freebsd-skq/sys/boot/ficl/stack.c
msmith fe1c6b5af2 Add the Ficl (Forth Inspired Command Language) interpreter. If all goes well,
this will allow us to manage bloat in the loader by using a bytecoded HLL
rather than lots of C code.  It also offers an opportunity for vendors
or others with special applications to significantly customise the boot
process without having to commit to a divergent code branch.

This early commit is to allow others to experiment with the most effective
mechanisms for integrating FICL with the loader as it currently stands.

Ficl is distributed with the following license conditions:

"Ficl is freeware.  Use it in any way that you like, with the understanding
 that the code is not supported."

All source files contain authorship attributions.

Obtained from:	John Sadler (john_sadler@alum.mit.edu)
1998-11-03 06:11:35 +00:00

302 lines
7.0 KiB
C

/*******************************************************************
** s t a c k . c
** Forth Inspired Command Language
** Author: John Sadler (john_sadler@alum.mit.edu)
** Created: 16 Oct 1997
**
*******************************************************************/
#include <stdlib.h>
#include "ficl.h"
#define STKDEPTH(s) ((s)->sp - (s)->base)
/*
** N O T E: Stack convention:
**
** sp points to the first available cell
** push: store value at sp, increment sp
** pop: decrement sp, fetch value at sp
** Stack grows from low to high memory
*/
/*******************************************************************
v m C h e c k S t a c k
** Check the parameter stack for underflow or overflow.
** nCells controls the type of check: if nCells is zero,
** the function checks the stack state for underflow and overflow.
** If nCells > 0, checks to see that the stack has room to push
** that many cells. If less than zero, checks to see that the
** stack has room to pop that many cells. If any test fails,
** the function throws (via vmThrow) a VM_ERREXIT exception.
*******************************************************************/
void vmCheckStack(FICL_VM *pVM, int popCells, int pushCells)
{
FICL_STACK *pStack = pVM->pStack;
int nFree = pStack->base + pStack->nCells - pStack->sp;
if (popCells > STKDEPTH(pStack))
{
vmThrowErr(pVM, "Error: stack underflow");
}
if (nFree < pushCells - popCells)
{
vmThrowErr(pVM, "Error: stack overflow");
}
return;
}
/*******************************************************************
s t a c k C r e a t e
**
*******************************************************************/
FICL_STACK *stackCreate(unsigned nCells)
{
size_t size = sizeof (FICL_STACK) + nCells * sizeof (CELL);
FICL_STACK *pStack = ficlMalloc(size);
#if FICL_ROBUST
assert (nCells != 0);
assert (pStack != NULL);
#endif
pStack->nCells = nCells;
pStack->sp = pStack->base;
pStack->pFrame = NULL;
return pStack;
}
/*******************************************************************
s t a c k D e l e t e
**
*******************************************************************/
void stackDelete(FICL_STACK *pStack)
{
if (pStack)
ficlFree(pStack);
return;
}
/*******************************************************************
s t a c k D e p t h
**
*******************************************************************/
int stackDepth(FICL_STACK *pStack)
{
return STKDEPTH(pStack);
}
/*******************************************************************
s t a c k D r o p
**
*******************************************************************/
void stackDrop(FICL_STACK *pStack, int n)
{
#if FICL_ROBUST
assert(n > 0);
#endif
pStack->sp -= n;
return;
}
/*******************************************************************
s t a c k F e t c h
**
*******************************************************************/
CELL stackFetch(FICL_STACK *pStack, int n)
{
return pStack->sp[-n-1];
}
void stackStore(FICL_STACK *pStack, int n, CELL c)
{
pStack->sp[-n-1] = c;
return;
}
/*******************************************************************
s t a c k G e t T o p
**
*******************************************************************/
CELL stackGetTop(FICL_STACK *pStack)
{
return pStack->sp[-1];
}
/*******************************************************************
s t a c k L i n k
** Link a frame using the stack's frame pointer. Allot space for
** nCells cells in the frame
** 1) Push pFrame
** 2) pFrame = sp
** 3) sp += nCells
*******************************************************************/
void stackLink(FICL_STACK *pStack, int nCells)
{
stackPushPtr(pStack, pStack->pFrame);
pStack->pFrame = pStack->sp;
pStack->sp += nCells;
return;
}
/*******************************************************************
s t a c k U n l i n k
** Unink a stack frame previously created by stackLink
** 1) sp = pFrame
** 2) pFrame = pop()
*******************************************************************/
void stackUnlink(FICL_STACK *pStack)
{
pStack->sp = pStack->pFrame;
pStack->pFrame = stackPopPtr(pStack);
return;
}
/*******************************************************************
s t a c k P i c k
**
*******************************************************************/
void stackPick(FICL_STACK *pStack, int n)
{
stackPush(pStack, stackFetch(pStack, n));
return;
}
/*******************************************************************
s t a c k P o p
**
*******************************************************************/
CELL stackPop(FICL_STACK *pStack)
{
return *--pStack->sp;
}
void *stackPopPtr(FICL_STACK *pStack)
{
return (*--pStack->sp).p;
}
UNS32 stackPopUNS32(FICL_STACK *pStack)
{
return (*--pStack->sp).u;
}
INT32 stackPopINT32(FICL_STACK *pStack)
{
return (*--pStack->sp).i;
}
/*******************************************************************
s t a c k P u s h
**
*******************************************************************/
void stackPush(FICL_STACK *pStack, CELL c)
{
*pStack->sp++ = c;
}
void stackPushPtr(FICL_STACK *pStack, void *ptr)
{
*pStack->sp++ = LVALUEtoCELL(ptr);
}
void stackPushUNS32(FICL_STACK *pStack, UNS32 u)
{
*pStack->sp++ = LVALUEtoCELL(u);
}
void stackPushINT32(FICL_STACK *pStack, INT32 i)
{
*pStack->sp++ = LVALUEtoCELL(i);
}
/*******************************************************************
s t a c k R e s e t
**
*******************************************************************/
void stackReset(FICL_STACK *pStack)
{
pStack->sp = pStack->base;
return;
}
/*******************************************************************
s t a c k R o l l
** Roll nth stack entry to the top (counting from zero), if n is
** >= 0. Drop other entries as needed to fill the hole.
** If n < 0, roll top-of-stack to nth entry, pushing others
** upward as needed to fill the hole.
*******************************************************************/
void stackRoll(FICL_STACK *pStack, int n)
{
CELL c;
CELL *pCell;
if (n == 0)
return;
else if (n > 0)
{
pCell = pStack->sp - n - 1;
c = *pCell;
for (;n > 0; --n, pCell++)
{
*pCell = pCell[1];
}
*pCell = c;
}
else
{
pCell = pStack->sp - 1;
c = *pCell;
for (; n < 0; ++n, pCell--)
{
*pCell = pCell[-1];
}
*pCell = c;
}
return;
}
/*******************************************************************
s t a c k S e t T o p
**
*******************************************************************/
void stackSetTop(FICL_STACK *pStack, CELL c)
{
pStack->sp[-1] = c;
return;
}