The state of every card (I/O addresses, IRQs, ...) is stored into a driver-specific structure that is passed (directly or indirectly) to every entry point of the driver which can this way differenciate the cards. That way the very same code can control different cards (which means that yes, the kernel only keeps one instance of a driver's module no matter the number of devices it controls).
For instance, have a look at
drivers/video/backlight/platform_lcd.c, which is a very simple LCD power driver. It contains a structure called
platform_lcd that is private to this file and stores the state of the LCD (whether it is powered, and whether it is suspended). One instance of this structure is allocated in the
probe function of the driver through
kzalloc - that is, one per LCD device - and stored into the platform device representing the LCD using
platform_set_drvdata. The instance that has been allocated for this device is then fetched back at the beginning of all other driver functions so that it knows which instance it is working on:
struct platform_lcd *plcd = to_our_lcd(lcd);
to_our_lcd expands to
lcd_get_data which itself expands to
dev_get_drvdata (a counterpart of platform_set_drvdata) if you look at
include/linux/lcd.h. The function can then know the state of the device is has been invoked for.
This is a very simple example, and the
platform_lcd driver does not directly control any device (this is deferred to a function pointer in the platform data), but add hardware-specific parameters (IRQ, I/O base, etc.) and you get how 99% of the drivers in Linux work.