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our manual ".code32" will break a KEEP_IT_REAL build. |
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firmware/pcbios | ||
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transitions | ||
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kir-Makefile | ||
Makefile | ||
README.i386 |
Etherboot/NILO i386 initialisation path and external call interface =================================================================== 1. Background GCC compiles 32-bit code. It is capable of producing position-independent code, but the resulting binary is about 25% bigger than the corresponding fixed-position code. Since one main use of Etherboot is as firmware to be burned into an EPROM, code size must be kept as small as possible. This means that we want to compile fixed-position code with GCC, and link it to have a predetermined start address. The problem then is that we must know the address that the code will be loaded to when it runs. There are several ways to solve this: 1. Pick an address, link the code with this start address, then make sure that the code gets loaded at that location. This is problematic, because we may pick an address that we later end up wanting to use to load the operating system that we're booting. 2. Pick an address, link the code with this start address, then set up virtual addressing so that the virtual addresses match the link-time addresses regardless of the real physical address that the code is loaded to. This enables us to relocate Etherboot to the top of high memory, where it will be out of the way of any loading operating system. 3. Link the code with a text start address of zero and a data start address also of zero. Use 16-bit real mode and the quasi-position-independence it gives you via segment addressing. Doing this requires that we generate 16-bit code, rather than 32-bit code, and restricts us to a maximum of 64kB in each segment. There are other possible approaches (e.g. including a relocation table and code that performs standard dynamic relocation), but the three options listed above are probably the best available. Etherboot can be invoked in a variety of ways (ROM, floppy, as a PXE NBP, etc). Several of these ways involve control being passed to Etherboot with the CPU in 16-bit real mode. Some will involve the CPU being in 32-bit protected mode, and there's an outside chance that some may involve the CPU being in 16-bit protected mode. We will almost certainly have to effect a CPU mode change in order to reach the mode we want to be in to execute the C code. Additionally, Etherboot may wish to call external routines, such as BIOS interrupts, which must be called in 16-bit real mode. When providing a PXE API, Etherboot must provide a mechanism for external code to call it from 16-bit real mode. Not all i386 builds of Etherboot will want to make real-mode calls. For example, when built for LinuxBIOS rather than the standard PCBIOS, no real-mode calls are necessary. For the ultimate in PXE compatibility, we may want to build Etherboot to run permanently in real mode. There is a wide variety of potential combinations of mode switches that we may wish to implement. There are additional complications, such as the inability to access a high-memory stack when running in real mode. 2. Transition libraries To handle all these various combinations of mode switches, we have several "transition" libraries in Etherboot. We also have the concept of an "internal" and an "external" environment. The internal environment is the environment within which we can execute C code. The external environment is the environment of whatever external code we're trying to interface to, such as the system BIOS or a PXE NBP. As well as having a separate addressing scheme, the internal environment also has a separate stack. The transition libraries are: a) librm librm handles transitions between an external 16-bit real-mode environment and an internal 32-bit protected-mode environment with virtual addresses. b) libkir libkir handles transitions between an external 16-bit real-mode (or 16:16 or 16:32 protected-mode) environment and an internal 16-bit real-mode (or 16:16 protected-mode) environment. c) libpm libpm handles transitions between an external 32-bit protected-mode environment with flat physical addresses and an internal 32-bit protected-mode environment with virtual addresses. The transition libraries handle the transitions required when Etherboot is started up for the first time, the transitions required to execute any external code, and the transitions required when Etherboot exits (if it exits). When Etherboot provides a PXE API, they also handle the transitions required when a PXE client makes a PXE API call to Etherboot. Etherboot may use multiple transition libraries. For example, an Etherboot ELF image does not require librm for its initial transitions from prefix to runtime, but may require librm for calling external real-mode functions. 3. Setup and initialisation Etherboot is conceptually divided into the prefix, the decompressor, and the runtime image. (For non-compressed images, the decompressor is a no-op.) The complete image comprises all three parts and is distinct from the runtime image, which exclude the prefix and the decompressor. The prefix does several tasks: Load the complete image into memory. (For example, the floppy prefix issues BIOS calls to load the remainder of the complete image from the floppy disk into RAM, and the ISA ROM prefix copies the ROM contents into RAM for faster access.) Call the decompressor, if the runtime image is compressed. This decompresses the runtime image. Call the runtime image's setup() routine. This is a routine implemented in assembly code which sets up the internal environment so that C code can execute. Call the runtime image's arch_initialise() routine. This is a routine implemented in C which does some basic startup tasks, such as initialising the console device, obtaining a memory map and relocating the runtime image to high memory. Call the runtime image's arch_main() routine. This records the exit mechanism requested by the prefix and calls main(). (The prefix needs to register an exit mechanism because by the time main() returns, the memory occupied by the prefix has most likely been overwritten.) When acting as a PXE ROM, the ROM prefix contains an UNDI loader routine in addition to its usual code. The UNDI loader performs a similar sequence of steps: Load the complete image into memory. Call the decompressor. Call the runtime image's setup() routine. Call the runtime image's arch_initialise() routine. Call the runtime image's install_pxe_stack() routine. Return to caller. The runtime image's setup() routine will perform the following steps: Switch to the internal environment using an appropriate transition library. This will record the parameters of the external environment. Set up the internal environment: load a stack, and set up a GDT for virtual addressing if virtual addressing is to be used. Switch back to the external environment using the transition library. This will record the parameters of the internal environment. Once the setup() routine has returned, the internal environment has been set up ready for C code to run. The prefix can call C routines using a function from the transition library. The runtime image's arch_initialise() routine will perform the following steps: Zero the bss Initialise the console device(s) and print a welcome message. Obtain a memory map via the INT 15,E820 BIOS call or suitable fallback mechanism. [not done if libkir is being used] Relocate the runtime image to the top of high memory. [not done if libkir is being used] Install librm to base memory. [done only if librm is being used] Call initialise(). Return to the prefix, setting registers to indicate to the prefix the new location of the transition library, if applicable. Which registers these are is specific to the transition library being used. Once the arch_initialise() routine has returned, the prefix will probably call arch_main().