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ID:XD XDI Specification for DESQview Quarterdeck Technical Note by Daniel Travison Q: How can my device driver/TSR work better with DESQview? DESQview's External Device Interface DESQview version 2.26 (and above), can issue informative messages to third party software in order for that software to monitor certain DESQview operations such as starting a task or swapping out a process. These messages can be useful for determining when to allocate/deallocate resources (e.g., memory) on a process by process basis, communicating with tasks running within DESQview, rescheduling tasks, tracking DESQview's task switching, etc. DESQview provides this information through the External Device Interface (XDI) - Quarterdeck's specification for communicating with external drivers. An XDI driver may be implemented either as a DOS device driver (loaded by CONFIG.SYS), a Terminate and Stay Resident program (TSR) loaded before or after DESQview, or as a DESQview shared program (shared among several processes). For the rest of this documentation, the term 'driver' will normally refer to a program that uses the XDI irrespective of its method of implementation (device driver, TSR or shared program). Also, any number of XDI drivers can be loaded. When DESQview starts, it simply attaches itself to the XDI chain and starts sending XDI messages to to previously loaded XDI drivers. Within the XDI, there are 15 subfunctions (messages). Fourteen of these messages inform the driver what action DESQview has just performed or is about to perform. Your driver can choose to ignore the message and pass it on to the next driver in the chain, perform/schedule work based on the message, or save information for later use (e.g., the current mapping context). XDI_CHECK_PRESENCE Check for XDI driver presence XDI_RESERVED_SUBFUNC XDI driver custom subfunction XDI_START_DV DV system initialization complete XDI_END_DV DV system termination XDI_START_PROC DV process creation XDI_END_PROC DV process termination XDI_START_TASK Task creation XDI_END_TASK Task termination XDI_SAVE_STATE Task state save XDI_RESTORE_STATE Task state restore XDI_KEYBOARD Change of keyboard focus XDI_PROCESS_DVP Processing of DVP file complete XDI_SWAPPING_OUT Swap out of DV process XDI_SWAPPED_IN Swap in of DV process XDI_FAILED_DVP DV process creation failure An XDI driver can schedule second level handlers to make API calls, collect data, transfer data, dispatch tasks, perform initialization/termination when DESQview is started and quit. The fifteenth subfunction, XDI_RESERVED_SUBFUNC provides a method for applications to communicate with your driver without needing to grab an additional interrupt vector. Additionally, this interface does not require DESQview to be loaded. In other words, if DESQview is not loaded, the application and XDI driver will still be able to communicate. Q: When would I want to use the XDI specification? If your driver needs to write into an application's address space then you need to ensure that the address is valid when you perform the write. (e.g., The DOS SETDTA call requires the caller provide a pointer to a buffer that will be filled in at a later time. A communications handler might use a similar interface but perform the update at interrupt time.) With DESQview, this buffer may get mapped in and out to accomodate running multiple programs. If your driver attempts to write into this buffer when DESQview has mapped some other application into it (e.g., at interrupt time) then you will be corrupting the unknown application. The XDI allows your driver to determine when the write operation is safe or specifically request that DESQview map the application in to allow safe access to the application's address space. Another example is the use of Multiplex boards. Multiplex boards have two important features: One, they provide access to multiple external devices (e.g., modems) using a single IRQ and two, they provide a software interface for applications. The software interface removes the need for the application to manage the hardware directly. In the case of a multiplex board providing additional serial ports, the user will often want to run more than one program at a time to take advantage extra serial ports. (e.g., A number of BBS systems provide the option for running multiple copies at once and also support drivers for multiplex boards.) The programmer writing the driver will need to accomodate simultaneous access to the driver as well as provide a reliable software interface. Other issues addressed by the XDI: 1) Allocation of a software interrupt to allow the application to communicate with the driver. With more and more device drivers and TSR's available, it is important to prevent possible conflicts with other software. The XDI specification uses the multiplex interrupt (INT 2Fh) as a basis for sharing a single interrupt using a well defined interface. Once the application has 'logged' itself with the driver (XDI_RESERVED_SUBFUNC), the driver might provide an ID for future use or simply manage it internally based on which process DESQview has mapped in when the software interrupt is called. This portion of the interface functions in the same manner whether DESQview is loaded or not. When DESQview is not present, the driver does not need to be concerned with the mapping context. 2) Allocation of memory/application that needs to be accessible at any given time. This might be a buffer for incoming data. Normally, the driver would need to allocate all of its memory needs during its initialization code. DESQview allows an XDI driver to allocate COMMON memory (memory that does not get mapped out) during an XDI call. This allows the driver to allocate only the memory necessary when a new application starts. It DESQview is not present, the application would allocate a buffer out of its own data space. A check for DESQview would be all that is necessary for the application to determine whether it needs to allocate a buffer or allow the driver to allocate it from COMMON memory. 3) Preventing reentrancy during non-reentrant sections of code. In a perfect world, all of your driver's code would be reentrant. Since this may not be practical without unreasonble code or CPU overhead, the XDI driver can temporarily suspend multitasking to perform its critical work. This does not mean that the XDI allows you to write non-reentrant handlers but it can solve some sticky issues that arise when you need to support simultaneous access. 4) The application can not keep up with the data rate. There will be times when the application can not empty the driver's buffer faster than the driver can fill it. The user may have started up a few extra applications and the CPU is too slow to give everyone enough time. The XDI driver could consider some percentage of the buffer as a threshold. When this threshold is reached the driver can temporarily override DESQview's dispatcher and force the application's 'buffer management' routine to execute at the next context switch. 5) The driver needs to know when the application exits to allow proper cleanup. Normally, the application itself would call the driver to initiate cleanup. Occasionally this will not occur (e.g., the user shut down the application via DESQview's Close Window menu selection). DESQview notifies the XDI driver when a process ends to allow the driver to determine if it needs to perform any cleanup for the process. There are other areas where an XDI driver would be of use; resource tracking on a process by process basis, modifying the .DVP when each process starts, allocating additional system memory for the process at startup, tracking CPU usage, or even displacing DESQview's dispatcher. Q: How do I find out more about the XDI? DESQview's XDI is fully documented in Quarterdeck's API Reference Manual (versions 1.20 and later). Included is a sample XDI driver (POKEXDI.ASM) that can be used as a template for designing your own. Contact Quarterdeck for information on obtaining a copy of our API Reference Manual or upgrading and older API Reference Manual. Copyright (C) 1990 by Quarterdeck Office Systems * * * E N D O F F I L E * * *