "can't multiply sequence with non-int"); return NULL; } return (*tp->tp_as_sequence->sq_repeat) (v, (int)getintvalue(w)); } err_setstr(TypeError, "bad operand type(s) for *"); return NULL; } static object * divide(v, w) object *v, *w; { BINOP("__div__", "__rdiv__", divide); if (v->ob_type->tp_as_number != NULL) { object *x; if (coerce(&v, &w) != 0) return NULL; x = (*v->ob_type->tp_as_number->nb_divide)(v, w); DECREF(v); DECREF(w); return x; } err_setstr(TypeError, "bad operand type(s) for /"); return NULL; } static object * mod(v, w) object *v, *w; { if (is_stringobject(v)) { return formatstring(v, w); } BINOP("__mod__", "__rmod__", mod); if (v->ob_type->tp_as_number != NULL) { object *x; if (coerce(&v, &w) != 0) return NULL; x = (*v->ob_type->tp_as_number->nb_remainder)(v, w); DECREF(v); DECREF(w); return x; } err_setstr(TypeError, "bad operand type(s) for %"); return NULL; } static object * neg(v) object *v; { if (v->ob_type->tp_as_number != NULL) return (*v->ob_type->tp_as_number->nb_negative)(v); err_setstr(TypeError, "bad operand type(s) for unary -"); return NULL; } static object * pos(v) object *v; { if (v->ob_type->tp_as_number != NULL) return (*v->ob_type->tp_as_number->nb_positive)(v); err_setstr(TypeError, "bad operand type(s) for unary +"); return NULL; } static object * invert(v) object *v; { object * (*f) FPROTO((object *)); if (v->ob_type->tp_as_number != NULL && (f = v->ob_type->tp_as_number->nb_invert) != NULL) return (*f)(v); err_setstr(TypeError, "bad operand type(s) for unary ~"); return NULL; } static object * not(v) object *v; { int outcome = testbool(v); object *w; if (outcome < 0) return NULL; if (outcome == 0) w = True; else w = False; INCREF(w); return w; } /* External interface to call any callable object. The arg may be NULL. */ object * call_object(func, arg) object *func; object *arg; { binaryfunc call; object *result; if (call = func->ob_type->tp_call) { int size = gettuplesize(arg); if (arg) { size = gettuplesize(arg); if (size == 1) arg = gettupleitem(arg, 0); else if (size == 0) arg = NULL; } result = (*call)(func, arg); } else if (is_instancemethodobject(func) || is_funcobject(func)) result = call_function(func, arg); else result = call_builtin(func, arg); if (result == NULL && !err_occurred()) fatal("null result without error in call_object"); return result; } static object * call_builtin(func, arg) object *func; object *arg; { if (is_methodobject(func)) { method meth = getmethod(func); object *self = getself(func); if (!getvarargs(func) && arg != NULL && is_tupleobject(arg)) { int size = gettuplesize(arg); if (size == 1) arg = gettupleitem(arg, 0); else if (size == 0) arg = NULL; } return (*meth)(self, arg); } if (is_classobject(func)) { return newinstanceobject(func, arg); } if (is_instanceobject(func)) { object *res, *call = getattr(func,"__call__"); if (call == NULL) { err_clear(); err_setstr(AttributeError, "no __call__ method defined"); return NULL; } res = call_object(call, arg); DECREF(call); return res; } err_setstr(TypeError, "call of non-function"); return NULL; } static object * call_function(func, arg) object *func; object *arg; { object *newarg = NULL; object *newlocals, *newglobals; object *class = NULL; object *co, *v; object *argdefs; int argcount; if (is_instancemethodobject(func)) { object *self = instancemethodgetself(func); class = instancemethodgetclass(func); func = instancemethodgetfunc(func); if (self == NULL) { /* Unbound methods must be called with an instance of the class (or a derived class) as first argument */ if (arg != NULL && is_tupleobject(arg) && gettuplesize(arg) >= 1) { self = gettupleitem(arg, 0); if (self != NULL && is_instanceobject(self) && issubclass((object *) (((instanceobject *)self)->in_class), class)) /* self = self */ ; else self = NULL; } if (self == NULL) { err_setstr(TypeError, "unbound method must be called with class instance argument"); return NULL; } } else { if (arg == NULL) argcount = 0; else if (is_tupleobject(arg)) argcount = gettuplesize(arg); else argcount = 1; newarg = newtupleobject(argcount + 1); if (newarg == NULL) return NULL; INCREF(self); settupleitem(newarg, 0, self); if (arg != NULL && !is_tupleobject(arg)) { INCREF(arg); settupleitem(newarg, 1, arg); } else { int i; object *v; for (i = 0; i < argcount; i++) { v = gettupleitem(arg, i); XINCREF(v); settupleitem(newarg, i+1, v); } } arg = newarg; } } else { if (!is_funcobject(func)) { err_setstr(TypeError, "call of non-function"); return NULL; } } argdefs = getfuncargstuff(func, &argcount); if (argdefs != NULL && arg != NULL && is_tupleobject(arg)) { int actualcount, j; /* Process default arguments */ if (argcount & 0x4000) argcount ^= 0x4000; actualcount = gettuplesize(arg); j = gettuplesize(argdefs) - (argcount - actualcount); if (actualcount < argcount && j >= 0) { int i; object *v; if (newarg == NULL) INCREF(arg); newarg = newtupleobject(argcount); if (newarg == NULL) { DECREF(arg); return NULL; } for (i = 0; i < actualcount; i++) { v = gettupleitem(arg, i); XINCREF(v); settupleitem(newarg, i, v); } for (; i < argcount; i++, j++) { v = gettupleitem(argdefs, j); XINCREF(v); settupleitem(newarg, i, v); } DECREF(arg); arg = newarg; } } co = getfunccode(func); if (co == NULL) { XDECREF(newarg); return NULL; } if (!is_codeobject(co)) fatal("XXX Bad code"); newlocals = newdictobject(); if (newlocals == NULL) { XDECREF(newarg); return NULL; } newglobals = getfuncglobals(func); INCREF(newglobals); v = eval_code((codeobject *)co, newglobals, newlocals, class, arg); DECREF(newlocals); DECREF(newglobals); XDECREF(newarg); return v; } static object * apply_subscript(v, w) object *v, *w; { typeobject *tp = v->ob_type; if (tp->tp_as_sequence == NULL && tp->tp_as_mapping == NULL) { err_setstr(TypeError, "unsubscriptable object"); return NULL; } if (tp->tp_as_mapping != NULL) { return (*tp->tp_as_mapping->mp_subscript)(v, w); } else { int i; if (!is_intobject(w)) { err_setstr(TypeError, "sequence subscript not int"); return NULL; } i = getintvalue(w); if (i < 0) { int len = (*tp->tp_as_sequence->sq_length)(v); if (len < 0) return NULL; i += len; } return (*tp->tp_as_sequence->sq_item)(v, i); } } static object * loop_subscript(v, w) object *v, *w; { sequence_methods *sq = v->ob_type->tp_as_sequence; int i; if (sq == NULL) { err_setstr(TypeError, "loop over non-sequence"); return NULL; } i = getintvalue(w); v = (*sq->sq_item)(v, i); if (v) return v; if (err_occurred() == IndexError) err_clear(); return NULL; } static int slice_index(v, isize, pi) object *v; int isize; int *pi; { if (v != NULL) { if (!is_intobject(v)) { err_setstr(TypeError, "slice index must be int"); return -1; } *pi = getintvalue(v); if (*pi < 0) *pi += isize; } return 0; } static object * apply_slice(u, v, w) /* return u[v:w] */ object *u, *v, *w; { typeobject *tp = u->ob_type; int ilow, ihigh, isize; if (tp->tp_as_sequence == NULL) { err_setstr(TypeError, "only sequences can be sliced"); return NULL; } ilow = 0; isize = ihigh = (*tp->tp_as_sequence->sq_length)(u); if (isize < 0) return NULL; if (slice_index(v, isize, &ilow) != 0) return NULL; if (slice_index(w, isize, &ihigh) != 0) return NULL; return (*tp->tp_as_sequence->sq_slice)(u, ilow, ihigh); } static int assign_subscript(w, key, v) /* w[key] = v */ object *w; object *key; object *v; { typeobject *tp = w->ob_type; sequence_methods *sq; mapping_methods *mp; int (*func)(); if ((mp = tp->tp_as_mapping) != NULL && (func = mp->mp_ass_subscript) != NULL) { return (*func)(w, key, v); } else if ((sq = tp->tp_as_sequence) != NULL && (func = sq->sq_ass_item) != NULL) { if (!is_intobject(key)) { err_setstr(TypeError, "sequence subscript must be integer (assign or del)"); return -1; } else { int i = getintvalue(key); if (i < 0) { int len = (*sq->sq_length)(w); if (len < 0) return -1; i += len; } return (*func)(w, i, v); } } else { err_setstr(TypeError, "can't assign to this subscripted object"); return -1; } } static int assign_slice(u, v, w, x) /* u[v:w] = x */ object *u, *v, *w, *x; { sequence_methods *sq = u->ob_type->tp_as_sequence; int ilow, ihigh, isize; if (sq == NULL) { err_setstr(TypeError, "assign to slice of non-sequence"); return -1; } if (sq == NULL || sq->sq_ass_slice == NULL) { err_setstr(TypeError, "unassignable slice"); return -1; } ilow = 0; isize = ihigh = (*sq->sq_length)(u); if (isize < 0) return -1; if (slice_index(v, isize, &ilow) != 0) return -1; if (slice_index(w, isize, &ihigh) != 0) return -1; return (*sq->sq_ass_slice)(u, ilow, ihigh, x); } static int cmp_exception(err, v) object *err, *v; { if (is_tupleobject(v)) { int i, n; n = gettuplesize(v); for (i = 0; i < n; i++) { /* Test recursively */ if (cmp_exception(err, gettupleitem(v, i))) return 1; } return 0; } if (is_classobject(v) && is_classobject(err)) return issubclass(err, v); return err == v; } static int cmp_member(v, w) object *v, *w; { int i, cmp; object *x; sequence_methods *sq; /* Special case for char in string */ if (is_stringobject(w)) { register char *s, *end; register char c; if (!is_stringobject(v) || getstringsize(v) != 1) { err_setstr(TypeError, "string member test needs char left operand"); return -1; } c = getstringvalue(v)[0]; s = getstringvalue(w); end = s + getstringsize(w); while (s < end) { if (c == *s++) return 1; } return 0; } sq = w->ob_type->tp_as_sequence; if (sq == NULL) { err_setstr(TypeError, "'in' or 'not in' needs sequence right argument"); return -1; } for (i = 0; ; i++) { x = (*sq->sq_item)(w, i); if (x == NULL) { if (err_occurred() == IndexError) { err_clear(); break; } return -1; } cmp = cmpobject(v, x); XDECREF(x); if (cmp == 0) return 1; } return 0; } static object * cmp_outcome(op, v, w) int op; register object *v; register object *w; { register int cmp; register int res = 0; switch (op) { case IS: case IS_NOT: res = (v == w); if (op == (int) IS_NOT) res = !res; break; case IN: case NOT_IN: res = cmp_member(v, w); if (res < 0) return NULL; if (op == (int) NOT_IN) res = !res; break; case EXC_MATCH: res = cmp_exception(v, w); break; default: cmp = cmpobject(v, w); switch (op) { case LT: res = cmp < 0; break; case LE: res = cmp <= 0; break; case EQ: res = cmp == 0; break; case NE: res = cmp != 0; break; case GT: res = cmp > 0; break; case GE: res = cmp >= 0; break; /* XXX no default? (res is initialized to 0 though) */ } } v = res ? True : False; INCREF(v); return v; } static int import_from(locals, v, name) object *locals; object *v; object *name; { object *w, *x; if (!is_moduleobject(v)) { err_setstr(TypeError, "import-from requires module object"); return -1; } w = getmoduledict(v); if (getstringvalue(name)[0] == '*') { int pos, err; object *name, *value; pos = 0; while (mappinggetnext(w, &pos, &name, &value)) { if (!is_stringobject(name) || getstringvalue(name)[0] == '_') continue; if (is_accessobject(value)) { value = getaccessvalue(value, (object *)NULL); if (value == NULL) { err_clear(); continue; } } else INCREF(value); err = dict2insert(locals, name, value); DECREF(value); if (err != 0) return -1; } return 0; } else { x = dict2lookup(w, name); if (x == NULL) { char buf[250]; sprintf(buf, "cannot import name %.230s", getstringvalue(name)); err_setstr(ImportError, buf); return -1; } else return dict2insert(locals, name, x); } } static object * build_class(methods, bases, name) object *methods; /* dictionary */ object *bases; /* tuple containing classes */ object *name; /* string */ { int i; if (!is_tupleobject(bases)) { err_setstr(SystemError, "build_class with non-tuple bases"); return NULL; } if (gettuplesize(bases) > 0) { object *base; base = gettupleitem(bases, 0); /* Call the base's *type*, if it is callable. This code is a hook for Donald Beaudry's type extensions. In unexended Python it will never be triggered since its types are not callable. */ if (base->ob_type->ob_type->tp_call) { object *args; object *class; args = mkvalue("(OOO)", name, bases, methods); class = call_object((object *)base->ob_type, args); DECREF(args); return class; } } if (!is_dictobject(methods)) { err_setstr(SystemError, "build_class with non-dictionary"); return NULL; } if (!is_stringobject(name)) { err_setstr(SystemError, "build_class witn non-string name"); return NULL; } for (i = gettuplesize(bases); --i >= 0; ) { object *base = gettupleitem(bases, i); if (!is_classobject(base)) { err_setstr(TypeError, "base is not a class object"); return NULL; } } return newclassobject(bases, methods, name); } static int access_statement(name, vmode, f) object *name; object *vmode; frameobject *f; { int mode = getintvalue(vmode); object *value, *ac; typeobject *type; int fastind, ret; fastind = -1; if (f->f_localmap == NULL) value = dict2lookup(f->f_locals, name); else { object *map = f->f_localmap; value = NULL; for (fastind = gettuplesize(map); --fastind >= 0; ) { object *fname = gettupleitem(map, fastind); if (cmpobject(name, fname) == 0) { value = getlistitem(f->f_fastlocals, fastind); break; } } } if (value && is_accessobject(value)) { err_setstr(AccessError, "can't override access"); return -1; } err_clear(); if (value != NULL && value != None) type = value->ob_type; else type = NULL; ac = newaccessobject(value, f->f_locals, type, mode); if (ac == NULL) return -1; if (fastind >= 0) ret = setlistitem(f->f_fastlocals, fastind, ac); else { ret = dict2insert(f->f_locals, name, ac); DECREF(ac); } return ret; } static int exec_statement(prog, globals, locals) object *prog; object *globals; object *locals; { char *s; int n; if (is_tupleobject(prog) && globals == None && locals == None && ((n = gettuplesize(prog)) == 2 || n == 3)) { /* Backward compatibility hack */ globals = gettupleitem(prog, 1); if (n == 3) locals = gettupleitem(prog, 2); prog = gettupleitem(prog, 0); } if (globals == None) { globals = getglobals(); if (locals == None) locals = getlocals(); } else if (locals == None) locals = globals; if (!is_stringobject(prog) && !is_codeobject(prog) && !is_fileobject(prog)) { err_setstr(TypeError, "exec 1st arg must be string, code or file object"); return -1; } if (!is_dictobject(globals) || !is_dictobject(locals)) { err_setstr(TypeError, "exec 2nd/3rd args must be dict or None"); return -1; } if (dictlookup(globals, "__builtins__") == NULL) dictinsert(globals, "__builtins__", current_frame->f_builtins); if (is_codeobject(prog)) { if (eval_code((codeobject *) prog, globals, locals, (object *)NULL, (object *)NULL) == NULL) return -1; return 0; } if (is_fileobject(prog)) { FILE *fp = getfilefile(prog); char *name = getstringvalue(getfilename(prog)); if (run_file(fp, name, file_input, globals, locals) == NULL) return -1; return 0; } s = getstringvalue(prog); if (strlen(s) != getstringsize(prog)) { err_setstr(ValueError, "embedded '\\0' in exec string"); return -1; } if (run_string(s, file_input, globals, locals) == NULL) return -1; return 0; }