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| 1 | +=============================================== |
| 2 | +Power Architecture 64-bit Linux system call ABI |
| 3 | +=============================================== |
| 4 | + |
| 5 | +syscall |
| 6 | +======= |
| 7 | + |
| 8 | +syscall calling sequence[*] matches the Power Architecture 64-bit ELF ABI |
| 9 | +specification C function calling sequence, including register preservation |
| 10 | +rules, with the following differences. |
| 11 | + |
| 12 | +[*] Some syscalls (typically low-level management functions) may have |
| 13 | + different calling sequences (e.g., rt_sigreturn). |
| 14 | + |
| 15 | +Parameters and return value |
| 16 | +--------------------------- |
| 17 | +The system call number is specified in r0. |
| 18 | + |
| 19 | +There is a maximum of 6 integer parameters to a syscall, passed in r3-r8. |
| 20 | + |
| 21 | +Both a return value and a return error code are returned. cr0.SO is the return |
| 22 | +error code, and r3 is the return value or error code. When cr0.SO is clear, |
| 23 | +the syscall succeeded and r3 is the return value. When cr0.SO is set, the |
| 24 | +syscall failed and r3 is the error code that generally corresponds to errno. |
| 25 | + |
| 26 | +Stack |
| 27 | +----- |
| 28 | +System calls do not modify the caller's stack frame. For example, the caller's |
| 29 | +stack frame LR and CR save fields are not used. |
| 30 | + |
| 31 | +Register preservation rules |
| 32 | +--------------------------- |
| 33 | +Register preservation rules match the ELF ABI calling sequence with the |
| 34 | +following differences: |
| 35 | + |
| 36 | +r0: Volatile. (System call number.) |
| 37 | +r3: Volatile. (Parameter 1, and return value.) |
| 38 | +r4-r8: Volatile. (Parameters 2-6.) |
| 39 | +cr0: Volatile (cr0.SO is the return error condition) |
| 40 | +cr1, cr5-7: Nonvolatile. |
| 41 | +lr: Nonvolatile. |
| 42 | + |
| 43 | +All floating point and vector data registers as well as control and status |
| 44 | +registers are nonvolatile. |
| 45 | + |
| 46 | +Invocation |
| 47 | +---------- |
| 48 | +The syscall is performed with the sc instruction, and returns with execution |
| 49 | +continuing at the instruction following the sc instruction. |
| 50 | + |
| 51 | +Transactional Memory |
| 52 | +-------------------- |
| 53 | +Syscall behavior can change if the processor is in transactional or suspended |
| 54 | +transaction state, and the syscall can affect the behavior of the transaction. |
| 55 | + |
| 56 | +If the processor is in suspended state when a syscall is made, the syscall |
| 57 | +will be performed as normal, and will return as normal. The syscall will be |
| 58 | +performed in suspended state, so its side effects will be persistent according |
| 59 | +to the usual transactional memory semantics. A syscall may or may not result |
| 60 | +in the transaction being doomed by hardware. |
| 61 | + |
| 62 | +If the processor is in transactional state when a syscall is made, then the |
| 63 | +behavior depends on the presence of PPC_FEATURE2_HTM_NOSC in the AT_HWCAP2 ELF |
| 64 | +auxiliary vector. |
| 65 | + |
| 66 | +- If present, which is the case for newer kernels, then the syscall will not |
| 67 | + be performed and the transaction will be doomed by the kernel with the |
| 68 | + failure code TM_CAUSE_SYSCALL | TM_CAUSE_PERSISTENT in the TEXASR SPR. |
| 69 | + |
| 70 | +- If not present (older kernels), then the kernel will suspend the |
| 71 | + transactional state and the syscall will proceed as in the case of a |
| 72 | + suspended state syscall, and will resume the transactional state before |
| 73 | + returning to the caller. This case is not well defined or supported, so this |
| 74 | + behavior should not be relied upon. |
| 75 | + |
| 76 | + |
| 77 | +vsyscall |
| 78 | +======== |
| 79 | + |
| 80 | +vsyscall calling sequence matches the syscall calling sequence, with the |
| 81 | +following differences. Some vsyscalls may have different calling sequences. |
| 82 | + |
| 83 | +Parameters and return value |
| 84 | +--------------------------- |
| 85 | +r0 is not used as an input. The vsyscall is selected by its address. |
| 86 | + |
| 87 | +Stack |
| 88 | +----- |
| 89 | +The vsyscall may or may not use the caller's stack frame save areas. |
| 90 | + |
| 91 | +Register preservation rules |
| 92 | +--------------------------- |
| 93 | +r0: Volatile. |
| 94 | +cr1, cr5-7: Volatile. |
| 95 | +lr: Volatile. |
| 96 | + |
| 97 | +Invocation |
| 98 | +---------- |
| 99 | +The vsyscall is performed with a branch-with-link instruction to the vsyscall |
| 100 | +function address. |
| 101 | + |
| 102 | +Transactional Memory |
| 103 | +-------------------- |
| 104 | +vsyscalls will run in the same transactional state as the caller. A vsyscall |
| 105 | +may or may not result in the transaction being doomed by hardware. |
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