cpython/Python/ceval.c

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1991-02-19 08:39:46 -04:00
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/* Execute compiled code */
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/* XXX TO DO:
XXX speed up searching for keywords by using a dictionary
XXX document it!
*/
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#include "Python.h"
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#include "compile.h"
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#include "frameobject.h"
#include "eval.h"
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#include "opcode.h"
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#include "structmember.h"
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#ifdef macintosh
#include "macglue.h"
#endif
#include <ctype.h>
/* Turn this on if your compiler chokes on the big switch: */
/* #define CASE_TOO_BIG 1 */
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#ifdef Py_DEBUG
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/* For debugging the interpreter: */
#define LLTRACE 1 /* Low-level trace feature */
#define CHECKEXC 1 /* Double-check exception checking */
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#endif
typedef PyObject *(*callproc)(PyObject *, PyObject *, PyObject *);
/* Forward declarations */
static PyObject *eval_frame(PyFrameObject *);
static PyObject *fast_function(PyObject *, PyObject ***, int, int, int);
static PyObject *fast_cfunction(PyObject *, PyObject ***, int);
static PyObject *do_call(PyObject *, PyObject ***, int, int);
static PyObject *ext_do_call(PyObject *, PyObject ***, int, int, int);
static PyObject *update_keyword_args(PyObject *, int, PyObject ***,PyObject *);
static PyObject *update_star_args(int, int, PyObject *, PyObject ***);
static PyObject *load_args(PyObject ***, int);
#define CALL_FLAG_VAR 1
#define CALL_FLAG_KW 2
#ifdef LLTRACE
static int prtrace(PyObject *, char *);
#endif
static int call_trace(Py_tracefunc, PyObject *, PyFrameObject *,
int, PyObject *);
static void call_trace_protected(Py_tracefunc, PyObject *,
PyFrameObject *, int);
static void call_exc_trace(Py_tracefunc, PyObject *, PyFrameObject *);
static PyObject *loop_subscript(PyObject *, PyObject *);
static PyObject *apply_slice(PyObject *, PyObject *, PyObject *);
static int assign_slice(PyObject *, PyObject *,
PyObject *, PyObject *);
static PyObject *cmp_outcome(int, PyObject *, PyObject *);
static PyObject *import_from(PyObject *, PyObject *);
static int import_all_from(PyObject *, PyObject *);
static PyObject *build_class(PyObject *, PyObject *, PyObject *);
static int exec_statement(PyFrameObject *,
PyObject *, PyObject *, PyObject *);
static void set_exc_info(PyThreadState *, PyObject *, PyObject *, PyObject *);
static void reset_exc_info(PyThreadState *);
static void format_exc_check_arg(PyObject *, char *, PyObject *);
#define NAME_ERROR_MSG \
"name '%.200s' is not defined"
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
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#define GLOBAL_NAME_ERROR_MSG \
"global name '%.200s' is not defined"
#define UNBOUNDLOCAL_ERROR_MSG \
"local variable '%.200s' referenced before assignment"
#define UNBOUNDFREE_ERROR_MSG \
"free variable '%.200s' referenced before assignment" \
" in enclosing scope"
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/* Dynamic execution profile */
#ifdef DYNAMIC_EXECUTION_PROFILE
#ifdef DXPAIRS
static long dxpairs[257][256];
#define dxp dxpairs[256]
#else
static long dxp[256];
#endif
#endif
staticforward PyTypeObject gentype;
typedef struct {
PyObject_HEAD
/* The gi_ prefix is intended to remind of generator-iterator. */
PyFrameObject *gi_frame;
/* True if generator is being executed. */
int gi_running;
} genobject;
static PyObject *
gen_new(PyFrameObject *f)
{
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genobject *gen = PyObject_GC_New(genobject, &gentype);
if (gen == NULL) {
Py_DECREF(f);
return NULL;
}
gen->gi_frame = f;
gen->gi_running = 0;
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_PyObject_GC_TRACK(gen);
return (PyObject *)gen;
}
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static int
gen_traverse(genobject *gen, visitproc visit, void *arg)
{
return visit((PyObject *)gen->gi_frame, arg);
}
static void
gen_dealloc(genobject *gen)
{
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_PyObject_GC_UNTRACK(gen);
Py_DECREF(gen->gi_frame);
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PyObject_GC_Del(gen);
}
static PyObject *
gen_iternext(genobject *gen)
{
PyThreadState *tstate = PyThreadState_GET();
PyFrameObject *f = gen->gi_frame;
PyObject *result;
if (gen->gi_running) {
PyErr_SetString(PyExc_ValueError,
"generator already executing");
return NULL;
}
if (f->f_stacktop == NULL)
return NULL;
/* Generators always return to their most recent caller, not
* necessarily their creator. */
Py_XINCREF(tstate->frame);
assert(f->f_back == NULL);
f->f_back = tstate->frame;
gen->gi_running = 1;
result = eval_frame(f);
gen->gi_running = 0;
/* Don't keep the reference to f_back any longer than necessary. It
* may keep a chain of frames alive or it could create a reference
* cycle. */
Py_XDECREF(f->f_back);
f->f_back = NULL;
/* If the generator just returned (as opposed to yielding), signal
* that the generator is exhausted. */
if (result == Py_None && f->f_stacktop == NULL) {
Py_DECREF(result);
result = NULL;
}
return result;
}
static PyObject *
gen_next(genobject *gen)
{
PyObject *result;
result = gen_iternext(gen);
if (result == NULL && !PyErr_Occurred()) {
PyErr_SetObject(PyExc_StopIteration, Py_None);
return NULL;
}
return result;
}
static PyObject *
gen_getiter(PyObject *gen)
{
Py_INCREF(gen);
return gen;
}
static struct PyMethodDef gen_methods[] = {
{"next", (PyCFunction)gen_next, METH_NOARGS,
"next() -- get the next value, or raise StopIteration"},
{NULL, NULL} /* Sentinel */
};
static PyMemberDef gen_memberlist[] = {
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{"gi_frame", T_OBJECT, offsetof(genobject, gi_frame), RO},
{"gi_running", T_INT, offsetof(genobject, gi_running), RO},
{NULL} /* Sentinel */
};
statichere PyTypeObject gentype = {
PyObject_HEAD_INIT(&PyType_Type)
0, /* ob_size */
"generator", /* tp_name */
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sizeof(genobject), /* tp_basicsize */
0, /* tp_itemsize */
/* methods */
(destructor)gen_dealloc, /* tp_dealloc */
0, /* tp_print */
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0, /* tp_getattr */
0, /* tp_setattr */
0, /* tp_compare */
0, /* tp_repr */
0, /* tp_as_number */
0, /* tp_as_sequence */
0, /* tp_as_mapping */
0, /* tp_hash */
0, /* tp_call */
0, /* tp_str */
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PyObject_GenericGetAttr, /* tp_getattro */
0, /* tp_setattro */
0, /* tp_as_buffer */
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Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HAVE_GC,/* tp_flags */
0, /* tp_doc */
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(traverseproc)gen_traverse, /* tp_traverse */
0, /* tp_clear */
0, /* tp_richcompare */
0, /* tp_weaklistoffset */
(getiterfunc)gen_getiter, /* tp_iter */
(iternextfunc)gen_iternext, /* tp_iternext */
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gen_methods, /* tp_methods */
gen_memberlist, /* tp_members */
0, /* tp_getset */
0, /* tp_base */
0, /* tp_dict */
};
#ifdef WITH_THREAD
#ifndef DONT_HAVE_ERRNO_H
#include <errno.h>
#endif
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#include "pythread.h"
extern int _PyThread_Started; /* Flag for Py_Exit */
static PyThread_type_lock interpreter_lock = 0;
static long main_thread = 0;
void
PyEval_InitThreads(void)
{
if (interpreter_lock)
return;
_PyThread_Started = 1;
interpreter_lock = PyThread_allocate_lock();
PyThread_acquire_lock(interpreter_lock, 1);
main_thread = PyThread_get_thread_ident();
}
void
PyEval_AcquireLock(void)
{
PyThread_acquire_lock(interpreter_lock, 1);
}
void
PyEval_ReleaseLock(void)
{
PyThread_release_lock(interpreter_lock);
}
void
PyEval_AcquireThread(PyThreadState *tstate)
{
if (tstate == NULL)
Py_FatalError("PyEval_AcquireThread: NULL new thread state");
PyThread_acquire_lock(interpreter_lock, 1);
if (PyThreadState_Swap(tstate) != NULL)
Py_FatalError(
"PyEval_AcquireThread: non-NULL old thread state");
}
void
PyEval_ReleaseThread(PyThreadState *tstate)
{
if (tstate == NULL)
Py_FatalError("PyEval_ReleaseThread: NULL thread state");
if (PyThreadState_Swap(NULL) != tstate)
Py_FatalError("PyEval_ReleaseThread: wrong thread state");
PyThread_release_lock(interpreter_lock);
}
/* This function is called from PyOS_AfterFork to ensure that newly
created child processes don't hold locks referring to threads which
are not running in the child process. (This could also be done using
pthread_atfork mechanism, at least for the pthreads implementation.) */
void
PyEval_ReInitThreads(void)
{
if (!interpreter_lock)
return;
/*XXX Can't use PyThread_free_lock here because it does too
much error-checking. Doing this cleanly would require
adding a new function to each thread_*.h. Instead, just
create a new lock and waste a little bit of memory */
interpreter_lock = PyThread_allocate_lock();
PyThread_acquire_lock(interpreter_lock, 1);
main_thread = PyThread_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: */
PyThreadState *
PyEval_SaveThread(void)
{
PyThreadState *tstate = PyThreadState_Swap(NULL);
if (tstate == NULL)
Py_FatalError("PyEval_SaveThread: NULL tstate");
#ifdef WITH_THREAD
if (interpreter_lock)
PyThread_release_lock(interpreter_lock);
#endif
return tstate;
}
void
PyEval_RestoreThread(PyThreadState *tstate)
{
if (tstate == NULL)
Py_FatalError("PyEval_RestoreThread: NULL tstate");
#ifdef WITH_THREAD
if (interpreter_lock) {
int err = errno;
PyThread_acquire_lock(interpreter_lock, 1);
errno = err;
}
#endif
PyThreadState_Swap(tstate);
}
/* 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.
XXX Darn! With the advent of thread state, we should have an array
of pending calls per thread in the thread state! Later...
*/
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#define NPENDINGCALLS 32
static struct {
int (*func)(void *);
void *arg;
} pendingcalls[NPENDINGCALLS];
static volatile int pendingfirst = 0;
static volatile int pendinglast = 0;
static volatile int things_to_do = 0;
int
Py_AddPendingCall(int (*func)(void *), void *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;
things_to_do = 1; /* Signal main loop */
busy = 0;
/* XXX End critical section */
return 0;
}
int
Py_MakePendingCalls(void)
{
static int busy = 0;
#ifdef WITH_THREAD
if (main_thread && PyThread_get_thread_ident() != main_thread)
return 0;
#endif
if (busy)
return 0;
busy = 1;
things_to_do = 0;
for (;;) {
int i;
int (*func)(void *);
void *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;
things_to_do = 1; /* We're not done yet */
return -1;
}
}
busy = 0;
return 0;
}
/* The interpreter's recursion limit */
static int recursion_limit = 1000;
int
Py_GetRecursionLimit(void)
{
return recursion_limit;
}
void
Py_SetRecursionLimit(int new_limit)
{
recursion_limit = new_limit;
}
/* 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 */
WHY_CONTINUE, /* 'continue' statement */
WHY_YIELD /* 'yield' operator */
};
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static enum why_code do_raise(PyObject *, PyObject *, PyObject *);
static int unpack_iterable(PyObject *, int, PyObject **);
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PyObject *
PyEval_EvalCode(PyCodeObject *co, PyObject *globals, PyObject *locals)
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{
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return PyEval_EvalCodeEx(co,
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globals, locals,
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(PyObject **)NULL, 0,
(PyObject **)NULL, 0,
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
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(PyObject **)NULL, 0,
NULL);
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}
/* Interpreter main loop */
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static PyObject *
eval_frame(PyFrameObject *f)
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{
#ifdef DXPAIRS
int lastopcode = 0;
#endif
PyObject **stack_pointer; /* Next free slot in value stack */
register unsigned char *next_instr;
register int opcode=0; /* Current opcode */
register int oparg=0; /* Current opcode argument, if any */
register enum why_code why; /* Reason for block stack unwind */
register int err; /* Error status -- nonzero if error */
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register PyObject *x; /* Result object -- NULL if error */
register PyObject *v; /* Temporary objects popped off stack */
register PyObject *w;
register PyObject *u;
register PyObject *t;
register PyObject *stream = NULL; /* for PRINT opcodes */
register PyObject **fastlocals, **freevars;
PyObject *retval = NULL; /* Return value */
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PyThreadState *tstate = PyThreadState_GET();
PyCodeObject *co;
unsigned char *first_instr;
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#ifdef LLTRACE
int lltrace;
#endif
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#if defined(Py_DEBUG) || defined(LLTRACE)
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/* Make it easier to find out where we are with a debugger */
char *filename;
#endif
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/* Code access macros */
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#define GETCONST(i) Getconst(f, i)
#define GETNAME(i) Getname(f, i)
#define GETNAMEV(i) Getnamev(f, i)
#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))
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/* Stack manipulation macros */
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#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)
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#ifdef LLTRACE
#define PUSH(v) { (void)(BASIC_PUSH(v), \
lltrace && prtrace(TOP(), "push")); \
assert(STACK_LEVEL() <= f->f_stacksize); }
#define POP() ((void)(lltrace && prtrace(TOP(), "pop")), BASIC_POP())
#else
#define PUSH(v) BASIC_PUSH(v)
#define POP() BASIC_POP()
#endif
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/* Local variable macros */
#define GETLOCAL(i) (fastlocals[i])
/* The SETLOCAL() macro must not DECREF the local variable in-place and
then store the new value; it must copy the old value to a temporary
value, then store the new value, and then DECREF the temporary value.
This is because it is possible that during the DECREF the frame is
accessed by other code (e.g. a __del__ method or gc.collect()) and the
variable would be pointing to already-freed memory. */
#define SETLOCAL(i, value) do { PyObject *tmp = GETLOCAL(i); \
GETLOCAL(i) = value; \
Py_XDECREF(tmp); } while (0)
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/* Start of code */
if (f == NULL)
return NULL;
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#ifdef USE_STACKCHECK
if (tstate->recursion_depth%10 == 0 && PyOS_CheckStack()) {
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PyErr_SetString(PyExc_MemoryError, "Stack overflow");
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return NULL;
}
#endif
/* push frame */
if (++tstate->recursion_depth > recursion_limit) {
--tstate->recursion_depth;
PyErr_SetString(PyExc_RuntimeError,
"maximum recursion depth exceeded");
tstate->frame = f->f_back;
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return NULL;
}
tstate->frame = f;
co = f->f_code;
fastlocals = f->f_localsplus;
freevars = f->f_localsplus + f->f_nlocals;
_PyCode_GETCODEPTR(co, &first_instr);
next_instr = first_instr + f->f_lasti;
stack_pointer = f->f_stacktop;
assert(stack_pointer != NULL);
f->f_stacktop = NULL; /* remains NULL unless yield suspends frame */
if (tstate->use_tracing) {
if (tstate->c_tracefunc != NULL) {
/* tstate->c_tracefunc, 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 is also called
whenever an exception is detected. */
if (call_trace(tstate->c_tracefunc, tstate->c_traceobj,
f, PyTrace_CALL, Py_None)) {
/* Trace function raised an error */
return NULL;
}
}
if (tstate->c_profilefunc != NULL) {
/* Similar for c_profilefunc, except it needn't
return itself and isn't called for "line" events */
if (call_trace(tstate->c_profilefunc,
tstate->c_profileobj,
f, PyTrace_CALL, Py_None)) {
/* Profile function raised an error */
return NULL;
}
}
}
#ifdef LLTRACE
lltrace = PyDict_GetItemString(f->f_globals,"__lltrace__") != NULL;
#endif
#if defined(Py_DEBUG) || defined(LLTRACE)
filename = PyString_AsString(co->co_filename);
#endif
why = WHY_NOT;
err = 0;
1997-04-29 15:18:01 -03:00
x = Py_None; /* Not a reference, just anything non-NULL */
w = NULL;
for (;;) {
assert(stack_pointer >= f->f_valuestack); /* else underflow */
assert(STACK_LEVEL() <= f->f_stacksize); /* else overflow */
/* Do periodic things. Doing this every time through
the loop would add too much overhead, so we do it
only every Nth instruction. We also do it if
``things_to_do'' is set, i.e. when an asynchronous
event needs attention (e.g. a signal handler or
async I/O handler); see Py_AddPendingCall() and
Py_MakePendingCalls() above. */
if (things_to_do || --tstate->ticker < 0) {
tstate->ticker = tstate->interp->checkinterval;
if (things_to_do) {
1996-07-30 13:49:37 -03:00
if (Py_MakePendingCalls() < 0) {
why = WHY_EXCEPTION;
goto on_error;
}
}
#if !defined(HAVE_SIGNAL_H) || defined(macintosh)
/* If we have true signals, the signal handler
will call Py_AddPendingCall() so we don't
have to call sigcheck(). On the Mac and
DOS, alas, we have to call it. */
1997-04-29 15:18:01 -03:00
if (PyErr_CheckSignals()) {
why = WHY_EXCEPTION;
goto on_error;
}
#endif
#ifdef WITH_THREAD
if (interpreter_lock) {
/* Give another thread a chance */
if (PyThreadState_Swap(NULL) != tstate)
Py_FatalError("ceval: tstate mix-up");
PyThread_release_lock(interpreter_lock);
/* Other threads may run now */
PyThread_acquire_lock(interpreter_lock, 1);
if (PyThreadState_Swap(tstate) != NULL)
Py_FatalError("ceval: orphan tstate");
}
#endif
1990-11-18 13:27:39 -04:00
}
fast_next_opcode:
/* Extract opcode and argument */
1996-12-30 12:17:54 -04:00
#if defined(Py_DEBUG) || defined(LLTRACE)
f->f_lasti = INSTR_OFFSET();
#endif
opcode = NEXTOP();
if (HAS_ARG(opcode))
oparg = NEXTARG();
dispatch_opcode:
#ifdef DYNAMIC_EXECUTION_PROFILE
#ifdef DXPAIRS
dxpairs[lastopcode][opcode]++;
lastopcode = opcode;
#endif
dxp[opcode]++;
#endif
1990-11-18 13:27:39 -04:00
1992-01-11 22:29:51 -04:00
#ifdef LLTRACE
/* Instruction tracing */
1992-01-11 22:29:51 -04:00
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
1990-12-20 11:06:42 -04:00
/* Main switch on opcode */
1990-12-20 11:06:42 -04:00
switch (opcode) {
1990-12-20 11:06:42 -04:00
/* 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! */
1990-12-20 11:06:42 -04:00
/* case STOP_CODE: this is an error! */
case SET_LINENO:
#ifdef LLTRACE
if (lltrace)
printf("--- %s:%d \n", filename, oparg);
#endif
f->f_lineno = oparg;
if (tstate->c_tracefunc == NULL || tstate->tracing)
goto fast_next_opcode;
/* Trace each line of code reached */
f->f_lasti = INSTR_OFFSET();
/* Inline call_trace() for performance: */
tstate->tracing++;
tstate->use_tracing = 0;
err = (tstate->c_tracefunc)(tstate->c_traceobj, f,
PyTrace_LINE, Py_None);
tstate->use_tracing = (tstate->c_tracefunc
|| tstate->c_profilefunc);
tstate->tracing--;
break;
case LOAD_FAST:
x = GETLOCAL(oparg);
if (x != NULL) {
Py_INCREF(x);
PUSH(x);
goto fast_next_opcode;
}
format_exc_check_arg(PyExc_UnboundLocalError,
UNBOUNDLOCAL_ERROR_MSG,
PyTuple_GetItem(co->co_varnames, oparg));
break;
case LOAD_CONST:
x = GETCONST(oparg);
Py_INCREF(x);
PUSH(x);
goto fast_next_opcode;
case STORE_FAST:
v = POP();
SETLOCAL(oparg, v);
goto fast_next_opcode;
1990-11-18 13:27:39 -04:00
case POP_TOP:
v = POP();
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
goto fast_next_opcode;
1990-11-18 13:27:39 -04:00
case ROT_TWO:
v = POP();
w = POP();
PUSH(v);
PUSH(w);
continue;
1990-11-18 13:27:39 -04:00
case ROT_THREE:
v = POP();
w = POP();
x = POP();
PUSH(v);
PUSH(x);
PUSH(w);
continue;
case ROT_FOUR:
u = POP();
v = POP();
w = POP();
x = POP();
PUSH(u);
PUSH(x);
PUSH(w);
PUSH(v);
continue;
1990-12-20 11:06:42 -04:00
case DUP_TOP:
v = TOP();
1997-04-29 15:18:01 -03:00
Py_INCREF(v);
1990-12-20 11:06:42 -04:00
PUSH(v);
continue;
case DUP_TOPX:
switch (oparg) {
case 1:
x = TOP();
Py_INCREF(x);
PUSH(x);
continue;
case 2:
x = POP();
Py_INCREF(x);
w = TOP();
Py_INCREF(w);
PUSH(x);
PUSH(w);
PUSH(x);
continue;
case 3:
x = POP();
Py_INCREF(x);
w = POP();
Py_INCREF(w);
v = TOP();
Py_INCREF(v);
PUSH(w);
PUSH(x);
PUSH(v);
PUSH(w);
PUSH(x);
continue;
case 4:
x = POP();
Py_INCREF(x);
w = POP();
Py_INCREF(w);
v = POP();
Py_INCREF(v);
u = TOP();
Py_INCREF(u);
PUSH(v);
PUSH(w);
PUSH(x);
PUSH(u);
PUSH(v);
PUSH(w);
PUSH(x);
continue;
case 5:
x = POP();
Py_INCREF(x);
w = POP();
Py_INCREF(w);
v = POP();
Py_INCREF(v);
u = POP();
Py_INCREF(u);
t = TOP();
Py_INCREF(t);
PUSH(u);
PUSH(v);
PUSH(w);
PUSH(x);
PUSH(t);
PUSH(u);
PUSH(v);
PUSH(w);
PUSH(x);
continue;
default:
Py_FatalError("invalid argument to DUP_TOPX"
" (bytecode corruption?)");
}
break;
1990-11-18 13:27:39 -04:00
case UNARY_POSITIVE:
v = POP();
x = PyNumber_Positive(v);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case UNARY_NEGATIVE:
v = POP();
x = PyNumber_Negative(v);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case UNARY_NOT:
v = POP();
err = PyObject_IsTrue(v);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
if (err == 0) {
Py_INCREF(Py_True);
PUSH(Py_True);
continue;
}
else if (err > 0) {
Py_INCREF(Py_False);
PUSH(Py_False);
err = 0;
continue;
}
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case UNARY_CONVERT:
v = POP();
1997-04-29 15:18:01 -03:00
x = PyObject_Repr(v);
Py_DECREF(v);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1991-10-24 11:59:31 -03:00
case UNARY_INVERT:
v = POP();
x = PyNumber_Invert(v);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
1991-10-24 11:59:31 -03:00
PUSH(x);
if (x != NULL) continue;
1991-10-24 11:59:31 -03:00
break;
case BINARY_POWER:
w = POP();
v = POP();
x = PyNumber_Power(v, w, Py_None);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
1990-11-18 13:27:39 -04:00
case BINARY_MULTIPLY:
w = POP();
v = POP();
x = PyNumber_Multiply(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case BINARY_DIVIDE:
if (!_Py_QnewFlag) {
w = POP();
v = POP();
x = PyNumber_Divide(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
}
/* -Qnew is in effect: fall through to
BINARY_TRUE_DIVIDE */
case BINARY_TRUE_DIVIDE:
1990-11-18 13:27:39 -04:00
w = POP();
v = POP();
x = PyNumber_TrueDivide(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
case BINARY_FLOOR_DIVIDE:
w = POP();
v = POP();
x = PyNumber_FloorDivide(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
1990-11-18 13:27:39 -04:00
case BINARY_MODULO:
w = POP();
v = POP();
x = PyNumber_Remainder(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case BINARY_ADD:
w = POP();
v = POP();
if (PyInt_CheckExact(v) && PyInt_CheckExact(w)) {
/* INLINE: int + int */
register long a, b, i;
a = PyInt_AS_LONG(v);
b = PyInt_AS_LONG(w);
i = a + b;
if ((i^a) < 0 && (i^b) < 0)
goto slow_add;
x = PyInt_FromLong(i);
}
else {
slow_add:
x = PyNumber_Add(v, w);
}
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case BINARY_SUBTRACT:
w = POP();
v = POP();
if (PyInt_CheckExact(v) && PyInt_CheckExact(w)) {
/* INLINE: int - int */
register long a, b, i;
a = PyInt_AS_LONG(v);
b = PyInt_AS_LONG(w);
i = a - b;
if ((i^a) < 0 && (i^~b) < 0)
goto slow_sub;
x = PyInt_FromLong(i);
}
else {
slow_sub:
x = PyNumber_Subtract(v, w);
}
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case BINARY_SUBSCR:
w = POP();
v = POP();
if (PyList_CheckExact(v) && PyInt_CheckExact(w)) {
/* INLINE: list[int] */
long i = PyInt_AsLong(w);
if (i < 0)
i += PyList_GET_SIZE(v);
if (i < 0 ||
i >= PyList_GET_SIZE(v)) {
PyErr_SetString(PyExc_IndexError,
"list index out of range");
x = NULL;
}
else {
x = PyList_GET_ITEM(v, i);
Py_INCREF(x);
}
}
else
x = PyObject_GetItem(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1991-10-24 11:59:31 -03:00
case BINARY_LSHIFT:
w = POP();
v = POP();
x = PyNumber_Lshift(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1991-10-24 11:59:31 -03:00
PUSH(x);
if (x != NULL) continue;
1991-10-24 11:59:31 -03:00
break;
1991-10-24 11:59:31 -03:00
case BINARY_RSHIFT:
w = POP();
v = POP();
x = PyNumber_Rshift(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1991-10-24 11:59:31 -03:00
PUSH(x);
if (x != NULL) continue;
1991-10-24 11:59:31 -03:00
break;
1991-10-24 11:59:31 -03:00
case BINARY_AND:
w = POP();
v = POP();
x = PyNumber_And(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1991-10-24 11:59:31 -03:00
PUSH(x);
if (x != NULL) continue;
1991-10-24 11:59:31 -03:00
break;
1991-10-24 11:59:31 -03:00
case BINARY_XOR:
w = POP();
v = POP();
x = PyNumber_Xor(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1991-10-24 11:59:31 -03:00
PUSH(x);
if (x != NULL) continue;
1991-10-24 11:59:31 -03:00
break;
1991-10-24 11:59:31 -03:00
case BINARY_OR:
w = POP();
v = POP();
x = PyNumber_Or(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1991-10-24 11:59:31 -03:00
PUSH(x);
if (x != NULL) continue;
1991-10-24 11:59:31 -03:00
break;
case INPLACE_POWER:
w = POP();
v = POP();
x = PyNumber_InPlacePower(v, w, Py_None);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_MULTIPLY:
w = POP();
v = POP();
x = PyNumber_InPlaceMultiply(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_DIVIDE:
if (!_Py_QnewFlag) {
w = POP();
v = POP();
x = PyNumber_InPlaceDivide(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
}
/* -Qnew is in effect: fall through to
INPLACE_TRUE_DIVIDE */
case INPLACE_TRUE_DIVIDE:
w = POP();
v = POP();
x = PyNumber_InPlaceTrueDivide(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_FLOOR_DIVIDE:
w = POP();
v = POP();
x = PyNumber_InPlaceFloorDivide(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_MODULO:
w = POP();
v = POP();
x = PyNumber_InPlaceRemainder(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_ADD:
w = POP();
v = POP();
if (PyInt_CheckExact(v) && PyInt_CheckExact(w)) {
/* INLINE: int + int */
register long a, b, i;
a = PyInt_AS_LONG(v);
b = PyInt_AS_LONG(w);
i = a + b;
if ((i^a) < 0 && (i^b) < 0)
goto slow_iadd;
x = PyInt_FromLong(i);
}
else {
slow_iadd:
x = PyNumber_InPlaceAdd(v, w);
}
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_SUBTRACT:
w = POP();
v = POP();
if (PyInt_CheckExact(v) && PyInt_CheckExact(w)) {
/* INLINE: int - int */
register long a, b, i;
a = PyInt_AS_LONG(v);
b = PyInt_AS_LONG(w);
i = a - b;
if ((i^a) < 0 && (i^~b) < 0)
goto slow_isub;
x = PyInt_FromLong(i);
}
else {
slow_isub:
x = PyNumber_InPlaceSubtract(v, w);
}
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_LSHIFT:
w = POP();
v = POP();
x = PyNumber_InPlaceLshift(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_RSHIFT:
w = POP();
v = POP();
x = PyNumber_InPlaceRshift(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_AND:
w = POP();
v = POP();
x = PyNumber_InPlaceAnd(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_XOR:
w = POP();
v = POP();
x = PyNumber_InPlaceXor(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case INPLACE_OR:
w = POP();
v = POP();
x = PyNumber_InPlaceOr(v, w);
Py_DECREF(v);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
break;
case SLICE+0:
1990-11-18 13:27:39 -04:00
case SLICE+1:
case SLICE+2:
case SLICE+3:
1990-12-20 11:06:42 -04:00
if ((opcode-SLICE) & 2)
w = POP();
else
w = NULL;
1990-12-20 11:06:42 -04:00
if ((opcode-SLICE) & 1)
v = POP();
else
v = NULL;
1990-11-18 13:27:39 -04:00
u = POP();
1990-12-20 11:06:42 -04:00
x = apply_slice(u, v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(u);
Py_XDECREF(v);
Py_XDECREF(w);
1990-11-18 13:27:39 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
case STORE_SLICE+0:
1990-11-18 13:27:39 -04:00
case STORE_SLICE+1:
case STORE_SLICE+2:
case STORE_SLICE+3:
1990-12-20 11:06:42 -04:00
if ((opcode-STORE_SLICE) & 2)
w = POP();
else
w = NULL;
1990-12-20 11:06:42 -04:00
if ((opcode-STORE_SLICE) & 1)
v = POP();
else
v = NULL;
1990-11-18 13:27:39 -04:00
u = POP();
1990-12-20 11:06:42 -04:00
t = POP();
err = assign_slice(u, v, w, t); /* u[v:w] = t */
1997-04-29 15:18:01 -03:00
Py_DECREF(t);
Py_DECREF(u);
Py_XDECREF(v);
Py_XDECREF(w);
if (err == 0) continue;
1990-11-18 13:27:39 -04:00
break;
case DELETE_SLICE+0:
1990-11-18 13:27:39 -04:00
case DELETE_SLICE+1:
case DELETE_SLICE+2:
case DELETE_SLICE+3:
1990-12-20 11:06:42 -04:00
if ((opcode-DELETE_SLICE) & 2)
w = POP();
else
w = NULL;
1990-12-20 11:06:42 -04:00
if ((opcode-DELETE_SLICE) & 1)
v = POP();
else
v = NULL;
1990-11-18 13:27:39 -04:00
u = POP();
1997-04-29 15:18:01 -03:00
err = assign_slice(u, v, w, (PyObject *)NULL);
1990-12-20 11:06:42 -04:00
/* del u[v:w] */
1997-04-29 15:18:01 -03:00
Py_DECREF(u);
Py_XDECREF(v);
Py_XDECREF(w);
if (err == 0) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case STORE_SUBSCR:
w = POP();
v = POP();
u = POP();
/* v[w] = u */
err = PyObject_SetItem(v, w, u);
1997-04-29 15:18:01 -03:00
Py_DECREF(u);
Py_DECREF(v);
Py_DECREF(w);
if (err == 0) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case DELETE_SUBSCR:
w = POP();
v = POP();
/* del v[w] */
err = PyObject_DelItem(v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
if (err == 0) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case PRINT_EXPR:
v = POP();
w = PySys_GetObject("displayhook");
if (w == NULL) {
PyErr_SetString(PyExc_RuntimeError,
"lost sys.displayhook");
err = -1;
x = NULL;
}
if (err == 0) {
x = Py_BuildValue("(O)", v);
if (x == NULL)
err = -1;
}
if (err == 0) {
w = PyEval_CallObject(w, x);
Py_XDECREF(w);
if (w == NULL)
err = -1;
1997-04-29 15:18:01 -03:00
}
Py_DECREF(v);
Py_XDECREF(x);
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break;
case PRINT_ITEM_TO:
w = stream = POP();
/* fall through to PRINT_ITEM */
1990-11-18 13:27:39 -04:00
case PRINT_ITEM:
v = POP();
if (stream == NULL || stream == Py_None) {
w = PySys_GetObject("stdout");
if (w == NULL) {
PyErr_SetString(PyExc_RuntimeError,
"lost sys.stdout");
err = -1;
}
}
if (w != NULL && PyFile_SoftSpace(w, 0))
err = PyFile_WriteString(" ", w);
if (err == 0)
err = PyFile_WriteObject(v, w, Py_PRINT_RAW);
if (err == 0) {
/* XXX move into writeobject() ? */
if (PyString_Check(v)) {
char *s = PyString_AS_STRING(v);
int len = PyString_GET_SIZE(v);
if (len == 0 ||
!isspace(Py_CHARMASK(s[len-1])) ||
s[len-1] == ' ')
PyFile_SoftSpace(w, 1);
}
#ifdef Py_USING_UNICODE
else if (PyUnicode_Check(v)) {
Py_UNICODE *s = PyUnicode_AS_UNICODE(v);
int len = PyUnicode_GET_SIZE(v);
if (len == 0 ||
!Py_UNICODE_ISSPACE(s[len-1]) ||
s[len-1] == ' ')
PyFile_SoftSpace(w, 1);
}
else
PyFile_SoftSpace(w, 1);
#endif
1990-11-18 13:27:39 -04:00
}
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_XDECREF(stream);
stream = NULL;
if (err == 0)
continue;
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break;
case PRINT_NEWLINE_TO:
w = stream = POP();
/* fall through to PRINT_NEWLINE */
1990-11-18 13:27:39 -04:00
case PRINT_NEWLINE:
if (stream == NULL || stream == Py_None) {
w = PySys_GetObject("stdout");
if (w == NULL)
PyErr_SetString(PyExc_RuntimeError,
"lost sys.stdout");
}
if (w != NULL) {
err = PyFile_WriteString("\n", w);
if (err == 0)
PyFile_SoftSpace(w, 0);
}
Py_XDECREF(stream);
stream = NULL;
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break;
#ifdef CASE_TOO_BIG
default: switch (opcode) {
#endif
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case BREAK_LOOP:
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why = WHY_BREAK;
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break;
case CONTINUE_LOOP:
retval = PyInt_FromLong(oparg);
why = WHY_CONTINUE;
break;
case RAISE_VARARGS:
u = v = w = NULL;
switch (oparg) {
case 3:
u = POP(); /* traceback */
/* Fallthrough */
case 2:
v = POP(); /* value */
/* Fallthrough */
case 1:
w = POP(); /* exc */
1998-04-09 18:39:57 -03:00
case 0: /* Fallthrough */
why = do_raise(w, v, u);
break;
default:
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PyErr_SetString(PyExc_SystemError,
"bad RAISE_VARARGS oparg");
why = WHY_EXCEPTION;
break;
}
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break;
case LOAD_LOCALS:
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if ((x = f->f_locals) == NULL) {
PyErr_SetString(PyExc_SystemError,
"no locals");
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break;
}
1997-04-29 15:18:01 -03:00
Py_INCREF(x);
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PUSH(x);
break;
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case RETURN_VALUE:
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retval = POP();
why = WHY_RETURN;
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break;
case YIELD_VALUE:
retval = POP();
f->f_stacktop = stack_pointer;
f->f_lasti = INSTR_OFFSET();
why = WHY_YIELD;
break;
case EXEC_STMT:
w = POP();
v = POP();
u = POP();
err = exec_statement(f, u, v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(u);
Py_DECREF(v);
Py_DECREF(w);
break;
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case POP_BLOCK:
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{
1997-04-29 15:18:01 -03:00
PyTryBlock *b = PyFrame_BlockPop(f);
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while (STACK_LEVEL() > b->b_level) {
v = POP();
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
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}
}
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break;
1990-11-18 13:27:39 -04:00
case END_FINALLY:
v = POP();
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if (PyInt_Check(v)) {
why = (enum why_code) PyInt_AsLong(v);
if (why == WHY_RETURN ||
why == WHY_YIELD ||
why == CONTINUE_LOOP)
1990-12-20 11:06:42 -04:00
retval = POP();
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}
1997-04-29 15:18:01 -03:00
else if (PyString_Check(v) || PyClass_Check(v)) {
1990-12-20 11:06:42 -04:00
w = POP();
u = POP();
1997-04-29 15:18:01 -03:00
PyErr_Restore(v, w, u);
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why = WHY_RERAISE;
1995-07-28 20:06:00 -03:00
break;
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}
1997-04-29 15:18:01 -03:00
else if (v != Py_None) {
PyErr_SetString(PyExc_SystemError,
1990-12-20 11:06:42 -04:00
"'finally' pops bad exception");
why = WHY_EXCEPTION;
1990-11-18 13:27:39 -04:00
}
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
1990-11-18 13:27:39 -04:00
break;
case BUILD_CLASS:
u = POP();
v = POP();
w = POP();
x = build_class(u, v, w);
PUSH(x);
1997-04-29 15:18:01 -03:00
Py_DECREF(u);
Py_DECREF(v);
Py_DECREF(w);
break;
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case STORE_NAME:
1991-04-03 14:59:50 -04:00
w = GETNAMEV(oparg);
1990-11-18 13:27:39 -04:00
v = POP();
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if ((x = f->f_locals) == NULL) {
PyErr_Format(PyExc_SystemError,
"no locals found when storing %s",
PyObject_REPR(w));
1995-07-18 11:51:37 -03:00
break;
}
1997-04-29 15:18:01 -03:00
err = PyDict_SetItem(x, w, v);
Py_DECREF(v);
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case DELETE_NAME:
w = GETNAMEV(oparg);
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if ((x = f->f_locals) == NULL) {
PyErr_Format(PyExc_SystemError,
"no locals when deleting %s",
PyObject_REPR(w));
1995-07-18 11:51:37 -03:00
break;
}
1997-04-29 15:18:01 -03:00
if ((err = PyDict_DelItem(x, w)) != 0)
format_exc_check_arg(PyExc_NameError,
NAME_ERROR_MSG ,w);
1990-11-18 13:27:39 -04:00
break;
case UNPACK_SEQUENCE:
1990-11-18 13:27:39 -04:00
v = POP();
if (PyTuple_Check(v)) {
if (PyTuple_Size(v) != oparg) {
PyErr_SetString(PyExc_ValueError,
"unpack tuple of wrong size");
why = WHY_EXCEPTION;
}
else {
for (; --oparg >= 0; ) {
w = PyTuple_GET_ITEM(v, oparg);
Py_INCREF(w);
PUSH(w);
}
1990-11-18 13:27:39 -04:00
}
}
else if (PyList_Check(v)) {
if (PyList_Size(v) != oparg) {
PyErr_SetString(PyExc_ValueError,
"unpack list of wrong size");
why = WHY_EXCEPTION;
}
else {
for (; --oparg >= 0; ) {
w = PyList_GET_ITEM(v, oparg);
Py_INCREF(w);
PUSH(w);
}
}
1990-11-18 13:27:39 -04:00
}
else if (unpack_iterable(v, oparg,
stack_pointer + oparg))
stack_pointer += oparg;
else {
if (PyErr_ExceptionMatches(PyExc_TypeError))
PyErr_SetString(PyExc_TypeError,
"unpack non-sequence");
why = WHY_EXCEPTION;
}
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case STORE_ATTR:
w = GETNAMEV(oparg);
1990-11-18 13:27:39 -04:00
v = POP();
u = POP();
1997-04-29 15:18:01 -03:00
err = PyObject_SetAttr(v, w, u); /* v.w = u */
Py_DECREF(v);
Py_DECREF(u);
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case DELETE_ATTR:
w = GETNAMEV(oparg);
1990-11-18 13:27:39 -04:00
v = POP();
err = PyObject_SetAttr(v, w, (PyObject *)NULL);
/* del v.w */
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
1990-11-18 13:27:39 -04:00
break;
case STORE_GLOBAL:
w = GETNAMEV(oparg);
v = POP();
1997-04-29 15:18:01 -03:00
err = PyDict_SetItem(f->f_globals, w, v);
Py_DECREF(v);
break;
case DELETE_GLOBAL:
w = GETNAMEV(oparg);
1997-04-29 15:18:01 -03:00
if ((err = PyDict_DelItem(f->f_globals, w)) != 0)
format_exc_check_arg(
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
PyExc_NameError, GLOBAL_NAME_ERROR_MSG, w);
break;
1990-11-18 13:27:39 -04:00
case LOAD_NAME:
w = GETNAMEV(oparg);
1995-07-18 11:51:37 -03:00
if ((x = f->f_locals) == NULL) {
PyErr_Format(PyExc_SystemError,
"no locals when loading %s",
PyObject_REPR(w));
1995-07-18 11:51:37 -03:00
break;
}
1997-04-29 15:18:01 -03:00
x = PyDict_GetItem(x, w);
1990-12-20 11:06:42 -04:00
if (x == NULL) {
1997-04-29 15:18:01 -03:00
x = PyDict_GetItem(f->f_globals, w);
if (x == NULL) {
1997-04-29 15:18:01 -03:00
x = PyDict_GetItem(f->f_builtins, w);
if (x == NULL) {
format_exc_check_arg(
PyExc_NameError,
NAME_ERROR_MSG ,w);
break;
}
}
}
1997-04-29 15:18:01 -03:00
Py_INCREF(x);
PUSH(x);
break;
case LOAD_GLOBAL:
w = GETNAMEV(oparg);
1997-04-29 15:18:01 -03:00
x = PyDict_GetItem(f->f_globals, w);
if (x == NULL) {
1997-04-29 15:18:01 -03:00
x = PyDict_GetItem(f->f_builtins, w);
if (x == NULL) {
format_exc_check_arg(
PyExc_NameError,
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
GLOBAL_NAME_ERROR_MSG ,w);
break;
}
1990-11-18 13:27:39 -04:00
}
1997-04-29 15:18:01 -03:00
Py_INCREF(x);
1990-12-20 11:06:42 -04:00
PUSH(x);
1990-11-18 13:27:39 -04:00
break;
case DELETE_FAST:
x = GETLOCAL(oparg);
if (x == NULL) {
format_exc_check_arg(
PyExc_UnboundLocalError,
UNBOUNDLOCAL_ERROR_MSG,
PyTuple_GetItem(co->co_varnames, oparg)
);
break;
}
1995-07-18 11:51:37 -03:00
SETLOCAL(oparg, NULL);
continue;
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
case LOAD_CLOSURE:
x = freevars[oparg];
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
Py_INCREF(x);
PUSH(x);
break;
case LOAD_DEREF:
x = freevars[oparg];
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
w = PyCell_Get(x);
if (w == NULL) {
if (oparg < f->f_ncells) {
v = PyTuple_GetItem(co->co_cellvars,
oparg);
format_exc_check_arg(
PyExc_UnboundLocalError,
UNBOUNDLOCAL_ERROR_MSG,
v);
} else {
v = PyTuple_GetItem(
co->co_freevars,
oparg - f->f_ncells);
format_exc_check_arg(
PyExc_NameError,
UNBOUNDFREE_ERROR_MSG,
v);
}
err = -1;
break;
}
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
PUSH(w);
break;
case STORE_DEREF:
w = POP();
x = freevars[oparg];
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
PyCell_Set(x, w);
Py_DECREF(w);
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
continue;
1990-11-18 13:27:39 -04:00
case BUILD_TUPLE:
1997-04-29 15:18:01 -03:00
x = PyTuple_New(oparg);
1990-12-20 11:06:42 -04:00
if (x != NULL) {
for (; --oparg >= 0;) {
1990-11-18 13:27:39 -04:00
w = POP();
1997-04-29 15:18:01 -03:00
PyTuple_SET_ITEM(x, oparg, w);
1990-11-18 13:27:39 -04:00
}
1990-12-20 11:06:42 -04:00
PUSH(x);
continue;
1990-11-18 13:27:39 -04:00
}
break;
1990-11-18 13:27:39 -04:00
case BUILD_LIST:
1997-04-29 15:18:01 -03:00
x = PyList_New(oparg);
1990-12-20 11:06:42 -04:00
if (x != NULL) {
for (; --oparg >= 0;) {
1990-11-18 13:27:39 -04:00
w = POP();
PyList_SET_ITEM(x, oparg, w);
1990-11-18 13:27:39 -04:00
}
1990-12-20 11:06:42 -04:00
PUSH(x);
continue;
1990-11-18 13:27:39 -04:00
}
break;
1990-11-18 13:27:39 -04:00
case BUILD_MAP:
1997-04-29 15:18:01 -03:00
x = PyDict_New();
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case LOAD_ATTR:
w = GETNAMEV(oparg);
1990-11-18 13:27:39 -04:00
v = POP();
1997-04-29 15:18:01 -03:00
x = PyObject_GetAttr(v, w);
Py_DECREF(v);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case COMPARE_OP:
w = POP();
v = POP();
if (PyInt_CheckExact(v) && PyInt_CheckExact(w)) {
/* INLINE: cmp(int, int) */
register long a, b;
register int res;
a = PyInt_AS_LONG(v);
b = PyInt_AS_LONG(w);
switch (oparg) {
case PyCmp_LT: res = a < b; break;
case PyCmp_LE: res = a <= b; break;
case PyCmp_EQ: res = a == b; break;
case PyCmp_NE: res = a != b; break;
case PyCmp_GT: res = a > b; break;
case PyCmp_GE: res = a >= b; break;
case PyCmp_IS: res = v == w; break;
case PyCmp_IS_NOT: res = v != w; break;
default: goto slow_compare;
}
x = res ? Py_True : Py_False;
Py_INCREF(x);
}
else {
slow_compare:
x = cmp_outcome(oparg, v, w);
}
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
1990-11-18 13:27:39 -04:00
case IMPORT_NAME:
w = GETNAMEV(oparg);
1997-04-29 15:18:01 -03:00
x = PyDict_GetItemString(f->f_builtins, "__import__");
if (x == NULL) {
1997-04-29 15:18:01 -03:00
PyErr_SetString(PyExc_ImportError,
"__import__ not found");
break;
}
u = POP();
1997-04-29 15:18:01 -03:00
w = Py_BuildValue("(OOOO)",
1995-07-18 11:51:37 -03:00
w,
f->f_globals,
f->f_locals == NULL ?
Py_None : f->f_locals,
1995-07-18 11:51:37 -03:00
u);
1997-04-29 15:18:01 -03:00
Py_DECREF(u);
if (w == NULL) {
x = NULL;
break;
}
1997-04-29 15:18:01 -03:00
x = PyEval_CallObject(x, w);
Py_DECREF(w);
PUSH(x);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
break;
case IMPORT_STAR:
v = POP();
1997-04-29 15:18:01 -03:00
PyFrame_FastToLocals(f);
1995-07-18 11:51:37 -03:00
if ((x = f->f_locals) == NULL) {
PyErr_SetString(PyExc_SystemError,
"no locals found during 'import *'");
1995-07-18 11:51:37 -03:00
break;
}
err = import_all_from(x, v);
1997-04-29 15:18:01 -03:00
PyFrame_LocalsToFast(f, 0);
Py_DECREF(v);
if (err == 0) continue;
1990-11-18 13:27:39 -04:00
break;
case IMPORT_FROM:
w = GETNAMEV(oparg);
v = TOP();
x = import_from(v, w);
PUSH(x);
if (x != NULL) continue;
break;
1990-11-18 13:27:39 -04:00
case JUMP_FORWARD:
1990-12-20 11:06:42 -04:00
JUMPBY(oparg);
continue;
1990-11-18 13:27:39 -04:00
case JUMP_IF_FALSE:
1997-04-29 15:18:01 -03:00
err = PyObject_IsTrue(TOP());
if (err > 0)
err = 0;
else if (err == 0)
1990-12-20 11:06:42 -04:00
JUMPBY(oparg);
else
break;
continue;
1990-11-18 13:27:39 -04:00
case JUMP_IF_TRUE:
1997-04-29 15:18:01 -03:00
err = PyObject_IsTrue(TOP());
if (err > 0) {
err = 0;
1990-12-20 11:06:42 -04:00
JUMPBY(oparg);
}
else if (err == 0)
;
else
break;
continue;
1990-11-18 13:27:39 -04:00
case JUMP_ABSOLUTE:
1990-12-20 11:06:42 -04:00
JUMPTO(oparg);
continue;
case GET_ITER:
/* before: [obj]; after [getiter(obj)] */
v = POP();
x = PyObject_GetIter(v);
Py_DECREF(v);
if (x != NULL) {
PUSH(x);
continue;
}
break;
case FOR_ITER:
/* before: [iter]; after: [iter, iter()] *or* [] */
v = TOP();
x = PyIter_Next(v);
if (x != NULL) {
PUSH(x);
continue;
}
if (!PyErr_Occurred()) {
/* iterator ended normally */
x = v = POP();
Py_DECREF(v);
JUMPBY(oparg);
continue;
}
break;
1990-11-18 13:27:39 -04:00
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 */
1990-11-18 13:27:39 -04:00
w = POP(); /* Loop index */
v = POP(); /* Sequence object */
1990-12-20 11:06:42 -04:00
u = loop_subscript(v, w);
if (u != NULL) {
1990-11-18 13:27:39 -04:00
PUSH(v);
1997-04-29 15:18:01 -03:00
x = PyInt_FromLong(PyInt_AsLong(w)+1);
1990-11-18 13:27:39 -04:00
PUSH(x);
1997-04-29 15:18:01 -03:00
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
PUSH(u);
if (x != NULL) continue;
1990-11-18 13:27:39 -04:00
}
else {
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
Py_DECREF(w);
1990-12-20 11:06:42 -04:00
/* A NULL can mean "s exhausted"
but also an error: */
1997-04-29 15:18:01 -03:00
if (PyErr_Occurred())
1990-12-20 11:06:42 -04:00
why = WHY_EXCEPTION;
else {
1990-12-20 11:06:42 -04:00
JUMPBY(oparg);
continue;
}
1990-11-18 13:27:39 -04:00
}
break;
1990-11-18 13:27:39 -04:00
case SETUP_LOOP:
case SETUP_EXCEPT:
1990-12-20 11:06:42 -04:00
case SETUP_FINALLY:
1997-04-29 15:18:01 -03:00
PyFrame_BlockSetup(f, opcode, INSTR_OFFSET() + oparg,
STACK_LEVEL());
continue;
case CALL_FUNCTION:
{
int na = oparg & 0xff;
int nk = (oparg>>8) & 0xff;
int n = na + 2 * nk;
PyObject **pfunc = stack_pointer - n - 1;
PyObject *func = *pfunc;
f->f_lasti = INSTR_OFFSET() - 3; /* For tracing */
/* Always dispatch PyCFunction first, because
these are presumed to be the most frequent
callable object.
*/
if (PyCFunction_Check(func)) {
int flags = PyCFunction_GET_FLAGS(func);
if (nk != 0 || (flags & METH_KEYWORDS))
x = do_call(func, &stack_pointer,
na, nk);
else if (flags == METH_VARARGS) {
PyObject *callargs;
callargs = load_args(&stack_pointer, na);
x = PyCFunction_Call(func, callargs, NULL);
Py_XDECREF(callargs);
} else
x = fast_cfunction(func,
&stack_pointer, na);
} else {
if (PyMethod_Check(func)
&& PyMethod_GET_SELF(func) != NULL) {
/* optimize access to bound methods */
PyObject *self = PyMethod_GET_SELF(func);
Py_INCREF(self);
func = PyMethod_GET_FUNCTION(func);
Py_INCREF(func);
Py_DECREF(*pfunc);
*pfunc = self;
na++;
n++;
} else
Py_INCREF(func);
if (PyFunction_Check(func)) {
x = fast_function(func, &stack_pointer,
n, na, nk);
} else {
x = do_call(func, &stack_pointer,
na, nk);
}
Py_DECREF(func);
}
while (stack_pointer > pfunc) {
w = POP();
Py_DECREF(w);
}
PUSH(x);
if (x != NULL)
continue;
break;
}
case CALL_FUNCTION_VAR:
case CALL_FUNCTION_KW:
case CALL_FUNCTION_VAR_KW:
{
int na = oparg & 0xff;
int nk = (oparg>>8) & 0xff;
int flags = (opcode - CALL_FUNCTION) & 3;
int n = na + 2 * nk;
PyObject **pfunc, *func;
if (flags & CALL_FLAG_VAR)
n++;
if (flags & CALL_FLAG_KW)
n++;
pfunc = stack_pointer - n - 1;
func = *pfunc;
f->f_lasti = INSTR_OFFSET() - 3; /* For tracing */
if (PyMethod_Check(func)
&& PyMethod_GET_SELF(func) != NULL) {
PyObject *self = PyMethod_GET_SELF(func);
Py_INCREF(self);
func = PyMethod_GET_FUNCTION(func);
Py_INCREF(func);
Py_DECREF(*pfunc);
*pfunc = self;
na++;
n++;
} else
Py_INCREF(func);
x = ext_do_call(func, &stack_pointer, flags, na, nk);
Py_DECREF(func);
while (stack_pointer > pfunc) {
w = POP();
Py_DECREF(w);
}
PUSH(x);
if (x != NULL)
continue;
break;
}
1995-07-18 11:51:37 -03:00
case MAKE_FUNCTION:
v = POP(); /* code object */
1997-04-29 15:18:01 -03:00
x = PyFunction_New(v, f->f_globals);
Py_DECREF(v);
1995-07-18 11:51:37 -03:00
/* XXX Maybe this should be a separate opcode? */
if (x != NULL && oparg > 0) {
1997-04-29 15:18:01 -03:00
v = PyTuple_New(oparg);
1995-07-18 11:51:37 -03:00
if (v == NULL) {
1997-04-29 15:18:01 -03:00
Py_DECREF(x);
1995-07-18 11:51:37 -03:00
x = NULL;
break;
}
while (--oparg >= 0) {
w = POP();
1997-04-29 15:18:01 -03:00
PyTuple_SET_ITEM(v, oparg, w);
1995-07-18 11:51:37 -03:00
}
err = PyFunction_SetDefaults(x, v);
1997-04-29 15:18:01 -03:00
Py_DECREF(v);
1995-07-18 11:51:37 -03:00
}
PUSH(x);
break;
1996-07-30 13:49:37 -03:00
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
case MAKE_CLOSURE:
{
int nfree;
v = POP(); /* code object */
x = PyFunction_New(v, f->f_globals);
nfree = PyCode_GetNumFree((PyCodeObject *)v);
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
Py_DECREF(v);
/* XXX Maybe this should be a separate opcode? */
if (x != NULL && nfree > 0) {
v = PyTuple_New(nfree);
if (v == NULL) {
Py_DECREF(x);
x = NULL;
break;
}
while (--nfree >= 0) {
w = POP();
PyTuple_SET_ITEM(v, nfree, w);
}
err = PyFunction_SetClosure(x, v);
Py_DECREF(v);
}
if (x != NULL && oparg > 0) {
v = PyTuple_New(oparg);
if (v == NULL) {
Py_DECREF(x);
x = NULL;
break;
}
while (--oparg >= 0) {
w = POP();
PyTuple_SET_ITEM(v, oparg, w);
}
err = PyFunction_SetDefaults(x, v);
Py_DECREF(v);
}
PUSH(x);
break;
}
1996-07-30 13:49:37 -03:00
case BUILD_SLICE:
if (oparg == 3)
w = POP();
else
w = NULL;
v = POP();
u = POP();
x = PySlice_New(u, v, w);
1997-04-29 15:18:01 -03:00
Py_DECREF(u);
Py_DECREF(v);
Py_XDECREF(w);
1996-07-30 13:49:37 -03:00
PUSH(x);
if (x != NULL) continue;
1996-07-30 13:49:37 -03:00
break;
case EXTENDED_ARG:
opcode = NEXTOP();
oparg = oparg<<16 | NEXTARG();
goto dispatch_opcode;
1996-07-30 13:49:37 -03:00
1990-11-18 13:27:39 -04:00
default:
1990-12-20 11:06:42 -04:00
fprintf(stderr,
"XXX lineno: %d, opcode: %d\n",
1992-01-11 22:29:51 -04:00
f->f_lineno, opcode);
1997-04-29 15:18:01 -03:00
PyErr_SetString(PyExc_SystemError, "unknown opcode");
1990-12-20 11:06:42 -04:00
why = WHY_EXCEPTION;
1990-11-18 13:27:39 -04:00
break;
#ifdef CASE_TOO_BIG
}
#endif
1990-12-20 11:06:42 -04:00
} /* switch */
on_error:
/* Quickly continue if no error occurred */
if (why == WHY_NOT) {
1995-07-18 11:51:37 -03:00
if (err == 0 && x != NULL) {
#ifdef CHECKEXC
/* This check is expensive! */
1997-04-29 15:18:01 -03:00
if (PyErr_Occurred())
1995-07-18 11:51:37 -03:00
fprintf(stderr,
"XXX undetected error\n");
else
#endif
continue; /* Normal, fast path */
}
why = WHY_EXCEPTION;
1997-04-29 15:18:01 -03:00
x = Py_None;
err = 0;
}
/* Double-check exception status */
if (why == WHY_EXCEPTION || why == WHY_RERAISE) {
1997-04-29 15:18:01 -03:00
if (!PyErr_Occurred()) {
PyErr_SetString(PyExc_SystemError,
"error return without exception set");
why = WHY_EXCEPTION;
}
}
#ifdef CHECKEXC
else {
/* This check is expensive! */
1997-04-29 15:18:01 -03:00
if (PyErr_Occurred()) {
1995-07-18 11:51:37 -03:00
fprintf(stderr,
"XXX undetected error (why=%d)\n",
why);
why = WHY_EXCEPTION;
}
}
#endif
/* Log traceback info if this is a real exception */
if (why == WHY_EXCEPTION) {
1992-01-11 22:29:51 -04:00
f->f_lasti = INSTR_OFFSET() - 1;
if (HAS_ARG(opcode))
1992-01-11 22:29:51 -04:00
f->f_lasti -= 2;
1997-04-29 15:18:01 -03:00
PyTraceBack_Here(f);
1992-01-11 22:29:51 -04:00
if (tstate->c_tracefunc != NULL)
call_exc_trace(tstate->c_tracefunc,
tstate->c_traceobj, 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 && why != WHY_YIELD && f->f_iblock > 0) {
1997-04-29 15:18:01 -03:00
PyTryBlock *b = PyFrame_BlockPop(f);
if (b->b_type == SETUP_LOOP && why == WHY_CONTINUE) {
/* For a continue inside a try block,
don't pop the block for the loop. */
PyFrame_BlockSetup(f, b->b_type, b->b_handler,
b->b_level);
why = WHY_NOT;
JUMPTO(PyInt_AS_LONG(retval));
Py_DECREF(retval);
break;
}
while (STACK_LEVEL() > b->b_level) {
v = POP();
1997-04-29 15:18:01 -03:00
Py_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) {
1997-04-29 15:18:01 -03:00
PyObject *exc, *val, *tb;
PyErr_Fetch(&exc, &val, &tb);
if (val == NULL) {
1997-04-29 15:18:01 -03:00
val = Py_None;
Py_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) {
PyErr_NormalizeException(
&exc, &val, &tb);
set_exc_info(tstate,
exc, val, tb);
}
if (tb == NULL) {
Py_INCREF(Py_None);
PUSH(Py_None);
} else
PUSH(tb);
PUSH(val);
PUSH(exc);
}
else {
if (why == WHY_RETURN ||
why == CONTINUE_LOOP)
PUSH(retval);
1997-04-29 15:18:01 -03:00
v = PyInt_FromLong((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 */
if (why != WHY_YIELD) {
/* Pop remaining stack entries -- but when yielding */
while (!EMPTY()) {
v = POP();
Py_XDECREF(v);
}
}
if (why != WHY_RETURN && why != WHY_YIELD)
1992-01-11 22:29:51 -04:00
retval = NULL;
if (tstate->use_tracing) {
if (tstate->c_tracefunc
&& (why == WHY_RETURN || why == WHY_YIELD)) {
if (call_trace(tstate->c_tracefunc,
tstate->c_traceobj, f,
PyTrace_RETURN, retval)) {
1997-04-29 15:18:01 -03:00
Py_XDECREF(retval);
1992-01-11 22:29:51 -04:00
retval = NULL;
why = WHY_EXCEPTION;
1992-01-11 22:29:51 -04:00
}
}
if (tstate->c_profilefunc) {
if (why == WHY_EXCEPTION)
call_trace_protected(tstate->c_profilefunc,
tstate->c_profileobj, f,
PyTrace_RETURN);
else if (call_trace(tstate->c_profilefunc,
tstate->c_profileobj, f,
PyTrace_RETURN, retval)) {
Py_XDECREF(retval);
retval = NULL;
why = WHY_EXCEPTION;
}
}
1992-01-11 22:29:51 -04:00
}
reset_exc_info(tstate);
/* pop frame */
--tstate->recursion_depth;
tstate->frame = f->f_back;
return retval;
}
2001-08-02 01:15:00 -03:00
PyObject *
PyEval_EvalCodeEx(PyCodeObject *co, PyObject *globals, PyObject *locals,
PyObject **args, int argcount, PyObject **kws, int kwcount,
PyObject **defs, int defcount, PyObject *closure)
{
register PyFrameObject *f;
register PyObject *retval = NULL;
register PyObject **fastlocals, **freevars;
PyThreadState *tstate = PyThreadState_GET();
PyObject *x, *u;
if (globals == NULL) {
PyErr_SetString(PyExc_SystemError,
"PyEval_EvalCodeEx: NULL globals");
return NULL;
}
1995-07-18 11:51:37 -03:00
f = PyFrame_New(tstate, /*back*/
co, /*code*/
globals, locals);
if (f == NULL)
return NULL;
fastlocals = f->f_localsplus;
freevars = f->f_localsplus + f->f_nlocals;
if (co->co_argcount > 0 ||
co->co_flags & (CO_VARARGS | CO_VARKEYWORDS)) {
int i;
int n = argcount;
PyObject *kwdict = NULL;
if (co->co_flags & CO_VARKEYWORDS) {
kwdict = PyDict_New();
if (kwdict == NULL)
goto fail;
i = co->co_argcount;
if (co->co_flags & CO_VARARGS)
i++;
SETLOCAL(i, kwdict);
}
if (argcount > co->co_argcount) {
if (!(co->co_flags & CO_VARARGS)) {
PyErr_Format(PyExc_TypeError,
"%.200s() takes %s %d "
"%sargument%s (%d given)",
PyString_AsString(co->co_name),
defcount ? "at most" : "exactly",
co->co_argcount,
kwcount ? "non-keyword " : "",
co->co_argcount == 1 ? "" : "s",
argcount);
goto fail;
}
n = co->co_argcount;
}
for (i = 0; i < n; i++) {
x = args[i];
Py_INCREF(x);
SETLOCAL(i, x);
}
if (co->co_flags & CO_VARARGS) {
u = PyTuple_New(argcount - n);
if (u == NULL)
goto fail;
SETLOCAL(co->co_argcount, u);
for (i = n; i < argcount; i++) {
x = args[i];
Py_INCREF(x);
PyTuple_SET_ITEM(u, i-n, x);
}
}
for (i = 0; i < kwcount; i++) {
PyObject *keyword = kws[2*i];
PyObject *value = kws[2*i + 1];
int j;
if (keyword == NULL || !PyString_Check(keyword)) {
PyErr_Format(PyExc_TypeError,
"%.200s() keywords must be strings",
PyString_AsString(co->co_name));
goto fail;
}
/* XXX slow -- speed up using dictionary? */
for (j = 0; j < co->co_argcount; j++) {
PyObject *nm = PyTuple_GET_ITEM(
co->co_varnames, j);
int cmp = PyObject_RichCompareBool(
keyword, nm, Py_EQ);
if (cmp > 0)
break;
else if (cmp < 0)
goto fail;
}
/* Check errors from Compare */
if (PyErr_Occurred())
goto fail;
if (j >= co->co_argcount) {
if (kwdict == NULL) {
PyErr_Format(PyExc_TypeError,
"%.200s() got an unexpected "
"keyword argument '%.400s'",
PyString_AsString(co->co_name),
PyString_AsString(keyword));
goto fail;
}
PyDict_SetItem(kwdict, keyword, value);
}
else {
if (GETLOCAL(j) != NULL) {
PyErr_Format(PyExc_TypeError,
"%.200s() got multiple "
"values for keyword "
"argument '%.400s'",
PyString_AsString(co->co_name),
PyString_AsString(keyword));
goto fail;
}
Py_INCREF(value);
SETLOCAL(j, value);
}
}
if (argcount < co->co_argcount) {
int m = co->co_argcount - defcount;
for (i = argcount; i < m; i++) {
if (GETLOCAL(i) == NULL) {
PyErr_Format(PyExc_TypeError,
"%.200s() takes %s %d "
"%sargument%s (%d given)",
PyString_AsString(co->co_name),
((co->co_flags & CO_VARARGS) ||
defcount) ? "at least"
: "exactly",
m, kwcount ? "non-keyword " : "",
m == 1 ? "" : "s", i);
goto fail;
}
}
if (n > m)
i = n - m;
else
i = 0;
for (; i < defcount; i++) {
if (GETLOCAL(m+i) == NULL) {
PyObject *def = defs[i];
Py_INCREF(def);
SETLOCAL(m+i, def);
}
}
}
}
else {
if (argcount > 0 || kwcount > 0) {
PyErr_Format(PyExc_TypeError,
"%.200s() takes no arguments (%d given)",
PyString_AsString(co->co_name),
argcount + kwcount);
goto fail;
}
}
/* Allocate and initialize storage for cell vars, and copy free
vars into frame. This isn't too efficient right now. */
if (f->f_ncells) {
int i = 0, j = 0, nargs, found;
char *cellname, *argname;
PyObject *c;
nargs = co->co_argcount;
if (co->co_flags & CO_VARARGS)
nargs++;
if (co->co_flags & CO_VARKEYWORDS)
nargs++;
/* Check for cells that shadow args */
for (i = 0; i < f->f_ncells && j < nargs; ++i) {
cellname = PyString_AS_STRING(
PyTuple_GET_ITEM(co->co_cellvars, i));
found = 0;
while (j < nargs) {
argname = PyString_AS_STRING(
PyTuple_GET_ITEM(co->co_varnames, j));
if (strcmp(cellname, argname) == 0) {
c = PyCell_New(GETLOCAL(j));
if (c == NULL)
goto fail;
GETLOCAL(f->f_nlocals + i) = c;
found = 1;
break;
}
j++;
}
if (found == 0) {
c = PyCell_New(NULL);
if (c == NULL)
goto fail;
SETLOCAL(f->f_nlocals + i, c);
}
}
/* Initialize any that are left */
while (i < f->f_ncells) {
c = PyCell_New(NULL);
if (c == NULL)
goto fail;
SETLOCAL(f->f_nlocals + i, c);
i++;
}
}
if (f->f_nfreevars) {
int i;
for (i = 0; i < f->f_nfreevars; ++i) {
PyObject *o = PyTuple_GET_ITEM(closure, i);
Py_INCREF(o);
freevars[f->f_ncells + i] = o;
}
}
if (co->co_flags & CO_GENERATOR) {
/* Don't need to keep the reference to f_back, it will be set
* when the generator is resumed. */
Py_XDECREF(f->f_back);
f->f_back = NULL;
/* Create a new generator that owns the ready to run frame
* and return that as the value. */
return gen_new(f);
}
retval = eval_frame(f);
fail: /* Jump here from prelude on failure */
/* decref'ing the frame can cause __del__ methods to get invoked,
which can call back into Python. While we're done with the
current Python frame (f), the associated C stack is still in use,
so recursion_depth must be boosted for the duration.
*/
assert(tstate != NULL);
++tstate->recursion_depth;
Py_DECREF(f);
--tstate->recursion_depth;
1992-01-11 22:29:51 -04:00
return retval;
}
static void
set_exc_info(PyThreadState *tstate,
PyObject *type, PyObject *value, PyObject *tb)
{
PyFrameObject *frame;
PyObject *tmp_type, *tmp_value, *tmp_tb;
frame = tstate->frame;
if (frame->f_exc_type == NULL) {
/* This frame didn't catch an exception before */
/* Save previous exception of this thread in this frame */
if (tstate->exc_type == NULL) {
Py_INCREF(Py_None);
tstate->exc_type = Py_None;
}
tmp_type = frame->f_exc_type;
tmp_value = frame->f_exc_value;
tmp_tb = frame->f_exc_traceback;
Py_XINCREF(tstate->exc_type);
Py_XINCREF(tstate->exc_value);
Py_XINCREF(tstate->exc_traceback);
frame->f_exc_type = tstate->exc_type;
frame->f_exc_value = tstate->exc_value;
frame->f_exc_traceback = tstate->exc_traceback;
Py_XDECREF(tmp_type);
Py_XDECREF(tmp_value);
Py_XDECREF(tmp_tb);
}
/* Set new exception for this thread */
tmp_type = tstate->exc_type;
tmp_value = tstate->exc_value;
tmp_tb = tstate->exc_traceback;
Py_XINCREF(type);
Py_XINCREF(value);
Py_XINCREF(tb);
tstate->exc_type = type;
tstate->exc_value = value;
tstate->exc_traceback = tb;
Py_XDECREF(tmp_type);
Py_XDECREF(tmp_value);
Py_XDECREF(tmp_tb);
/* For b/w compatibility */
PySys_SetObject("exc_type", type);
PySys_SetObject("exc_value", value);
PySys_SetObject("exc_traceback", tb);
}
static void
reset_exc_info(PyThreadState *tstate)
{
PyFrameObject *frame;
PyObject *tmp_type, *tmp_value, *tmp_tb;
frame = tstate->frame;
if (frame->f_exc_type != NULL) {
/* This frame caught an exception */
tmp_type = tstate->exc_type;
tmp_value = tstate->exc_value;
tmp_tb = tstate->exc_traceback;
Py_XINCREF(frame->f_exc_type);
Py_XINCREF(frame->f_exc_value);
Py_XINCREF(frame->f_exc_traceback);
tstate->exc_type = frame->f_exc_type;
tstate->exc_value = frame->f_exc_value;
tstate->exc_traceback = frame->f_exc_traceback;
Py_XDECREF(tmp_type);
Py_XDECREF(tmp_value);
Py_XDECREF(tmp_tb);
/* For b/w compatibility */
PySys_SetObject("exc_type", frame->f_exc_type);
PySys_SetObject("exc_value", frame->f_exc_value);
PySys_SetObject("exc_traceback", frame->f_exc_traceback);
}
tmp_type = frame->f_exc_type;
tmp_value = frame->f_exc_value;
tmp_tb = frame->f_exc_traceback;
frame->f_exc_type = NULL;
frame->f_exc_value = NULL;
frame->f_exc_traceback = NULL;
Py_XDECREF(tmp_type);
Py_XDECREF(tmp_value);
Py_XDECREF(tmp_tb);
}
/* Logic for the raise statement (too complicated for inlining).
This *consumes* a reference count to each of its arguments. */
static enum why_code
do_raise(PyObject *type, PyObject *value, PyObject *tb)
{
1998-04-09 18:39:57 -03:00
if (type == NULL) {
/* Reraise */
PyThreadState *tstate = PyThreadState_Get();
type = tstate->exc_type == NULL ? Py_None : tstate->exc_type;
value = tstate->exc_value;
tb = tstate->exc_traceback;
Py_XINCREF(type);
Py_XINCREF(value);
Py_XINCREF(tb);
}
/* We support the following forms of raise:
raise <class>, <classinstance>
raise <class>, <argument tuple>
raise <class>, None
raise <class>, <argument>
raise <classinstance>, None
raise <string>, <object>
raise <string>, None
An omitted second argument is the same as None.
In addition, raise <tuple>, <anything> is the same as
raising the tuple's first item (and it better have one!);
this rule is applied recursively.
Finally, an optional third argument can be supplied, which
gives the traceback to be substituted (useful when
re-raising an exception after examining it). */
/* First, check the traceback argument, replacing None with
NULL. */
1997-04-29 15:18:01 -03:00
if (tb == Py_None) {
Py_DECREF(tb);
tb = NULL;
}
else if (tb != NULL && !PyTraceBack_Check(tb)) {
1997-04-29 15:18:01 -03:00
PyErr_SetString(PyExc_TypeError,
"raise: arg 3 must be a traceback or None");
goto raise_error;
}
/* Next, replace a missing value with None */
if (value == NULL) {
1997-04-29 15:18:01 -03:00
value = Py_None;
Py_INCREF(value);
}
/* Next, repeatedly, replace a tuple exception with its first item */
1997-04-29 15:18:01 -03:00
while (PyTuple_Check(type) && PyTuple_Size(type) > 0) {
PyObject *tmp = type;
type = PyTuple_GET_ITEM(type, 0);
Py_INCREF(type);
Py_DECREF(tmp);
}
if (PyString_Check(type))
;
else if (PyClass_Check(type))
PyErr_NormalizeException(&type, &value, &tb);
1997-04-29 15:18:01 -03:00
else if (PyInstance_Check(type)) {
/* Raising an instance. The value should be a dummy. */
1997-04-29 15:18:01 -03:00
if (value != Py_None) {
PyErr_SetString(PyExc_TypeError,
"instance exception may not have a separate value");
goto raise_error;
}
else {
/* Normalize to raise <class>, <instance> */
1997-04-29 15:18:01 -03:00
Py_DECREF(value);
value = type;
1997-04-29 15:18:01 -03:00
type = (PyObject*) ((PyInstanceObject*)type)->in_class;
Py_INCREF(type);
}
}
else {
/* Not something you can raise. You get an exception
anyway, just not what you specified :-) */
PyErr_Format(PyExc_TypeError,
"exceptions must be strings, classes, or "
"instances, not %s", type->ob_type->tp_name);
goto raise_error;
}
1997-04-29 15:18:01 -03:00
PyErr_Restore(type, value, tb);
if (tb == NULL)
return WHY_EXCEPTION;
else
return WHY_RERAISE;
raise_error:
1997-04-29 15:18:01 -03:00
Py_XDECREF(value);
Py_XDECREF(type);
Py_XDECREF(tb);
return WHY_EXCEPTION;
}
/* Iterate v argcnt times and store the results on the stack (via decreasing
sp). Return 1 for success, 0 if error. */
static int
unpack_iterable(PyObject *v, int argcnt, PyObject **sp)
{
int i = 0;
PyObject *it; /* iter(v) */
PyObject *w;
assert(v != NULL);
it = PyObject_GetIter(v);
if (it == NULL)
goto Error;
for (; i < argcnt; i++) {
w = PyIter_Next(it);
if (w == NULL) {
/* Iterator done, via error or exhaustion. */
if (!PyErr_Occurred()) {
PyErr_Format(PyExc_ValueError,
"need more than %d value%s to unpack",
i, i == 1 ? "" : "s");
}
goto Error;
}
*--sp = w;
}
/* We better have exhausted the iterator now. */
w = PyIter_Next(it);
if (w == NULL) {
if (PyErr_Occurred())
goto Error;
Py_DECREF(it);
return 1;
}
Py_DECREF(w);
PyErr_SetString(PyExc_ValueError, "too many values to unpack");
/* fall through */
Error:
for (; i > 0; i--, sp++)
Py_DECREF(*sp);
Py_XDECREF(it);
return 0;
}
1992-01-11 22:29:51 -04:00
#ifdef LLTRACE
static int
prtrace(PyObject *v, char *str)
{
printf("%s ", str);
1997-04-29 15:18:01 -03:00
if (PyObject_Print(v, stdout, 0) != 0)
PyErr_Clear(); /* Don't know what else to do */
printf("\n");
return 1;
}
#endif
static void
call_exc_trace(Py_tracefunc func, PyObject *self, PyFrameObject *f)
{
1997-04-29 15:18:01 -03:00
PyObject *type, *value, *traceback, *arg;
int err;
1997-04-29 15:18:01 -03:00
PyErr_Fetch(&type, &value, &traceback);
if (value == NULL) {
1997-04-29 15:18:01 -03:00
value = Py_None;
Py_INCREF(value);
}
1997-04-29 15:18:01 -03:00
arg = Py_BuildValue("(OOO)", type, value, traceback);
if (arg == NULL) {
1997-04-29 15:18:01 -03:00
PyErr_Restore(type, value, traceback);
return;
}
err = call_trace(func, self, f, PyTrace_EXCEPTION, arg);
1997-04-29 15:18:01 -03:00
Py_DECREF(arg);
if (err == 0)
1997-04-29 15:18:01 -03:00
PyErr_Restore(type, value, traceback);
else {
1997-04-29 15:18:01 -03:00
Py_XDECREF(type);
Py_XDECREF(value);
Py_XDECREF(traceback);
}
}
static void
call_trace_protected(Py_tracefunc func, PyObject *obj, PyFrameObject *frame,
int what)
{
PyObject *type, *value, *traceback;
int err;
PyErr_Fetch(&type, &value, &traceback);
err = call_trace(func, obj, frame, what, NULL);
if (err == 0)
PyErr_Restore(type, value, traceback);
else {
Py_XDECREF(type);
Py_XDECREF(value);
Py_XDECREF(traceback);
}
}
static int
call_trace(Py_tracefunc func, PyObject *obj, PyFrameObject *frame,
int what, PyObject *arg)
1992-01-11 22:29:51 -04:00
{
register PyThreadState *tstate = frame->f_tstate;
int result;
if (tstate->tracing)
return 0;
tstate->tracing++;
tstate->use_tracing = 0;
result = func(obj, frame, what, arg);
tstate->use_tracing = ((tstate->c_tracefunc != NULL)
|| (tstate->c_profilefunc != NULL));
tstate->tracing--;
return result;
1992-01-11 22:29:51 -04:00
}
void
PyEval_SetProfile(Py_tracefunc func, PyObject *arg)
{
PyThreadState *tstate = PyThreadState_Get();
PyObject *temp = tstate->c_profileobj;
Py_XINCREF(arg);
tstate->c_profilefunc = NULL;
tstate->c_profileobj = NULL;
tstate->use_tracing = tstate->c_tracefunc != NULL;
Py_XDECREF(temp);
tstate->c_profilefunc = func;
tstate->c_profileobj = arg;
tstate->use_tracing = (func != NULL) || (tstate->c_tracefunc != NULL);
}
void
PyEval_SetTrace(Py_tracefunc func, PyObject *arg)
{
PyThreadState *tstate = PyThreadState_Get();
PyObject *temp = tstate->c_traceobj;
Py_XINCREF(arg);
tstate->c_tracefunc = NULL;
tstate->c_traceobj = NULL;
tstate->use_tracing = tstate->c_profilefunc != NULL;
Py_XDECREF(temp);
tstate->c_tracefunc = func;
tstate->c_traceobj = arg;
tstate->use_tracing = ((func != NULL)
|| (tstate->c_profilefunc != NULL));
}
1997-04-29 15:18:01 -03:00
PyObject *
PyEval_GetBuiltins(void)
{
PyThreadState *tstate = PyThreadState_Get();
PyFrameObject *current_frame = tstate->frame;
if (current_frame == NULL)
return tstate->interp->builtins;
else
return current_frame->f_builtins;
}
1997-04-29 15:18:01 -03:00
PyObject *
PyEval_GetLocals(void)
{
PyFrameObject *current_frame = PyThreadState_Get()->frame;
if (current_frame == NULL)
return NULL;
1997-04-29 15:18:01 -03:00
PyFrame_FastToLocals(current_frame);
return current_frame->f_locals;
}
1997-04-29 15:18:01 -03:00
PyObject *
PyEval_GetGlobals(void)
{
PyFrameObject *current_frame = PyThreadState_Get()->frame;
if (current_frame == NULL)
return NULL;
else
return current_frame->f_globals;
}
1997-04-29 15:18:01 -03:00
PyObject *
PyEval_GetFrame(void)
{
PyFrameObject *current_frame = PyThreadState_Get()->frame;
1997-04-29 15:18:01 -03:00
return (PyObject *)current_frame;
}
int
PyEval_GetRestricted(void)
{
PyFrameObject *current_frame = PyThreadState_Get()->frame;
return current_frame == NULL ? 0 : current_frame->f_restricted;
}
int
PyEval_MergeCompilerFlags(PyCompilerFlags *cf)
{
PyFrameObject *current_frame = PyThreadState_Get()->frame;
int result = 0;
if (current_frame != NULL) {
const int codeflags = current_frame->f_code->co_flags;
const int compilerflags = codeflags & PyCF_MASK;
if (compilerflags) {
result = 1;
cf->cf_flags |= compilerflags;
}
#if 0 /* future keyword */
if (codeflags & CO_GENERATOR_ALLOWED) {
result = 1;
cf->cf_flags |= CO_GENERATOR_ALLOWED;
}
#endif
}
return result;
}
int
Py_FlushLine(void)
{
1997-04-29 15:18:01 -03:00
PyObject *f = PySys_GetObject("stdout");
if (f == NULL)
return 0;
if (!PyFile_SoftSpace(f, 0))
return 0;
return PyFile_WriteString("\n", f);
}
1995-07-18 11:51:37 -03:00
/* External interface to call any callable object.
The arg must be a tuple or NULL. */
#undef PyEval_CallObject
/* for backward compatibility: export this interface */
1997-04-29 15:18:01 -03:00
PyObject *
PyEval_CallObject(PyObject *func, PyObject *arg)
{
1997-04-29 15:18:01 -03:00
return PyEval_CallObjectWithKeywords(func, arg, (PyObject *)NULL);
1995-07-18 11:51:37 -03:00
}
#define PyEval_CallObject(func,arg) \
PyEval_CallObjectWithKeywords(func, arg, (PyObject *)NULL)
1995-07-18 11:51:37 -03:00
1997-04-29 15:18:01 -03:00
PyObject *
PyEval_CallObjectWithKeywords(PyObject *func, PyObject *arg, PyObject *kw)
1995-07-18 11:51:37 -03:00
{
PyObject *result;
1995-07-18 11:51:37 -03:00
if (arg == NULL)
1997-04-29 15:18:01 -03:00
arg = PyTuple_New(0);
else if (!PyTuple_Check(arg)) {
PyErr_SetString(PyExc_TypeError,
"argument list must be a tuple");
1995-07-18 11:51:37 -03:00
return NULL;
}
else
1997-04-29 15:18:01 -03:00
Py_INCREF(arg);
1995-07-18 11:51:37 -03:00
1997-04-29 15:18:01 -03:00
if (kw != NULL && !PyDict_Check(kw)) {
PyErr_SetString(PyExc_TypeError,
"keyword list must be a dictionary");
Py_DECREF(arg);
1995-08-04 01:14:47 -03:00
return NULL;
}
2001-08-02 01:15:00 -03:00
result = PyObject_Call(func, arg, kw);
1997-04-29 15:18:01 -03:00
Py_DECREF(arg);
return result;
}
2001-08-02 01:15:00 -03:00
char *
PyEval_GetFuncName(PyObject *func)
{
if (PyMethod_Check(func))
2001-08-02 01:15:00 -03:00
return PyEval_GetFuncName(PyMethod_GET_FUNCTION(func));
else if (PyFunction_Check(func))
return PyString_AsString(((PyFunctionObject*)func)->func_name);
else if (PyCFunction_Check(func))
return ((PyCFunctionObject*)func)->m_ml->ml_name;
else if (PyClass_Check(func))
return PyString_AsString(((PyClassObject*)func)->cl_name);
else if (PyInstance_Check(func)) {
return PyString_AsString(
((PyInstanceObject*)func)->in_class->cl_name);
} else {
return func->ob_type->tp_name;
}
}
2001-08-02 01:15:00 -03:00
char *
PyEval_GetFuncDesc(PyObject *func)
{
if (PyMethod_Check(func))
return "()";
else if (PyFunction_Check(func))
return "()";
else if (PyCFunction_Check(func))
return "()";
else if (PyClass_Check(func))
return " constructor";
else if (PyInstance_Check(func)) {
return " instance";
} else {
return " object";
}
}
#define EXT_POP(STACK_POINTER) (*--(STACK_POINTER))
/* The two fast_xxx() functions optimize calls for which no argument
tuple is necessary; the objects are passed directly from the stack.
fast_cfunction() is called for METH_OLDARGS functions.
fast_function() is for functions with no special argument handling.
*/
static PyObject *
fast_cfunction(PyObject *func, PyObject ***pp_stack, int na)
{
PyCFunction meth = PyCFunction_GET_FUNCTION(func);
PyObject *self = PyCFunction_GET_SELF(func);
int flags = PyCFunction_GET_FLAGS(func);
switch (flags) {
case METH_OLDARGS:
if (na == 0)
return (*meth)(self, NULL);
else if (na == 1) {
PyObject *arg = EXT_POP(*pp_stack);
PyObject *result = (*meth)(self, arg);
Py_DECREF(arg);
return result;
} else {
PyObject *args = load_args(pp_stack, na);
PyObject *result = (*meth)(self, args);
Py_DECREF(args);
return result;
}
case METH_NOARGS:
if (na == 0)
return (*meth)(self, NULL);
PyErr_Format(PyExc_TypeError,
"%.200s() takes no arguments (%d given)",
((PyCFunctionObject*)func)->m_ml->ml_name, na);
return NULL;
case METH_O:
if (na == 1) {
PyObject *arg = EXT_POP(*pp_stack);
PyObject *result = (*meth)(self, arg);
Py_DECREF(arg);
return result;
}
PyErr_Format(PyExc_TypeError,
"%.200s() takes exactly one argument (%d given)",
((PyCFunctionObject*)func)->m_ml->ml_name, na);
return NULL;
default:
fprintf(stderr, "%.200s() flags = %d\n",
((PyCFunctionObject*)func)->m_ml->ml_name, flags);
PyErr_BadInternalCall();
return NULL;
}
}
static PyObject *
fast_function(PyObject *func, PyObject ***pp_stack, int n, int na, int nk)
{
PyObject *co = PyFunction_GET_CODE(func);
PyObject *globals = PyFunction_GET_GLOBALS(func);
PyObject *argdefs = PyFunction_GET_DEFAULTS(func);
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
PyObject *closure = PyFunction_GET_CLOSURE(func);
PyObject **d = NULL;
int nd = 0;
if (argdefs != NULL) {
d = &PyTuple_GET_ITEM(argdefs, 0);
nd = ((PyTupleObject *)argdefs)->ob_size;
}
2001-08-02 01:15:00 -03:00
return PyEval_EvalCodeEx((PyCodeObject *)co, globals,
(PyObject *)NULL, (*pp_stack)-n, na,
PEP 227 implementation The majority of the changes are in the compiler. The mainloop changes primarily to implement the new opcodes and to pass a function's closure to eval_code2(). Frames and functions got new slots to hold the closure. Include/compile.h Add co_freevars and co_cellvars slots to code objects. Update PyCode_New() to take freevars and cellvars as arguments Include/funcobject.h Add func_closure slot to function objects. Add GetClosure()/SetClosure() functions (and corresponding macros) for getting at the closure. Include/frameobject.h PyFrame_New() now takes a closure. Include/opcode.h Add four new opcodes: MAKE_CLOSURE, LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF. Remove comment about old requirement for opcodes to fit in 7 bits. compile.c Implement changes to code objects for co_freevars and co_cellvars. Modify symbol table to use st_cur_name (string object for the name of the current scope) and st_cur_children (list of nested blocks). Also define st_nested, which might more properly be called st_cur_nested. Add several DEF_XXX flags to track def-use information for free variables. New or modified functions of note: com_make_closure(struct compiling *, PyCodeObject *) Emit LOAD_CLOSURE opcodes as needed to pass cells for free variables into nested scope. com_addop_varname(struct compiling *, int, char *) Emits opcodes for LOAD_DEREF and STORE_DEREF. get_ref_type(struct compiling *, char *name) Return NAME_CLOSURE if ref type is FREE or CELL symtable_load_symbols(struct compiling *) Decides what variables are cell or free based on def-use info. Can now raise SyntaxError if nested scopes are mixed with exec or from blah import *. make_scope_info(PyObject *, PyObject *, int, int) Helper functions for symtable scope stack. symtable_update_free_vars(struct symtable *) After a code block has been analyzed, it must check each of its children for free variables that are not defined in the block. If a variable is free in a child and not defined in the parent, then it is defined by block the enclosing the current one or it is a global. This does the right logic. symtable_add_use() is now a macro for symtable_add_def() symtable_assign(struct symtable *, node *) Use goto instead of for (;;) Fixed bug in symtable where name of keyword argument in function call was treated as assignment in the scope of the call site. Ex: def f(): g(a=2) # a was considered a local of f ceval.c eval_code2() now take one more argument, a closure. Implement LOAD_CLOSURE, LOAD_DEREF, STORE_DEREF, MAKE_CLOSURE> Also: When name error occurs for global variable, report that the name was global in the error mesage. Objects/frameobject.c Initialize f_closure to be a tuple containing space for cellvars and freevars. f_closure is NULL if neither are present. Objects/funcobject.c Add support for func_closure. Python/import.c Change the magic number. Python/marshal.c Track changes to code objects.
2001-01-25 16:06:59 -04:00
(*pp_stack)-2*nk, nk, d, nd,
closure);
}
static PyObject *
update_keyword_args(PyObject *orig_kwdict, int nk, PyObject ***pp_stack,
PyObject *func)
{
PyObject *kwdict = NULL;
if (orig_kwdict == NULL)
kwdict = PyDict_New();
else {
kwdict = PyDict_Copy(orig_kwdict);
Py_DECREF(orig_kwdict);
}
if (kwdict == NULL)
return NULL;
while (--nk >= 0) {
int err;
PyObject *value = EXT_POP(*pp_stack);
PyObject *key = EXT_POP(*pp_stack);
if (PyDict_GetItem(kwdict, key) != NULL) {
PyErr_Format(PyExc_TypeError,
"%.200s%s got multiple values "
"for keyword argument '%.200s'",
2001-08-02 01:15:00 -03:00
PyEval_GetFuncName(func),
PyEval_GetFuncDesc(func),
PyString_AsString(key));
Py_DECREF(key);
Py_DECREF(value);
Py_DECREF(kwdict);
return NULL;
}
err = PyDict_SetItem(kwdict, key, value);
Py_DECREF(key);
Py_DECREF(value);
if (err) {
Py_DECREF(kwdict);
return NULL;
}
}
return kwdict;
}
static PyObject *
update_star_args(int nstack, int nstar, PyObject *stararg,
PyObject ***pp_stack)
{
PyObject *callargs, *w;
callargs = PyTuple_New(nstack + nstar);
if (callargs == NULL) {
return NULL;
}
if (nstar) {
int i;
for (i = 0; i < nstar; i++) {
PyObject *a = PyTuple_GET_ITEM(stararg, i);
Py_INCREF(a);
PyTuple_SET_ITEM(callargs, nstack + i, a);
}
}
while (--nstack >= 0) {
w = EXT_POP(*pp_stack);
PyTuple_SET_ITEM(callargs, nstack, w);
}
return callargs;
}
static PyObject *
load_args(PyObject ***pp_stack, int na)
{
PyObject *args = PyTuple_New(na);
PyObject *w;
if (args == NULL)
return NULL;
while (--na >= 0) {
w = EXT_POP(*pp_stack);
PyTuple_SET_ITEM(args, na, w);
}
return args;
}
static PyObject *
do_call(PyObject *func, PyObject ***pp_stack, int na, int nk)
{
PyObject *callargs = NULL;
PyObject *kwdict = NULL;
PyObject *result = NULL;
if (nk > 0) {
kwdict = update_keyword_args(NULL, nk, pp_stack, func);
if (kwdict == NULL)
goto call_fail;
}
callargs = load_args(pp_stack, na);
if (callargs == NULL)
goto call_fail;
2001-08-02 01:15:00 -03:00
result = PyObject_Call(func, callargs, kwdict);
call_fail:
Py_XDECREF(callargs);
Py_XDECREF(kwdict);
return result;
}
static PyObject *
ext_do_call(PyObject *func, PyObject ***pp_stack, int flags, int na, int nk)
{
int nstar = 0;
PyObject *callargs = NULL;
PyObject *stararg = NULL;
PyObject *kwdict = NULL;
PyObject *result = NULL;
if (flags & CALL_FLAG_KW) {
kwdict = EXT_POP(*pp_stack);
if (!(kwdict && PyDict_Check(kwdict))) {
PyErr_Format(PyExc_TypeError,
"%s%s argument after ** "
"must be a dictionary",
2001-08-02 01:15:00 -03:00
PyEval_GetFuncName(func),
PyEval_GetFuncDesc(func));
goto ext_call_fail;
}
}
if (flags & CALL_FLAG_VAR) {
stararg = EXT_POP(*pp_stack);
if (!PyTuple_Check(stararg)) {
PyObject *t = NULL;
t = PySequence_Tuple(stararg);
if (t == NULL) {
if (PyErr_ExceptionMatches(PyExc_TypeError)) {
PyErr_Format(PyExc_TypeError,
"%s%s argument after * "
"must be a sequence",
2001-08-02 01:15:00 -03:00
PyEval_GetFuncName(func),
PyEval_GetFuncDesc(func));
}
goto ext_call_fail;
}
Py_DECREF(stararg);
stararg = t;
}
nstar = PyTuple_GET_SIZE(stararg);
}
if (nk > 0) {
kwdict = update_keyword_args(kwdict, nk, pp_stack, func);
if (kwdict == NULL)
goto ext_call_fail;
}
callargs = update_star_args(na, nstar, stararg, pp_stack);
if (callargs == NULL)
goto ext_call_fail;
2001-08-02 01:15:00 -03:00
result = PyObject_Call(func, callargs, kwdict);
ext_call_fail:
Py_XDECREF(callargs);
Py_XDECREF(kwdict);
Py_XDECREF(stararg);
return result;
}
#define SLICE_ERROR_MSG \
"standard sequence type does not support step size other than one"
1997-04-29 15:18:01 -03:00
static PyObject *
loop_subscript(PyObject *v, PyObject *w)
{
1997-04-29 15:18:01 -03:00
PySequenceMethods *sq = v->ob_type->tp_as_sequence;
int i;
if (sq == NULL || sq->sq_item == NULL) {
1997-04-29 15:18:01 -03:00
PyErr_SetString(PyExc_TypeError, "loop over non-sequence");
return NULL;
}
1997-04-29 15:18:01 -03:00
i = PyInt_AsLong(w);
v = (*sq->sq_item)(v, i);
if (v)
return v;
if (PyErr_ExceptionMatches(PyExc_IndexError))
1997-04-29 15:18:01 -03:00
PyErr_Clear();
return NULL;
}
/* Extract a slice index from a PyInt or PyLong, and store in *pi.
Silently reduce values larger than INT_MAX to INT_MAX, and silently
boost values less than -INT_MAX to 0. Return 0 on error, 1 on success.
*/
/* Note: If v is NULL, return success without storing into *pi. This
is because_PyEval_SliceIndex() is called by apply_slice(), which can be
called by the SLICE opcode with v and/or w equal to NULL.
*/
int
_PyEval_SliceIndex(PyObject *v, int *pi)
{
if (v != NULL) {
long x;
if (PyInt_Check(v)) {
x = PyInt_AsLong(v);
} else if (PyLong_Check(v)) {
x = PyLong_AsLong(v);
if (x==-1 && PyErr_Occurred()) {
PyObject *long_zero;
int cmp;
if (!PyErr_ExceptionMatches(
PyExc_OverflowError)) {
/* It's not an overflow error, so just
signal an error */
return 0;
}
/* Clear the OverflowError */
PyErr_Clear();
/* It's an overflow error, so we need to
check the sign of the long integer,
set the value to INT_MAX or 0, and clear
the error. */
/* Create a long integer with a value of 0 */
long_zero = PyLong_FromLong(0L);
if (long_zero == NULL)
return 0;
/* Check sign */
cmp = PyObject_RichCompareBool(v, long_zero,
Py_GT);
Py_DECREF(long_zero);
if (cmp < 0)
return 0;
else if (cmp > 0)
x = INT_MAX;
else
x = 0;
}
} else {
PyErr_SetString(PyExc_TypeError,
"slice indices must be integers");
return 0;
}
/* Truncate -- very long indices are truncated anyway */
if (x > INT_MAX)
x = INT_MAX;
else if (x < -INT_MAX)
x = 0;
*pi = x;
}
return 1;
}
#undef ISINT
#define ISINT(x) ((x) == NULL || PyInt_Check(x) || PyLong_Check(x))
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static PyObject *
apply_slice(PyObject *u, PyObject *v, PyObject *w) /* return u[v:w] */
{
PyTypeObject *tp = u->ob_type;
PySequenceMethods *sq = tp->tp_as_sequence;
if (sq && sq->sq_slice && ISINT(v) && ISINT(w)) {
int ilow = 0, ihigh = INT_MAX;
if (!_PyEval_SliceIndex(v, &ilow))
return NULL;
if (!_PyEval_SliceIndex(w, &ihigh))
return NULL;
return PySequence_GetSlice(u, ilow, ihigh);
}
else {
PyObject *slice = PySlice_New(v, w, NULL);
if (slice != NULL) {
PyObject *res = PyObject_GetItem(u, slice);
Py_DECREF(slice);
return res;
}
else
return NULL;
}
}
static int
assign_slice(PyObject *u, PyObject *v, PyObject *w, PyObject *x)
/* u[v:w] = x */
{
PyTypeObject *tp = u->ob_type;
PySequenceMethods *sq = tp->tp_as_sequence;
if (sq && sq->sq_slice && ISINT(v) && ISINT(w)) {
int ilow = 0, ihigh = INT_MAX;
if (!_PyEval_SliceIndex(v, &ilow))
return -1;
if (!_PyEval_SliceIndex(w, &ihigh))
return -1;
if (x == NULL)
return PySequence_DelSlice(u, ilow, ihigh);
else
return PySequence_SetSlice(u, ilow, ihigh, x);
}
else {
PyObject *slice = PySlice_New(v, w, NULL);
if (slice != NULL) {
int res;
if (x != NULL)
res = PyObject_SetItem(u, slice, x);
else
res = PyObject_DelItem(u, slice);
Py_DECREF(slice);
return res;
}
else
return -1;
}
}
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static PyObject *
cmp_outcome(int op, register PyObject *v, register PyObject *w)
{
int res = 0;
switch (op) {
case PyCmp_IS:
case PyCmp_IS_NOT:
res = (v == w);
if (op == (int) PyCmp_IS_NOT)
res = !res;
break;
case PyCmp_IN:
case PyCmp_NOT_IN:
res = PySequence_Contains(w, v);
if (res < 0)
return NULL;
if (op == (int) PyCmp_NOT_IN)
res = !res;
break;
case PyCmp_EXC_MATCH:
res = PyErr_GivenExceptionMatches(v, w);
break;
default:
return PyObject_RichCompare(v, w, op);
}
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v = res ? Py_True : Py_False;
Py_INCREF(v);
return v;
}
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static PyObject *
import_from(PyObject *v, PyObject *name)
{
PyObject *x;
x = PyObject_GetAttr(v, name);
if (x == NULL && PyErr_ExceptionMatches(PyExc_AttributeError)) {
PyErr_Format(PyExc_ImportError,
"cannot import name %.230s",
PyString_AsString(name));
}
return x;
}
static int
import_all_from(PyObject *locals, PyObject *v)
{
PyObject *all = PyObject_GetAttrString(v, "__all__");
PyObject *dict, *name, *value;
int skip_leading_underscores = 0;
int pos, err;
if (all == NULL) {
if (!PyErr_ExceptionMatches(PyExc_AttributeError))
return -1; /* Unexpected error */
PyErr_Clear();
dict = PyObject_GetAttrString(v, "__dict__");
if (dict == NULL) {
if (!PyErr_ExceptionMatches(PyExc_AttributeError))
return -1;
PyErr_SetString(PyExc_ImportError,
"from-import-* object has no __dict__ and no __all__");
return -1;
}
all = PyMapping_Keys(dict);
Py_DECREF(dict);
if (all == NULL)
return -1;
skip_leading_underscores = 1;
}
for (pos = 0, err = 0; ; pos++) {
name = PySequence_GetItem(all, pos);
if (name == NULL) {
if (!PyErr_ExceptionMatches(PyExc_IndexError))
err = -1;
else
PyErr_Clear();
break;
}
if (skip_leading_underscores &&
PyString_Check(name) &&
PyString_AS_STRING(name)[0] == '_')
{
Py_DECREF(name);
continue;
}
value = PyObject_GetAttr(v, name);
if (value == NULL)
err = -1;
else
err = PyDict_SetItem(locals, name, value);
Py_DECREF(name);
Py_XDECREF(value);
if (err != 0)
break;
}
Py_DECREF(all);
return err;
}
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static PyObject *
build_class(PyObject *methods, PyObject *bases, PyObject *name)
{
PyObject *metaclass = NULL, *result, *base;
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if (PyDict_Check(methods))
metaclass = PyDict_GetItemString(methods, "__metaclass__");
if (metaclass != NULL)
Py_INCREF(metaclass);
else if (PyTuple_Check(bases) && PyTuple_GET_SIZE(bases) > 0) {
base = PyTuple_GET_ITEM(bases, 0);
metaclass = PyObject_GetAttrString(base, "__class__");
if (metaclass == NULL) {
PyErr_Clear();
metaclass = (PyObject *)base->ob_type;
Py_INCREF(metaclass);
}
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}
else {
PyObject *g = PyEval_GetGlobals();
if (g != NULL && PyDict_Check(g))
metaclass = PyDict_GetItemString(g, "__metaclass__");
if (metaclass == NULL)
metaclass = (PyObject *) &PyClass_Type;
Py_INCREF(metaclass);
}
result = PyObject_CallFunction(metaclass, "OOO", name, bases, methods);
Py_DECREF(metaclass);
return result;
}
static int
exec_statement(PyFrameObject *f, PyObject *prog, PyObject *globals,
PyObject *locals)
{
int n;
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PyObject *v;
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int plain = 0;
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if (PyTuple_Check(prog) && globals == Py_None && locals == Py_None &&
((n = PyTuple_Size(prog)) == 2 || n == 3)) {
/* Backward compatibility hack */
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globals = PyTuple_GetItem(prog, 1);
if (n == 3)
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locals = PyTuple_GetItem(prog, 2);
prog = PyTuple_GetItem(prog, 0);
}
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if (globals == Py_None) {
globals = PyEval_GetGlobals();
if (locals == Py_None) {
locals = PyEval_GetLocals();
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plain = 1;
}
}
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else if (locals == Py_None)
locals = globals;
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if (!PyString_Check(prog) &&
!PyUnicode_Check(prog) &&
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!PyCode_Check(prog) &&
!PyFile_Check(prog)) {
PyErr_SetString(PyExc_TypeError,
"exec: arg 1 must be a string, file, or code object");
return -1;
}
if (!PyDict_Check(globals)) {
PyErr_SetString(PyExc_TypeError,
"exec: arg 2 must be a dictionary or None");
return -1;
}
if (!PyDict_Check(locals)) {
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PyErr_SetString(PyExc_TypeError,
"exec: arg 3 must be a dictionary or None");
return -1;
}
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if (PyDict_GetItemString(globals, "__builtins__") == NULL)
PyDict_SetItemString(globals, "__builtins__", f->f_builtins);
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if (PyCode_Check(prog)) {
if (PyCode_GetNumFree((PyCodeObject *)prog) > 0) {
PyErr_SetString(PyExc_TypeError,
"code object passed to exec may not contain free variables");
return -1;
}
v = PyEval_EvalCode((PyCodeObject *) prog, globals, locals);
}
else if (PyFile_Check(prog)) {
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FILE *fp = PyFile_AsFile(prog);
char *name = PyString_AsString(PyFile_Name(prog));
PyCompilerFlags cf;
cf.cf_flags = 0;
if (PyEval_MergeCompilerFlags(&cf))
v = PyRun_FileFlags(fp, name, Py_file_input, globals,
locals, &cf);
else
v = PyRun_File(fp, name, Py_file_input, globals,
locals);
}
else {
char *str;
PyCompilerFlags cf;
if (PyString_AsStringAndSize(prog, &str, NULL))
return -1;
cf.cf_flags = 0;
if (PyEval_MergeCompilerFlags(&cf))
v = PyRun_StringFlags(str, Py_file_input, globals,
locals, &cf);
else
v = PyRun_String(str, Py_file_input, globals, locals);
}
if (plain)
PyFrame_LocalsToFast(f, 0);
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if (v == NULL)
return -1;
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Py_DECREF(v);
return 0;
}
static void
format_exc_check_arg(PyObject *exc, char *format_str, PyObject *obj)
{
char *obj_str;
if (!obj)
return;
obj_str = PyString_AsString(obj);
if (!obj_str)
return;
PyErr_Format(exc, format_str, obj_str);
}
#ifdef DYNAMIC_EXECUTION_PROFILE
static PyObject *
getarray(long a[256])
{
int i;
PyObject *l = PyList_New(256);
if (l == NULL) return NULL;
for (i = 0; i < 256; i++) {
PyObject *x = PyInt_FromLong(a[i]);
if (x == NULL) {
Py_DECREF(l);
return NULL;
}
PyList_SetItem(l, i, x);
}
for (i = 0; i < 256; i++)
a[i] = 0;
return l;
}
PyObject *
_Py_GetDXProfile(PyObject *self, PyObject *args)
{
#ifndef DXPAIRS
return getarray(dxp);
#else
int i;
PyObject *l = PyList_New(257);
if (l == NULL) return NULL;
for (i = 0; i < 257; i++) {
PyObject *x = getarray(dxpairs[i]);
if (x == NULL) {
Py_DECREF(l);
return NULL;
}
PyList_SetItem(l, i, x);
}
return l;
#endif
}
#endif