usbloadergx/source/memory/mem2alloc.cpp

#include "mem2alloc.hpp"

#include <ogc/system.h>
#include <algorithm>
#include <string.h>


class LockMutex
{
        mutex_t &m_mutex;
    public:
        LockMutex( mutex_t &m ) : m_mutex( m ) { LWP_MutexLock( m_mutex ); }
        ~LockMutex( void ) { LWP_MutexUnlock( m_mutex ); }
};

void CMEM2Alloc::init( unsigned int size )
{
    m_baseAddress = ( SBlock * ) ( ( ( u32 )SYS_GetArena2Lo() + 31 ) & ~31 );
    m_endAddress = ( SBlock * ) ( ( char * )m_baseAddress + std::min( size * 0x100000, SYS_GetArena2Size() & ~31 ) );
    if ( m_endAddress > ( SBlock * ) 0x93300000 ) //rest is reserved for usb/usb2/network and other stuff... (0xE0000 bytes)
        m_endAddress = ( SBlock * ) 0x93300000;
    SYS_SetArena2Lo( m_endAddress );
    LWP_MutexInit( &m_mutex, 0 );
}

void CMEM2Alloc::init( void *addr, void *end )
{
    m_baseAddress = ( SBlock * )( ( ( u32 )addr + 31 ) & ~31 );
    m_endAddress = ( SBlock * )( ( u32 )end & ~31 );
    LWP_MutexInit( &m_mutex, 0 );
}

void CMEM2Alloc::cleanup( void )
{
    LWP_MutexDestroy( m_mutex );
    m_mutex = 0;
    m_first = 0;
    // Try to release the range we took through SYS functions
    if ( SYS_GetArena2Lo() == m_endAddress )
        SYS_SetArena2Lo( m_baseAddress );
    m_baseAddress = 0;
    m_endAddress = 0;
}

void CMEM2Alloc::clear( void )
{
    m_first = 0;
    memset( m_baseAddress, 0, ( u8 * )m_endAddress - ( u8 * )m_endAddress );
}

unsigned int CMEM2Alloc::usableSize( void *p )
{
    return p == 0 ? 0 : ( ( SBlock * )p - 1 )->s * sizeof ( SBlock );
}

void *CMEM2Alloc::allocate( unsigned int s )
{
    if ( s == 0 )
        s = 1;
    //
    LockMutex lock( m_mutex );
    //
    s = ( s - 1 ) / sizeof ( SBlock ) + 1;
    // First block
    if ( m_first == 0 )
    {
        if ( m_baseAddress + s + 1 >= m_endAddress )
            return 0;
        m_first = m_baseAddress;
        m_first->next = 0;
        m_first->prev = 0;
        m_first->s = s;
        m_first->f = false;
        return ( void * )( m_first + 1 );
    }
    // Search for a free block
    SBlock *i;
    SBlock *j;
    for ( i = m_first; i != 0; i = i->next )
    {
        if ( i->f && i->s >= s )
            break;
        j = i;
    }
    // Create a new block
    if ( i == 0 )
    {
        i = j + j->s + 1;
        if ( i + s + 1 >= m_endAddress )
            return 0;
        j->next = i;
        i->prev = j;
        i->next = 0;
        i->s = s;
        i->f = false;
        return ( void * )( i + 1 );
    }
    // Reuse a free block
    i->f = false;
    // Split it
    if ( i->s > s + 1 )
    {
        j = i + s + 1;
        j->f = true;
        j->s = i->s - s - 1;
        i->s = s;
        j->next = i->next;
        j->prev = i;
        i->next = j;
        if ( j->next != 0 )
            j->next->prev = j;
    }
    return ( void * )( i + 1 );
}

void CMEM2Alloc::release( void *p )
{
    if ( p == 0 )
        return;

    LockMutex lock( m_mutex );
    SBlock *i = ( SBlock * )p - 1;
    i->f = true;

    // If there are no other blocks following yet,
    // set the remaining size to free size. - Dimok
    if ( i->next == 0 )
        i->s = m_endAddress - i - 1;

    // Merge with previous block
    if ( i->prev != 0 && i->prev->f )
    {
        i = i->prev;
        i->s += i->next->s + 1;
        i->next = i->next->next;
        if ( i->next != 0 )
            i->next->prev = i;
    }
    // Merge with next block
    if ( i->next != 0 && i->next->f )
    {
        i->s += i->next->s + 1;
        i->next = i->next->next;
        if ( i->next != 0 )
            i->next->prev = i;
    }
}

void *CMEM2Alloc::reallocate( void *p, unsigned int s )
{
    SBlock *i;
    SBlock *j;
    void *n;

    if ( s == 0 )
        s = 1;
    if ( p == 0 )
        return allocate( s );

    i = ( SBlock * )p - 1;
    s = ( s - 1 ) / sizeof ( SBlock ) + 1;
    {
        LockMutex lock( m_mutex );

        //out of memory /* Dimok */
        if ( i + s + 1 >= m_endAddress )
        {
            return 0;
        }

        // Last block
        if ( i->next == 0 && i + s + 1 < m_endAddress )
        {
            i->s = s;
            return p;
        }
        // Size <= current size + next block
        if ( i->next != 0 && i->s < s && i->next->f && i->s + i->next->s + 1 >= s )
        {
            // Merge
            i->s += i->next->s + 1;
            i->next = i->next->next;
            if ( i->next != 0 )
                i->next->prev = i;
        }
        // Size <= current size
        if ( i->s >= s )
        {
            // Split
            if ( i->s > s + 1 )
            {
                j = i + s + 1;
                j->f = true;
                j->s = i->s - s - 1;
                i->s = s;
                j->next = i->next;
                j->prev = i;
                i->next = j;
                if ( j->next != 0 )
                    j->next->prev = j;
            }
            return p;
        }
    }
    // Size > current size
    n = allocate( s * sizeof ( SBlock ) );
    if ( n == 0 )
        return 0;
    memcpy( n, p, i->s * sizeof ( SBlock ) );
    release( p );
    return n;
}

unsigned int CMEM2Alloc::FreeSize()
{
    LockMutex lock( m_mutex );

    if ( m_first == 0 )
        return ( const char * ) m_endAddress - ( const char * ) m_baseAddress;

    SBlock *i;
    unsigned int size = 0;

    for ( i = m_first; i != 0; i = i->next )
    {
        if ( i->f && i->next != 0 )
            size += i->s;

        else if ( i->f && i->next == 0 )
            size += m_endAddress - i - 1;

        else if ( !i->f && i->next == 0 )
            size += m_endAddress - i - i->s - 1;
    }

    return size*sizeof( SBlock );
}