Writing network drivers for KolibriOS: Difference between revisions
(Created page with 'So, you want to write a new network driver for KolibriOS ? Or you are just curious about how they work? Well, since a driver for an ethernet, pci card, such as the rtl8139, actua...') |
No edit summary |
||
Line 10: | Line 10: | ||
;A program can communicate directly with the driver, using system function 68/17 | ;A program can communicate directly with the driver, using system function 68/17 | ||
== IOCTL input == | |||
Here is a list of opcodes the network drivers should accept trhough the IOCTL structure: | |||
Here is a list of opcodes: | |||
;0 - Getversion | ;0 - Getversion | ||
standard for all drivers, not only network drivers | standard for all drivers, not only network drivers | ||
Line 37: | Line 25: | ||
irq_line db ? | irq_line db ? | ||
</asm> | </asm> | ||
OUT:<br> | |||
eax = device number or -1 on error | |||
--or-- | |||
IN: (PCI) | IN: (PCI) | ||
Line 47: | Line 40: | ||
OUT:<br> | OUT:<br> | ||
eax = device number or -1 on error | eax = device number or -1 on error | ||
== The device stucture == | == The device stucture == |
Revision as of 17:47, 19 July 2010
So, you want to write a new network driver for KolibriOS ? Or you are just curious about how they work? Well, since a driver for an ethernet, pci card, such as the rtl8139, actually isnt that hard to understand, I advice you to read the code of a driver and try to understand it.</ br>
Here are some facts, summed op in no-particular order
- Drivers are designed to handle more then one devices at once.
- All device specific data is stored in a structure called the 'device structure'.
- Network drivers are loaded by a program (NetCfg).
- A program can communicate directly with the driver, using system function 68/17
IOCTL input
Here is a list of opcodes the network drivers should accept trhough the IOCTL structure:
- 0 - Getversion
standard for all drivers, not only network drivers
- 1 - Hook
Attach driver to a device
IN: (ISA) <asm> type db 0 ; isa io_addr dw ? irq_line db ? </asm>
OUT:
eax = device number or -1 on error
--or--
IN: (PCI) <asm> type db 1 ; pci pci_bus db ? pci_dev db ? </asm>
OUT:
eax = device number or -1 on error
The device stucture
Once the HOOK function of the driver has been called, the driver creates the NET_DEVICE structure, allocates some buffers needed for the driver, validates if a given device is supported by the driver, and calls the kernel function 'NetRegDev'.
This function registers a network device (device, not driver!) to the kernel, it only needs one parameter: pointer to device structure (NET_DEVICE) in ebx.
The function returns the device number in edi (..wich the driver then sends to the application in eax)
This NET_DEVICE structure is created and filled in by the driver for every device it is hooked to.
The driver may use this to store pointers to buffers, descriptors,.. etc
The top of the structure must always look like this: (Since it is shared by the driver and the kernel)
(it is defined in netdrv.inc)
<asm> NET_DEVICE:
.type dd ? ; Type field (ethernet/slip/...) .mtu dd ? ; Maximal Transmission Unit (in bytes) .name dd ? ; Ptr to 0 terminated string
.unload dd ? ; Ptrs to driver functions .reset dd ? ; .transmit dd ? ;
.bytes_tx dq ? ; Statistics, updated by the driver .bytes_rx dq ? ; .packets_tx dd ? ; .packets_rx dd ? ;
.end:
</asm>
This is appended by a Type-specific structure, for ethernet this will be:
<asm>
.set_mode dd ? .get_mode dd ?
.set_MAC dd ? .get_MAC dd ?
.mode dd ? .mac dp ?
</asm>
Wich is then followed by the private data, the driver uses to store information about the device.
When a packet is received by the driver, the driver copies it into a buffer allocated using 'KernelAlloc'.
Then the driver pushes the size of the buffer and the pointer to the buffer onto the stack (both are dwords, and must be pushed in this particular order)
And it calls 'EthReceiver' (or another procedure for another network device type).
This kernel function will return with the 2 dwords removed from the stack.
When the kernel needs to send a packet, it simple looks up the appropriate driver in it's driver table.
In the table it will find the pointer to the device structure, so the driver can directly call the transmit function listed in the structure.
The kernel will, similary to the driver, when receiving a packet, push the size of packet, and pointer to packet, onto the stack.
....More to come..