mpw/toolbox/mm.cpp
Kelvin Sherlock 5b0d9e7d07 .
2016-08-09 08:17:04 -04:00

1653 lines
31 KiB
C++
Raw Permalink Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
* Copyright (c) 2013, Kelvin W Sherlock
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*/
#include "mm.h"
#include "toolbox.h"
#include <cpu/defs.h>
#include <cpu/CpuModule.h>
#include <cpu/fmem.h>
#include <string>
#include <cstring>
#include <deque>
#include <vector>
#include <map>
#include <mplite/mplite.h>
#include <macos/sysequ.h>
#include <macos/errors.h>
#include "stackframe.h"
using ToolBox::Log;
using MacOS::tool_return;
using MacOS::macos_error_from_errno;
using MacOS::macos_error;
namespace
{
mplite_t pool;
uint8_t *Memory;
uint32_t MemorySize;
uint32_t HeapSize;
// queue of free Handles
std::deque<uint32_t> HandleQueue;
// map of ptr -> size
std::map<uint32_t, uint32_t> PtrMap;
// map of handle -> size [? just use Ptr map?]
std::map<uint32_t, MM::HandleInfo> HandleMap;
inline macos_error SetMemError(macos_error error)
{
memoryWriteWord(error, MacOS::MemErr);
return error;
}
inline macos_error SetMemError(int16_t error)
{
return SetMemError((macos_error)error);
}
bool alloc_handle_block()
{
const unsigned HandleCount = 128; // 512 bytes of handle blocks.
uint8_t *block = (uint8_t *)mplite_malloc(&pool,
sizeof(uint32_t) * HandleCount);
if (!block) return false;
uint32_t hh = block - Memory;
uint32_t end = hh + 128 * sizeof(uint32_t);
for ( ; hh < end; hh += sizeof(uint32_t))
{
HandleQueue.push_back(hh);
}
return true;
}
}
namespace MM
{
using MacOS::tool_return_type;
template<class T, class FRT, class F>
T with_handle_helper(F &&f, HandleInfo &info, typename std::enable_if<!std::is_void<FRT>::value>::type* = 0) {
T rv = f(info);
return rv;
}
template<class T, class FRT, class F>
T with_handle_helper(F &&f, HandleInfo &info, typename std::enable_if<std::is_void<FRT>::value>::type* = 0) {
f(info);
return tool_return<void>();
}
template<class F,
typename FRT = typename std::result_of<F(HandleInfo &)>::type, // function return type
typename TRT = typename tool_return_type<FRT>::type> // tool return type.
TRT __with_handle(uint32_t handle, F &&f)
{
if (handle == 0) return SetMemError(MacOS::nilHandleErr);
const auto iter = HandleMap.find(handle);
if (iter == HandleMap.end()) return SetMemError(MacOS::memWZErr);
auto &info = iter->second;
TRT rv = with_handle_helper<TRT, FRT>(std::forward<F>(f), info);
SetMemError(rv.error());
return rv;
}
bool Init(uint8_t *memory, uint32_t memorySize, uint32_t globals, uint32_t stack)
{
int ok;
Memory = memory;
MemorySize = memorySize;
HeapSize = memorySize - stack;
ok = mplite_init(&pool,
memory + globals,
memorySize - globals - stack,
32,
NULL);
if (ok != MPLITE_OK) return false;
// allocate a handle master block...
if (!alloc_handle_block()) return false;
// create system handles for the stack and global space?
return true;
}
namespace Native {
// debugger support.
// print info on an address.
void MemoryInfo(uint32_t address)
{
// 1. check if it's a pointer.
{
auto iter = PtrMap.find(address);
if (iter != PtrMap.end())
{
printf("Pointer $%08x Size: $%08x\n", iter->first, iter->second);
return;
}
}
// 2. check if it's contained in a pointer
for (const auto kv : PtrMap)
{
if (address < kv.first) continue;
if (address >= kv.first + kv.second) continue;
printf("Pointer $%08x Size: $%08x\n", kv.first, kv.second);
return;
}
// 2. check if it's a handle.
{
auto iter = HandleMap.find(address);
if (iter != HandleMap.end())
{
const HandleInfo &info = iter->second;
printf("Handle $%08x Pointer: $%08x Size: $%08x Flags: %c %c %c\n",
iter->first,
info.address,
info.size,
info.locked ? 'L' : ' ',
info.purgeable ? 'P' : ' ',
info.resource ? 'R' : ' '
);
return;
}
}
// 3. check if the address is within a handle.
{
for (const auto kv : HandleMap)
{
const HandleInfo &info = kv.second;
if (!info.address) continue;
uint32_t begin = info.address;
uint32_t end = info.address + info.size;
if (!info.size) end++;
if (address >= begin && address < end)
{
printf("Handle $%08x Pointer: $%08x Size: $%08x Flags: %c %c %c\n",
kv.first,
info.address,
info.size,
info.locked ? 'L' : ' ',
info.purgeable ? 'P' : ' ',
info.resource ? 'R' : ' '
);
return;
}
}
}
}
void PrintMemoryStats()
{
mplite_print_stats(&pool, std::puts);
for (const auto & kv : HandleMap)
{
const auto h = kv.first;
const auto & info = kv.second;
fprintf(stdout, "%08x %08x %08x %c %c %c\n",
h,
info.address,
info.size,
info.locked? 'L' : ' ',
info.purgeable? 'P' : ' ',
info.resource ? 'R' : ' '
);
}
}
tool_return<uint32_t> NewPtr(uint32_t size, bool clear)
{
// native pointers.
uint32_t mcptr = 0;
//if (size == 0) return 0;
uint8_t *ptr = nullptr;
ptr = (uint8_t *)mplite_malloc(&pool, size ? size : 1);
if (!ptr)
{
return SetMemError(MacOS::memFullErr);
}
if (clear)
std::memset(ptr, 0, size);
mcptr = ptr - Memory;
PtrMap.emplace(std::make_pair(mcptr, size));
SetMemError(0);
return mcptr;
}
tool_return<void> DisposePtr(uint32_t mcptr)
{
auto iter = PtrMap.find(mcptr);
if (iter == PtrMap.end()) return SetMemError(MacOS::memWZErr);
PtrMap.erase(iter);
uint8_t *ptr = mcptr + Memory;
mplite_free(&pool, ptr);
return SetMemError(0);
}
/* create a NULL handle (for resource manager) */
tool_return<uint32_t> NewEmptyHandle()
{
uint32_t hh;
if (!HandleQueue.size())
{
if (!alloc_handle_block())
{
return SetMemError(MacOS::memFullErr);
}
}
hh = HandleQueue.front();
HandleQueue.pop_front();
HandleMap.emplace(std::make_pair(hh, HandleInfo(0, 0)));
memoryWriteLong(0, hh);
return hh;
}
tool_return<hp> NewHandle(uint32_t size, bool clear)
{
uint8_t *ptr;
uint32_t hh;
uint32_t handle = 0;
uint32_t mcptr = 0;
if (!HandleQueue.size())
{
if (!alloc_handle_block())
{
return SetMemError(MacOS::memFullErr);
}
}
hh = HandleQueue.front();
HandleQueue.pop_front();
ptr = (uint8_t *)mplite_malloc(&pool, size ? size : 1);
if (!ptr)
{
HandleQueue.push_back(hh);
return SetMemError(MacOS::memFullErr);
}
mcptr = ptr - Memory;
if (clear)
std::memset(ptr, 0, size);
// need a handle -> ptr map?
HandleMap.emplace(std::make_pair(hh, HandleInfo(mcptr, size)));
memoryWriteLong(mcptr, hh);
handle = hh;
SetMemError(0);
return hp{handle, mcptr};
}
tool_return<hp> NewHandleWithAttr(uint32_t size, unsigned attr)
{
uint8_t *ptr;
uint32_t hh;
uint32_t handle = 0;
uint32_t mcptr = 0;
if (!HandleQueue.size())
{
if (!alloc_handle_block())
{
return SetMemError(MacOS::memFullErr);
}
}
hh = HandleQueue.front();
HandleQueue.pop_front();
ptr = (uint8_t *)mplite_malloc(&pool, size ? size : 1);
if (!ptr)
{
HandleQueue.push_back(hh);
return SetMemError(MacOS::memFullErr);
}
mcptr = ptr - Memory;
// always clear it.
std::memset(ptr, 0, size);
// need a handle -> ptr map?
HandleMap.emplace(std::make_pair(hh, HandleInfo(mcptr, size, attr)));
memoryWriteLong(mcptr, hh);
handle = hh;
SetMemError(0);
return hp{handle, mcptr};
}
tool_return<void> DisposeHandle(uint32_t handle)
{
auto iter = HandleMap.find(handle);
if (iter == HandleMap.end()) return SetMemError(MacOS::memWZErr);
HandleInfo info = iter->second;
HandleMap.erase(iter);
if (info.address)
{
uint8_t *ptr = info.address + Memory;
mplite_free(&pool, ptr);
}
HandleQueue.push_back(handle);
return SetMemError(0);
}
tool_return<uint32_t> ReallocHandle(uint32_t handle, uint32_t logicalSize)
{
if (handle == 0) return SetMemError(MacOS::nilHandleErr);
auto iter = HandleMap.find(handle);
if (iter == HandleMap.end()) return SetMemError(MacOS::memWZErr);
auto& info = iter->second;
if (info.locked) return SetMemError(MacOS::memLockedErr);
uint32_t mcptr = 0;
// todo -- purge & retry on failure.
void *address = mplite_malloc(&pool, logicalSize ? logicalSize : 1);
if (!address) return SetMemError(MacOS::memFullErr);
std::memset(address, 0, logicalSize);
mcptr = (uint8_t *)address - Memory;
// the handle is not altered in the event of an error.
if (info.address)
{
void *address = Memory + info.address;
mplite_free(&pool, address);
}
info.address = mcptr;
info.size = logicalSize;
// "The new block is unlocked and unpurgeable."
info.locked = false;
info.purgeable = false;
memoryWriteLong(mcptr, handle);
return mcptr;
}
/* returns true if memory has been purged. */
bool Purge(uint32_t but_not_this_handle = 0) {
bool rv = false;
for (auto & kv : HandleMap)
{
uint32_t ph = kv.first;
auto &info = kv.second;
if (info.address == 0) continue;
if (ph == but_not_this_handle) continue;
if (info.purgeable && !info.locked)
{
mplite_free(&pool, Memory + info.address);
info.size = 0;
info.address = 0;
// also need to update memory
memoryWriteLong(0, ph);
rv = true;
}
}
return rv;
}
tool_return<uint32_t> SetHandleSize(uint32_t handle, uint32_t newSize)
{
if (handle == 0) return SetMemError(MacOS::nilHandleErr);
const auto iter = HandleMap.find(handle);
if (iter == HandleMap.end()) return SetMemError(MacOS::memWZErr);
auto &info = iter->second;
// 0 - no change in size.
if (info.size == newSize) return SetMemError(0);
uint32_t mcptr = info.address;
uint8_t *ptr = mcptr + Memory;
// 1. - resizing to 0.
if (!newSize)
{
if (info.locked)
{
//return SetMemError(MacOS::memLockedErr);
// ppclink resizes locked handles.
info.size = 0;
return SetMemError(0);
}
// todo -- size 0 should have a ptr to differentiate
// from purged.
mplite_free(&pool, ptr);
info.address = 0;
info.size = 0;
memoryWriteLong(info.address, handle);
SetMemError(0);
return info.address;
}
// 2. - resizing from 0.
if (!mcptr)
{
if (info.locked) return SetMemError(MacOS::memLockedErr);
ptr = (uint8_t *)mplite_malloc(&pool, newSize);
if (!ptr) return SetMemError(MacOS::memFullErr);
mcptr = ptr - Memory;
info.address = mcptr;
info.size = newSize;
memoryWriteLong(info.address, handle);
SetMemError(0);
return info.address;
}
for (unsigned i = 0; i < 2; ++i)
{
// 3. - locked
if (info.locked)
{
if (mplite_resize(&pool, ptr, mplite_roundup(&pool, newSize)) == MPLITE_OK)
{
info.size = newSize;
SetMemError(0);
return info.address;
}
}
else
{
// 4. - resize.
ptr = (uint8_t *)mplite_realloc(&pool, ptr, mplite_roundup(&pool, newSize));
if (ptr)
{
mcptr = ptr - Memory;
info.address = mcptr;
info.size = newSize;
memoryWriteLong(info.address, handle);
SetMemError(0);
return info.address;
}
}
fprintf(stderr, "mplite_realloc failed.\n");
Native::PrintMemoryStats();
if (i > 0 || !Purge(handle)) break;
}
return SetMemError(MacOS::memFullErr);
}
tool_return<void> HSetState(uint32_t handle, uint16_t attr)
{
return __with_handle(handle, [attr](HandleInfo &info){
info.resource = attr & attrResource;
info.purgeable = attr & attrPurgeable;
info.locked = attr & attrLocked;
});
}
tool_return<uint16_t> HGetState(uint32_t handle)
{
return __with_handle(handle, [](const HandleInfo &info){
uint16_t attr = 0;
if (info.resource) attr |= attrResource;
if (info.purgeable) attr |= attrPurgeable;
if (info.locked) attr |= attrLocked;
return attr;
});
}
tool_return<void> HSetRBit(uint32_t handle)
{
return __with_handle(handle, [](HandleInfo &info) { info.resource = true; });
}
tool_return<void> HClrRBit(uint32_t handle)
{
return __with_handle(handle, [](HandleInfo &info) { info.resource = false; });
}
tool_return<void> HLock(uint32_t handle)
{
return __with_handle(handle, [](HandleInfo &info) { info.locked = true; });
}
tool_return<void> HUnlock(uint32_t handle)
{
return __with_handle(handle, [](HandleInfo &info) { info.locked = false; });
}
tool_return<uint32_t> GetHandleSize(uint32_t handle)
{
return __with_handle(handle, [](const HandleInfo &info){ return info.size; });
}
tool_return<HandleInfo> GetHandleInfo(uint32_t handle)
{
return __with_handle(handle, [](const HandleInfo &info){ return info; });
}
tool_return<void> EmptyHandle(uint32_t handle) {
return __with_handle(handle, [handle](HandleInfo &info) {
if (info.address == 0) return MacOS::noErr;
// "The block whose handle is h must be unlocked but need not be purgeable."
if (info.locked) return MacOS::memPurErr;
void *address = Memory + info.address;
mplite_free(&pool, address);
info.address = 0;
info.size = 0;
memoryWriteLong(0, handle);
return MacOS::noErr;
});
}
}
#pragma mark --
#pragma mark --
uint16_t BlockMove(uint16_t trap)
{
// also implements BlockMoveData.
// BlockMove will flush caches, BlockMoveData will not.
/*
* on entry:
* A0 Pointer to source
* A1 Pointer to destination
* D0 Number of bytes to copy
*
* on exit:
* A0 Address of the new block or NIL
* D0 Result code
*
*/
uint32_t source = cpuGetAReg(0);
uint32_t dest = cpuGetAReg(1);
uint32_t count = cpuGetDReg(0);
Log("%04x BlockMove(%08x, %08x, %08x)\n",
trap, source, dest, count);
// TODO -- 32-bit clean?
// TODO -- verify within MemorySize?
#if 0
if (source == 0 || dest == 0 || count == 0)
return 0;
#endif
std::memmove(Memory + dest, Memory + source, count);
return 0;
}
uint32_t CompactMem(uint16_t trap)
{
// todo -- add function to check pool for largest block?
/*
* on entry:
* D0: cbNeeded (long word)
*
* on exit:
* D0: function result (long word)
*
*/
uint32_t cbNeeded = cpuGetDReg(0);
Log("%04x CompactMem(%08x)\n", trap, cbNeeded);
SetMemError(0);
return mplite_maxmem(&pool);
}
uint32_t MaxMem(uint16_t trap)
{
// return largest contiguous free block size.
/*
* on entry:
* (nothing)
*
* on exit:
* D0: function result (long word)
*
*/
Log("%04x MaxMem()\n", trap);
SetMemError(0);
return mplite_maxmem(&pool);
}
uint32_t MaxBlock(uint16_t trap)
{
/*
* The MaxBlock function returns the maximum contiguous space, in bytes, that you
* could obtain after compacting the current heap zone. MaxBlock does not actually
* do the compaction.
*/
/*
* on entry:
* (nothing)
*
* on exit:
* D0: function result (long word)
*
*/
Log("%04x MaxBlock()\n", trap);
SetMemError(0);
return mplite_maxmem(&pool);
}
uint32_t FreeMem(uint16_t trap)
{
// total free memory.
/*
* on entry:
* (nothing)
*
* on exit:
* D0: function result (long word)
*
*/
Log("%04x FreeMem()\n", trap);
SetMemError(0);
return mplite_freemem(&pool);
}
uint16_t ReserveMem(uint16_t trap)
{
/*
* on entry:
* D0: cbNeeded (long word)
*
* on exit:
* D0: Result code.
*
*/
uint32_t cbNeeded = cpuGetDReg(0);
uint32_t available;
Log("%04x ReserveMem($%08x)\n", trap, cbNeeded);
available = mplite_maxmem(&pool);
// TODO -- if available < cbNeeded, purge handle and retry?
if (available < cbNeeded) return SetMemError(MacOS::memFullErr);
return SetMemError(0);
}
uint16_t MoveHHi(uint16_t trap)
{
/*
* on entry:
* A0: Handle to move
*
* on exit:
* D0: Result code.
*
*/
uint32_t theHandle = cpuGetAReg(0);
Log("%04x MoveHHi(%08x)\n", trap, theHandle);
// check if it's valid.
auto iter = HandleMap.find(theHandle);
if (iter == HandleMap.end()) return SetMemError(MacOS::memWZErr);
return SetMemError(0);
}
uint32_t StackSpace(uint16_t trap)
{
/*
* on entry:
*
* on exit:
* D0: Number of bytes between stack and heap
*
*/
uint32_t sp = cpuGetAReg(7);
Log("%04x StackSpace(%08x)\n", trap);
SetMemError(0);
// MemorySize is the top of the heap. stack is after it.
return sp - HeapSize;
}
#pragma mark Pointers
uint16_t NewPtr(uint16_t trap)
{
/*
* on entry:
* D0 Number of logical bytes requested
*
* on exit:
* A0 Address of the new block or NIL
* D0 Result code
*
*/
bool clear = trap & (1 << 9);
//bool sys = trap & (1 << 10);
uint32_t size = cpuGetDReg(0);
Log("%04x NewPtr(%08x)\n", trap, size);
// todo -- separate pools for sys vs non-sys?
// todo -- NewPtr(0) -- null or empty ptr?
auto rv = Native::NewPtr(size, clear);
cpuSetAReg(0, rv.value());
return rv.error(); //SetMemError(error);
}
uint16_t DisposePtr(uint16_t trap)
{
/*
* on entry:
* A0 Pointer to the nonrelocatable block to be disposed of
*
* on exit:
* D0 Result code
*
*/
uint32_t mcptr = cpuGetAReg(0);
Log("%04x DisposePtr(%08x)\n", trap, mcptr);
return Native::DisposePtr(mcptr).error();
}
uint32_t GetPtrSize(uint16_t trap)
{
/*
* on entry:
* A0 pointer
*
* on exit:
* D0 size (32-bit) or error code
*
*/
uint32_t mcptr = cpuGetAReg(0);
Log("%08x GetPtrSize(%08x)\n", trap, mcptr);
auto iter = PtrMap.find(mcptr);
if (iter == PtrMap.end()) return SetMemError(MacOS::memWZErr);
return iter->second;
}
uint16_t SetPtrSize(uint16_t trap)
{
/*
* on entry:
* A0 pointer
* D0 new size
*
* on exit:
* D0 Result code
*
*/
uint32_t mcptr = cpuGetAReg(0);
uint32_t newSize = cpuGetDReg(0);
Log("%08x SetPtrSize(%08x, %08x)\n", trap, mcptr, newSize);
auto iter = PtrMap.find(mcptr);
if (iter == PtrMap.end()) return SetMemError(MacOS::memWZErr);
uint8_t *ptr = mcptr + Memory;
if (mplite_resize(&pool, ptr, mplite_roundup(&pool, newSize)) < 0)
{
return SetMemError(MacOS::memFullErr);
}
// update the size.
iter->second = newSize;
return SetMemError(0);
}
#pragma mark Handles
uint16_t NewHandle(uint16_t trap)
{
/*
* on entry:
* D0 Number of logical bytes requested
*
* on exit:
* A0 Address of the new handle or NIL
* D0 Result code
*
*/
bool clear = trap & (1 << 9);
//bool sys = trap & (1 << 10);
uint32_t size = cpuGetDReg(0);
Log("%04x NewHandle(%08x)\n", trap, size);
auto rv = Native::NewHandle(size, clear);
cpuSetAReg(0, rv.value().handle);
return rv.error();
}
uint16_t DisposeHandle(uint16_t trap)
{
/*
* on entry:
* A0 Handle to be disposed of
*
* on exit:
* D0 Result code
*
*/
uint32_t hh = cpuGetAReg(0);
Log("%04x DisposeHandle(%08x)\n", trap, hh);
return Native::DisposeHandle(hh).error();
}
uint16_t EmptyHandle(uint16_t trap)
{
/*
* on entry:
* A0 Handle to be disposed of
*
* on exit:
* D0 Result code
*
*/
uint32_t hh = cpuGetAReg(0);
Log("%04x EmptyHandle(%08x)\n", trap, hh);
return Native::EmptyHandle(hh).error();
}
/*
* ReallocHandle (h: Handle; logicalSize: Size);
*
* ReallocHandle allocates a new relocatable block with a logical
* size of logicalSize bytes. It then updates handle h by setting
* its master pointer to point to the new block. The main use of
* this procedure is to reallocate space for a block that has
* been purged. Normally h is an empty handle, but it need not
* be: If it points to an existing block, that block is released
* before the new block is created.
*
* In case of an error, no new block is allocated and handle h is
* left unchanged.
*/
uint16_t ReallocHandle(uint16_t trap)
{
/*
* on entry:
* A0 Handle to be disposed of
* D0 Logical Size
*
* on exit:
* D0 Result code
*
*/
uint32_t hh = cpuGetAReg(0);
uint32_t logicalSize = cpuGetDReg(0);
Log("%04x ReallocHandle(%08x, %08x)\n", trap, hh, logicalSize);
return Native::ReallocHandle(hh, logicalSize).error();
}
uint32_t GetHandleSize(uint16_t trap)
{
/*
* on entry:
* A0 handle
*
* on exit:
* D0 size (32-bit) or error code
*
*/
/*
* The trap dispatcher sets the condition codes before returning
* from a trap by testing the low-order word of register D0 with
* a TST.W instruction. Because the block size returned in D0 by
* _GetHandleSize is a full 32-bit long word, the word-length
* test sets the condition codes incorrectly in this case. To
* branch on the contents of D0, use your own TST.L instruction
* on return from the trap to test the full 32 bits of the register.
*/
uint32_t hh = cpuGetAReg(0);
Log("%04x GetHandleSize(%08x)\n", trap, hh);
return Native::GetHandleSize(hh).value_or_error();
}
uint16_t SetHandleSize(uint16_t trap)
{
/*
* on entry:
* A0 pointer
* D0 new size
*
* on exit:
* D0 Result code
*
*/
uint32_t hh = cpuGetAReg(0);
uint32_t newSize = cpuGetDReg(0);
Log("%04x SetHandleSize(%08x, %08x)\n", trap, hh, newSize);
return Native::SetHandleSize(hh, newSize).error();
}
uint32_t RecoverHandle(uint16_t trap)
{
// FUNCTION RecoverHandle (p: Ptr): Handle;
/*
* on entry:
* A0 Master pointer
*
* on exit:
* A0 Handle to master pointers relocatable block
* D0 Unchanged
*
*/
uint32_t p = cpuGetAReg(0);
uint32_t hh = 0;
Log("%04x RecoverHandle(%08x)\n", trap, p);
uint16_t error = MacOS::memBCErr;
for (const auto kv : HandleMap)
{
const HandleInfo &info = kv.second;
if (!info.address) continue;
uint32_t begin = info.address;
uint32_t end = info.address + info.size;
if (!info.size) end++;
if (p >= begin && p < end)
{
hh = kv.first;
error = MacOS::noErr;
break;
}
}
SetMemError(error);
cpuSetAReg(0, hh);
// return d0 register unchanged.
return cpuGetDReg(0);
}
#pragma mark Handle attributes
uint16_t HGetState(uint16_t trap)
{
/*
* on entry:
* A0 Handle
*
* on exit:
* D0 flag byte
*
*/
unsigned flags = 0;
uint32_t hh = cpuGetAReg(0);
Log("%04x HGetState(%08x)\n", trap, hh);
return Native::HGetState(hh).value_or_error();
}
uint16_t HSetState(uint16_t trap)
{
/*
* on entry:
* A0 Handle
* D0 flags
*
* on exit:
* D0 flag byte
*
*/
uint32_t hh = cpuGetAReg(0);
uint16_t flags = cpuGetDReg(0);
Log("%04x HSetState(%08x, %04x)\n", trap, hh, flags);
return Native::HSetState(hh, flags).error();
}
uint16_t HPurge(uint16_t trap)
{
/*
* on entry:
* A0 Handle
*
* on exit:
* D0 Result code
*
*/
uint32_t hh = cpuGetAReg(0);
Log("%04x HPurge(%08x)\n", trap, hh);
return __with_handle(hh, [](HandleInfo &info){ info.purgeable = true; }).error();
}
uint16_t HNoPurge(uint16_t trap)
{
/*
* on entry:
* A0 Handle
*
* on exit:
* D0 Result code
*
*/
uint32_t hh = cpuGetAReg(0);
Log("%04x HNoPurge(%08x)\n", trap, hh);
return __with_handle(hh, [](HandleInfo &info){ info.purgeable = false; }).error();
}
uint16_t HLock(uint16_t trap)
{
/*
* on entry:
* A0 Handle
*
* on exit:
* D0 Result code
*
*/
uint32_t hh = cpuGetAReg(0);
Log("%04x HLock(%08x)\n", trap, hh);
return __with_handle(hh, [](HandleInfo &info){ info.locked = true; }).error();
}
uint16_t HUnlock(uint16_t trap)
{
/*
* on entry:
* A0 Handle
*
* on exit:
* D0 Result code
*
*/
uint32_t hh = cpuGetAReg(0);
Log("%04x HUnlock(%08x)\n", trap, hh);
return __with_handle(hh, [](HandleInfo &info){ info.locked = false; }).error();
}
#pragma mark - OS Utility Routines
uint16_t HandToHand(uint16_t trap)
{
/*
* on entry:
* A0 source Handle
*
* on exit:
* A0 destination Handle
* D0 Result code
*
*/
uint32_t srcHandle = cpuGetAReg(0);
Log("%04x HandToHand(%08x)\n", trap, srcHandle);
auto iter = HandleMap.find(srcHandle);
if (iter == HandleMap.end())
return SetMemError(MacOS::memWZErr);
auto const info = iter->second;
auto rv = Native::NewHandle(info.size, false);
if (!rv.error())
{
std::memmove(memoryPointer(rv.value().pointer), memoryPointer(info.address), info.size);
}
cpuSetAReg(0, rv.value().handle);
return rv.error(); // SetMemError called by Native::NewHandle.
}
uint16_t PtrToHand(uint16_t trap)
{
/*
* on entry:
* A0 source Pointer
* D0 size
*
* on exit:
* A0 destination pointer
* D0 Result code
*
*/
uint32_t mcptr = cpuGetAReg(0);
uint32_t size = cpuGetDReg(0);
Log("%04x PtrToHand(%08x, %08x)\n", trap, mcptr, size);
auto rv = Native::NewHandle(size, false);
if (!rv.error())
{
std::memmove(memoryPointer(rv.value().pointer), memoryPointer(mcptr), size);
}
cpuSetAReg(0, rv.value().handle);
return rv.error(); // SetMemError called by Native::NewHandle.
}
uint16_t PtrAndHand(uint16_t trap)
{
// FUNCTION PtrAndHand (pntr: Ptr; hndl: Handle; size: LongInt): OSErr;
/*
* on entry:
* A0 source Pointer
* A1 dest Handle
* D0 number of bytes to concatenate
*
* on exit:
* A0 destination Handle
* D0 Result code
*
*/
uint32_t ptr = cpuGetAReg(0);
uint32_t handle = cpuGetAReg(1);
uint32_t size = cpuGetDReg(0);
Log("%04x PtrAndHand(%08x, %08x, %08x)\n", trap, ptr, handle, size);
cpuSetAReg(0, handle);
auto tmp = Native::GetHandleSize(handle);
if (tmp.error()) return tmp.error();
uint32_t oldSize = tmp.value();
if ((uint64_t)oldSize + (uint64_t)size > UINT32_MAX)
return SetMemError(MacOS::memFullErr);
auto err = Native::SetHandleSize(handle, oldSize + size);
if (err.error()) return err.error();
auto iter = HandleMap.find(handle);
if (iter == HandleMap.end())
return SetMemError(MacOS::memWZErr);
auto const info = iter->second;
std::memmove(memoryPointer(info.address + oldSize), memoryPointer(ptr), size);
return SetMemError(0);
}
#pragma mark -
uint32_t StripAddress(uint16_t trap)
{
/*
* on entry:
* d0 Address to strip
*
* on exit:
* D0 Address that has been stripped.
*
*/
// TODO -- in 32-bit mode, this is a nop.
// have a --24 / --32 flag?
uint32_t address = cpuGetDReg(0);
Log("%04x StripAddress(%08x)\n", trap, address);
if (MemorySize <= 0x00ffffff)
address &= 0x00ffffff;
return address;
}
#pragma mark - zone
uint16_t HandleZone(uint16_t trap)
{
// FUNCTION HandleZone (h: Handle): THz;
/*
* on entry:
* A0 Handle whose zone is to be found
*
* on exit:
* A0 Pointer to handles heap zone
* D0 Result code
*
*/
uint32_t h = cpuGetAReg(0);
Log("%04x HandleZone(%08x)\n", trap, h);
if (HandleMap.find(h) == HandleMap.end())
{
cpuSetAReg(0, 0);
return SetMemError(MacOS::memWZErr);
}
cpuSetAReg(0, 0);
return SetMemError(0);
}
uint16_t GetZone(uint16_t trap)
{
// FUNCTION GetZone: THz;
/*
* on entry:
*
* on exit:
* A0 Pointer to current heap zone
* D0 Result code
*/
Log("%04x GetZone()\n", trap);
cpuSetAReg(0, 0);
return 0;
}
uint16_t SetZone(uint16_t trap)
{
// PROCEDURE SetZone (hz: THz);
/*
* on entry:
* A0 Pointer to new current heap zone
*
* on exit:
* D0 Result code
*/
uint32_t THz = cpuGetAReg(0);
Log("%04x SetZone(%08x)\n", trap, THz);
return 0;
}
uint16_t MaxApplZone(uint16_t trap)
{
// PROCEDURE MaxApplZone;
/*
* on exit:
* D0 Result code
*/
Log("%04x MaxApplZone\n", trap);
return 0;
}
uint16_t SetApplLimit(uint16_t trap)
{
// PROCEDURE SetApplLimit (zoneLimit: Ptr);
/*
* on entry
* A0 Pointer to desired new zone limit
*
* on exit
* D0 Result code
*/
uint32_t zoneLimit = cpuGetAReg(0);
Log("%04x SetApplLimit(%08x)\n", trap, zoneLimit);
return 0;
}
uint32_t PurgeSpace(uint16_t trap)
{
// PROCEDURE PurgeSpace (VAR total: LongInt; VAR contig: LongInt);
/*
* Registers on exit:
* A0 Maximum number of contiguous bytes after purge
* D0 Total free memory after purge
*/
Log("%04x PurgeSpace()\n", trap);
SetMemError(0);
cpuSetAReg(0, mplite_maxmem(&pool));
return mplite_freemem(&pool);
}
uint16_t TempMaxMem(void)
{
// FUNCTION TempMaxMem (VAR grow: Size): Size;
uint32_t address;
uint32_t sp = StackFrame<4>(address);
Log(" TempMaxMem(%08x)\n", address);
if (address) memoryWriteLong(0, address);
ToolReturn<4>(sp, mplite_maxmem(&pool));
return SetMemError(0);
}
uint16_t TempFreeMem(void)
{
// FUNCTION TempFreeMem: LongInt;
Log(" TempFreeMem()\n");
ToolReturn<4>(-1, mplite_freemem(&pool));
return SetMemError(0);
}
uint16_t TempNewHandle(void)
{
// FUNCTION TempNewHandle (logicalSize: Size;
// VAR resultCode: OSErr): Handle;
uint32_t logicalSize;
uint32_t resultCode;
uint32_t sp = StackFrame<8>(logicalSize, resultCode);
Log(" TempNewHandle(%08x, %08x)\n", logicalSize, resultCode);
auto rv = Native::NewHandle(logicalSize, true);
if (resultCode) memoryWriteWord(rv.error(), resultCode);
ToolReturn<4>(sp, rv.value().handle);
return rv.error();
}
uint16_t TempHLock(void)
{
// PROCEDURE TempHLock (theHandle: Handle; VAR resultCode: OSErr);
uint32_t theHandle;
uint32_t resultCode;
StackFrame<8>(theHandle, resultCode);
Log(" TempHLock(%08x, %08x)\n", theHandle, resultCode);
auto rv = Native::HLock(theHandle);
if (resultCode) memoryWriteWord(rv.error(), resultCode);
return rv.error();
}
uint16_t TempHUnlock(void)
{
// PROCEDURE TempHUnlock (theHandle: Handle; VAR resultCode: OSErr);
uint32_t theHandle;
uint32_t resultCode;
StackFrame<8>(theHandle, resultCode);
Log(" TempHUnlock(%08x, %08x)\n", theHandle, resultCode);
auto rv = Native::HUnlock(theHandle);
if (resultCode) memoryWriteWord(rv.error(), resultCode);
return rv.error();
}
uint16_t TempDisposeHandle(void)
{
// PROCEDURE TempDisposeHandle (theHandle: Handle; VAR resultCode: OSErr);
uint32_t theHandle;
uint32_t resultCode;
StackFrame<8>(theHandle, resultCode);
Log(" TempDisposeHandle(%08x, %08x)\n", theHandle, resultCode);
auto rv = Native::DisposeHandle(theHandle);
if (resultCode) memoryWriteWord(rv.error(), resultCode);
return rv.error();
}
}