* Acess2 IDE Harddisk Driver
* drv/ide.c
*/
+#define DEBUG 0
#include <common.h>
#include <modules.h>
#include <vfs.h>
#include <fs_devfs.h>
#include <drv_pci.h>
#include <tpl_drv_common.h>
+#include <drvutil.h>
// === CONSTANTS ===
#define MAX_ATA_DISKS 4
// === PROTOTYPES ===
int ATA_Install();
int ATA_SetupIO();
-static void ATA_SetupPartitions();
- void ATA_SetupVFS();
+void ATA_SetupPartitions();
+void ATA_SetupVFS();
int ATA_ScanDisk(int Disk);
void ATA_ParseGPT(int Disk);
void ATA_ParseMBR(int Disk);
void ATA_int_MakePartition(tATA_Partition *Part, int Disk, int Num, Uint64 Start, Uint64 Length);
Uint16 ATA_GetBasePort(int Disk);
+// Filesystem Interface
char *ATA_ReadDir(tVFS_Node *Node, int Pos);
tVFS_Node *ATA_FindDir(tVFS_Node *Node, char *Name);
Uint64 ATA_ReadFS(tVFS_Node *Node, Uint64 Offset, Uint64 Length, void *Buffer);
+Uint64 ATA_WriteFS(tVFS_Node *Node, Uint64 Offset, Uint64 Length, void *Buffer);
int ATA_IOCtl(tVFS_Node *Node, int Id, void *Data);
- int ATA_Read(Uint8 Disk, Uint64 Address, Uint64 Count, void *Buffer);
+// Read/Write Interface/Quantiser
+Uint ATA_ReadRaw(Uint64 Address, Uint Count, void *Buffer, Uint Disk);
+Uint ATA_WriteRaw(Uint64 Address, Uint Count, void *Buffer, Uint Disk);
+// Read/Write DMA
int ATA_ReadDMA(Uint8 Disk, Uint64 Address, Uint Count, void *Buffer);
-void ATA_IRQHandlerPri(void);
-void ATA_IRQHandlerSec(void);
+ int ATA_WriteDMA(Uint8 Disk, Uint64 Address, Uint Count, void *Buffer);
+// IRQs
+void ATA_IRQHandlerPri(int unused);
+void ATA_IRQHandlerSec(int unused);
+// Controller IO
Uint8 ATA_int_BusMasterReadByte(int Ofs);
void ATA_int_BusMasterWriteByte(int Ofs, Uint8 Value);
void ATA_int_BusMasterWriteDWord(int Ofs, Uint32 Value);
NULL, "ata",
{
.NumACLs = 1,
+ .Size = -1,
.Flags = VFS_FFLAG_DIRECTORY,
.ACLs = &gVFS_ACL_EveryoneRX,
.ReadDir = ATA_ReadDir,
}
/**
- * \fn static void ATA_SetupPartitions()
+ * \fn void ATA_SetupPartitions()
*/
-static void ATA_SetupPartitions()
+void ATA_SetupPartitions()
{
int i;
for( i = 0; i < MAX_ATA_DISKS; i ++ )
for( j = 0; j < gATA_Disks[i].NumPartitions; j ++ )
gATA_Nodes[ k++ ] = &gATA_Disks[i].Partitions[j].Node;
}
+
+ gATA_DriverInfo.RootNode.Size = giATA_NumNodes;
}
/**
= node->CTime = now();
node->Read = ATA_ReadFS;
- //node->Write = ATA_WriteFS;
+ node->Write = ATA_WriteFS;
node->IOCtl = ATA_IOCtl;
Part->Node.ImplPtr = Part->Name;
Part->Node.Read = ATA_ReadFS;
+ Part->Node.Write = ATA_WriteFS;
Part->Node.IOCtl = ATA_IOCtl;
LOG("Made '%s' (&Node=%p)", Part->Name, &Part->Node);
LEAVE('-');
char *ATA_ReadDir(tVFS_Node *Node, int Pos)
{
if(Pos >= giATA_NumNodes || Pos < 0) return NULL;
- return gATA_Nodes[Pos]->ImplPtr;
+ return strdup( gATA_Nodes[Pos]->ImplPtr );
}
/**
*/
Uint64 ATA_ReadFS(tVFS_Node *Node, Uint64 Offset, Uint64 Length, void *Buffer)
{
- int ret;
- int disk, part;
- Uint64 sector, count;
+ int disk = Node->Inode >> 8;
+ int part = Node->Inode & 0xFF;
- disk = Node->Inode >> 8;
- part = Node->Inode & 0xFF;
-
- // Aligned Read
- if(Offset % SECTOR_SIZE == 0 && Length % SECTOR_SIZE == 0)
+ // Raw Disk Access
+ if(part == 0xFF)
{
- sector = Offset / SECTOR_SIZE;
- count = Length / SECTOR_SIZE;
- // Raw Disk?
- if(part == 0xFF)
- {
- // Bounds Check
- if( sector >= gATA_Disks[disk].Sectors ) return 0;
- if( sector + count > gATA_Disks[disk].Sectors )
- count = gATA_Disks[disk].Sectors - sector;
- // Read Data
- ret = ATA_Read(disk, sector, count, Buffer);
- }
- else // Or a partition
- {
- //Log(" ATA_ReadFS: %i:%i 0x%llx + 0x%llx\n", disk, part,
- // gATA_Disks[disk].Partitions[part].Start,
- // gATA_Disks[disk].Partitions[part].Length );
-
- // Bounds Check
- if( sector >= gATA_Disks[disk].Partitions[part].Length ) return 0;
- if( sector + count > gATA_Disks[disk].Partitions[part].Length )
- count = gATA_Disks[disk].Partitions[part].Length - sector;
- // Read Disk
- ret = ATA_Read(disk,
- gATA_Disks[disk].Partitions[part].Start + sector,
- count,
- Buffer);
- }
- // Check return value
- if(ret == 1)
- return count * SECTOR_SIZE;
- else {
- Warning("ATA_ReadFS: RETURN 0 (Read failed with ret = %i)", ret);
+ if( Offset >= gATA_Disks[disk].Sectors * SECTOR_SIZE )
return 0;
- }
+ if( Offset + Length > gATA_Disks[disk].Sectors*SECTOR_SIZE )
+ Length = gATA_Disks[disk].Sectors*SECTOR_SIZE - Offset;
}
- Warning("ATA_ReadFS: RETURN 0 (Non-Aligned Read 0x%llx 0x%llx)", Offset, Length);
- return 0;
+ // Partition
+ else
+ {
+ if( Offset >= gATA_Disks[disk].Partitions[part].Length * SECTOR_SIZE )
+ return 0;
+ if( Offset + Length > gATA_Disks[disk].Partitions[part].Length * SECTOR_SIZE )
+ Length = gATA_Disks[disk].Partitions[part].Length * SECTOR_SIZE - Offset;
+ Offset += gATA_Disks[disk].Partitions[part].Start * SECTOR_SIZE;
+ }
+
+ //Log("ATA_ReadFS: (Node=%p, Offset=0x%llx, Length=0x%llx, Buffer=%p)", Node, Offset, Length, Buffer);
+ return DrvUtil_ReadBlock(Offset, Length, Buffer, ATA_ReadRaw, SECTOR_SIZE, disk);
}
/**
*/
Uint64 ATA_WriteFS(tVFS_Node *Node, Uint64 Offset, Uint64 Length, void *Buffer)
{
- return 0;
+ int disk = Node->Inode >> 8;
+ int part = Node->Inode & 0xFF;
+
+ // Raw Disk Access
+ if(part == 0xFF)
+ {
+ if( Offset >= gATA_Disks[disk].Sectors * SECTOR_SIZE )
+ return 0;
+ if( Offset + Length > gATA_Disks[disk].Sectors*SECTOR_SIZE )
+ Length = gATA_Disks[disk].Sectors*SECTOR_SIZE - Offset;
+ }
+ // Partition
+ else
+ {
+ if( Offset >= gATA_Disks[disk].Partitions[part].Length * SECTOR_SIZE )
+ return 0;
+ if( Offset + Length > gATA_Disks[disk].Partitions[part].Length * SECTOR_SIZE )
+ Length = gATA_Disks[disk].Partitions[part].Length * SECTOR_SIZE - Offset;
+ Offset += gATA_Disks[disk].Partitions[part].Start * SECTOR_SIZE;
+ }
+
+ Log("ATA_WriteFS: (Node=%p, Offset=0x%llx, Length=0x%llx, Buffer=%p)", Node, Offset, Length, Buffer);
+ Debug_HexDump("ATA_WriteFS", Buffer, Length);
+ return DrvUtil_WriteBlock(Offset, Length, Buffer, ATA_ReadRaw, ATA_WriteRaw, SECTOR_SIZE, disk);
}
/**
// --- Disk Access ---
/**
- * \fn int ATA_Read(Uint8 Disk, Uint64 Address, Uint64 Count, void *Buffer)
+ * \fn Uint ATA_ReadRaw(Uint64 Address, Uint Count, void *Buffer, Uint Disk)
*/
-int ATA_Read(Uint8 Disk, Uint64 Address, Uint64 Count, void *Buffer)
+Uint ATA_ReadRaw(Uint64 Address, Uint Count, void *Buffer, Uint Disk)
{
int ret;
Uint offset;
+ Uint done = 0;
// Pass straight on to ATA_ReadDMAPage if we can
if(Count <= MAX_DMA_SECTORS)
- return ATA_ReadDMA(Disk, Address, Count, Buffer);
+ {
+ ret = ATA_ReadDMA(Disk, Address, Count, Buffer);
+ if(ret == 0) return 0;
+ return Count;
+ }
// Else we will have to break up the transfer
offset = 0;
{
ret = ATA_ReadDMA(Disk, Address+offset, MAX_DMA_SECTORS, Buffer+offset);
// Check for errors
- if(ret != 1) return ret;
+ if(ret != 1) return done;
// Change Position
+ done += MAX_DMA_SECTORS;
Count -= MAX_DMA_SECTORS;
offset += MAX_DMA_SECTORS*SECTOR_SIZE;
}
- return ATA_ReadDMA(Disk, Address+offset, Count, Buffer+offset);
+ ret = ATA_ReadDMA(Disk, Address+offset, Count, Buffer+offset);
+ if(ret != 1) return 0;
+ return done+Count;
}
/**
- * \fn int ATA_ReadDMAPage(Uint8 Disk, Uint64 Address, Uint Count, void *Buffer)
+ * \fn Uint ATA_WriteRaw(Uint64 Address, Uint Count, void *Buffer, Uint Disk)
+ */
+Uint ATA_WriteRaw(Uint64 Address, Uint Count, void *Buffer, Uint Disk)
+{
+ int ret;
+ Uint offset;
+ Uint done = 0;
+
+ // Pass straight on to ATA_WriteDMA if we can
+ if(Count <= MAX_DMA_SECTORS)
+ {
+ ret = ATA_WriteDMA(Disk, Address, Count, Buffer);
+ if(ret == 0) return 0;
+ return Count;
+ }
+
+ // Else we will have to break up the transfer
+ offset = 0;
+ while(Count > MAX_DMA_SECTORS)
+ {
+ ret = ATA_WriteDMA(Disk, Address+offset, MAX_DMA_SECTORS, Buffer+offset);
+ // Check for errors
+ if(ret != 1) return done;
+ // Change Position
+ done += MAX_DMA_SECTORS;
+ Count -= MAX_DMA_SECTORS;
+ offset += MAX_DMA_SECTORS*SECTOR_SIZE;
+ }
+
+ ret = ATA_WriteDMA(Disk, Address+offset, Count, Buffer+offset);
+ if(ret != 1) return 0;
+ return done+Count;
+}
+
+/**
+ * \fn int ATA_ReadDMA(Uint8 Disk, Uint64 Address, Uint Count, void *Buffer)
*/
int ATA_ReadDMA(Uint8 Disk, Uint64 Address, Uint Count, void *Buffer)
{
Uint16 base;
// Check if the count is small enough
- if(Count > MAX_DMA_SECTORS) return -1;
+ if(Count > MAX_DMA_SECTORS) return 0;
// Get exclusive access to the disk controller
LOCK( &giaATA_ControllerLock[ cont ] );
ATA_int_BusMasterWriteByte( cont << 3, 9 ); // Read and start
// Wait for transfer to complete
- while( gaATA_IRQs[cont] == 0 ) Proc_Yield();
+ while( gaATA_IRQs[cont] == 0 ) Threads_Yield();
// Complete Transfer
ATA_int_BusMasterWriteByte( cont << 3, 0 ); // Write and stop
}
/**
- * \fn void ATA_IRQHandlerPri(void)
+ * \fn int ATA_WriteDMA(Uint8 Disk, Uint64 Address, Uint Count, void *Buffer)
+ */
+int ATA_WriteDMA(Uint8 Disk, Uint64 Address, Uint Count, void *Buffer)
+{
+ int cont = (Disk>>1)&1; // Controller ID
+ int disk = Disk & 1;
+ Uint16 base;
+
+ // Check if the count is small enough
+ if(Count > MAX_DMA_SECTORS) return 0;
+
+ // Get exclusive access to the disk controller
+ LOCK( &giaATA_ControllerLock[ cont ] );
+
+ // Set Size
+ gATA_PRDTs[ cont ].Bytes = Count * SECTOR_SIZE;
+
+ // Get Port Base
+ base = ATA_GetBasePort(Disk);
+
+ // Set up transfer
+ outb(base+0x01, 0x00);
+ if( Address > 0x0FFFFFFF ) // Use LBA48
+ {
+ outb(base+0x6, 0x40 | (disk << 4));
+ outb(base+0x2, 0 >> 8); // Upper Sector Count
+ outb(base+0x3, Address >> 24); // Low 2 Addr
+ outb(base+0x3, Address >> 28); // Mid 2 Addr
+ outb(base+0x3, Address >> 32); // High 2 Addr
+ }
+ else
+ {
+ outb(base+0x06, 0xE0 | (disk << 4) | ((Address >> 24) & 0x0F)); //Disk,Magic,High addr
+ }
+
+ outb(base+0x02, (Uint8) Count); // Sector Count
+ outb(base+0x03, (Uint8) Address); // Low Addr
+ outb(base+0x04, (Uint8) (Address >> 8)); // Middle Addr
+ outb(base+0x05, (Uint8) (Address >> 16)); // High Addr
+ if( Address > 0x0FFFFFFF )
+ outb(base+0x07, HDD_DMA_W48); // Write Command (LBA48)
+ else
+ outb(base+0x07, HDD_DMA_W28); // Write Command (LBA28)
+
+ // Reset IRQ Flag
+ gaATA_IRQs[cont] = 0;
+
+ // Copy to output buffer
+ memcpy( gATA_Buffers[cont], Buffer, Count*SECTOR_SIZE );
+
+ // Start transfer
+ ATA_int_BusMasterWriteByte( cont << 3, 1 ); // Write and start
+
+ // Wait for transfer to complete
+ while( gaATA_IRQs[cont] == 0 ) Threads_Yield();
+
+ // Complete Transfer
+ ATA_int_BusMasterWriteByte( cont << 3, 0 ); // Write and stop
+
+ // Release controller lock
+ RELEASE( &giaATA_ControllerLock[ cont ] );
+
+ return 1;
+}
+
+/**
+ * \fn void ATA_IRQHandlerPri(int unused)
*/
-void ATA_IRQHandlerPri(void)
+void ATA_IRQHandlerPri(int unused)
{
Uint8 val;
}
/**
- * \fn void ATA_IRQHandlerSec(void)
+ * \fn void ATA_IRQHandlerSec(int unused)
*/
-void ATA_IRQHandlerSec(void)
+void ATA_IRQHandlerSec(int unused)
{
Uint8 val;
// IRQ bit set for Secondary Controller