| okay, here are some hints for debugging the lower-level parts of |
| linux/parisc. |
| |
| |
| 1. Absolute addresses |
| |
| A lot of the assembly code currently runs in real mode, which means |
| absolute addresses are used instead of virtual addresses as in the |
| rest of the kernel. To translate an absolute address to a virtual |
| address you can lookup in System.map, add __PAGE_OFFSET (0x10000000 |
| currently). |
| |
| |
| 2. HPMCs |
| |
| When real-mode code tries to access non-existent memory, you'll get |
| an HPMC instead of a kernel oops. To debug an HPMC, try to find |
| the System Responder/Requestor addresses. The System Requestor |
| address should match (one of the) processor HPAs (high addresses in |
| the I/O range); the System Responder address is the address real-mode |
| code tried to access. |
| |
| Typical values for the System Responder address are addresses larger |
| than __PAGE_OFFSET (0x10000000) which mean a virtual address didn't |
| get translated to a physical address before real-mode code tried to |
| access it. |
| |
| |
| 3. Q bit fun |
| |
| Certain, very critical code has to clear the Q bit in the PSW. What |
| happens when the Q bit is cleared is the CPU does not update the |
| registers interruption handlers read to find out where the machine |
| was interrupted - so if you get an interruption between the instruction |
| that clears the Q bit and the RFI that sets it again you don't know |
| where exactly it happened. If you're lucky the IAOQ will point to the |
| instrucion that cleared the Q bit, if you're not it points anywhere |
| at all. Usually Q bit problems will show themselves in unexplainable |
| system hangs or running off the end of physical memory. |