ref: 0fd4ad8016cecf7210e64e9878d2cd6861a72fbf
dir: /sys/src/9/teg2/arm.s/
/* * nvidia tegra 2 machine assist, definitions * dual-core cortex-a9 processor * * R9 and R10 are used for `extern register' variables. * R11 is used by the loader as a temporary, so avoid it. */ #include "mem.h" #include "arm.h" #undef B /* B is for 'botch' */ #define KADDR(pa) (KZERO | ((pa) & ~KSEGM)) #define PADDR(va) (PHYSDRAM | ((va) & ~KSEGM)) #define L1X(va) (((((va))>>20) & 0x0fff)<<2) #define MACHADDR (L1-MACHSIZE) /* only room for cpu0's */ /* L1 pte values */ #define PTEDRAM (Dom0|L1AP(Krw)|Section|L1ptedramattrs) #define PTEIO (Dom0|L1AP(Krw)|Section) #define DOUBLEMAPMBS 512 /* megabytes of low dram to double-map */ /* steps on R0 */ #define DELAY(label, mloops) \ MOVW $((mloops)*1000000), R0; \ label: \ SUB.S $1, R0; \ BNE label /* print a byte on the serial console; clobbers R0 & R6; needs R12 (SB) set */ #define PUTC(c) \ BARRIERS; \ MOVW $(c), R0; \ MOVW $PHYSCONS, R6; \ MOVW R0, (R6); \ BARRIERS /* * new instructions */ #define SMC WORD $0xe1600070 /* low 4-bits are call # (trustzone) */ /* flush branch-target cache */ #define FLBTC MTCP CpSC, 0, PC, C(CpCACHE), C(CpCACHEinvi), CpCACHEflushbtc /* flush one entry of the branch-target cache, va in R0 (cortex) */ #define FLBTSE MTCP CpSC, 0, R0, C(CpCACHE), C(CpCACHEinvi), CpCACHEflushbtse /* arm v7 arch defines these */ #define DSB WORD $0xf57ff04f /* data synch. barrier; last f = SY */ #define DMB WORD $0xf57ff05f /* data mem. barrier; last f = SY */ #define ISB WORD $0xf57ff06f /* instr. sync. barrier; last f = SY */ #define WFI WORD $0xe320f003 /* wait for interrupt */ #define NOOP WORD $0xe320f000 #define CLZ(s, d) WORD $(0xe16f0f10 | (d) << 12 | (s)) /* count leading 0s */ #define SETEND(o) WORD $(0xf1010000 | (o) << 9) /* o==0, little-endian */ #define CPSIE WORD $0xf1080080 /* intr enable: zeroes I bit */ #define CPSID WORD $0xf10c00c0 /* intr disable: sets I,F bits */ #define CPSAE WORD $0xf1080100 /* async abt enable: zeroes A bit */ #define CPSMODE(m) WORD $(0xf1020000 | (m)) /* switch to mode m (PsrM*) */ #define CLREX WORD $0xf57ff01f /* floating point */ #define VMRS(fp, cpu) WORD $(0xeef00a10 | (fp)<<16 | (cpu)<<12) /* FP → arm */ #define VMSR(cpu, fp) WORD $(0xeee00a10 | (fp)<<16 | (cpu)<<12) /* arm → FP */ /* * a popular code sequence used to write a pte for va is: * * MOVW R(n), TTB[LnX(va)] * // clean the cache line * DSB * // invalidate tlb entry for va * FLBTC * DSB * PFF (now ISB) */ #define BARRIERS FLBTC; DSB; ISB /* * invoked with PTE bits in R2, pa in R3, PTE pointed to by R4. * fill PTE pointed to by R4 and increment R4 past it. * increment R3 by a MB. clobbers R1. */ #define FILLPTE() \ ORR R3, R2, R1; /* pte bits in R2, pa in R3 */ \ MOVW R1, (R4); \ ADD $4, R4; /* bump PTE address */ \ ADD $MiB, R3; /* bump pa */ \ /* zero PTE pointed to by R4 and increment R4 past it. assumes R0 is 0. */ #define ZEROPTE() \ MOVW R0, (R4); \ ADD $4, R4; /* bump PTE address */ /* * set kernel SB for zero segment (instead of usual KZERO segment). * NB: the next line puts rubbish in R12: * MOVW $setR12-KZERO(SB), R12 */ #define SETZSB \ MOVW $setR12(SB), R12; /* load kernel's SB */ \ SUB $KZERO, R12; \ ADD $PHYSDRAM, R12 /* * note that 5a's RFE is not the v6/7 arch. instruction (0xf8900a00), * which loads CPSR from the word after the PC at (R13), but rather * the pre-v6 simulation `MOVM.IA.S.W (R13), [R15]' (0xe8fd8000 since * MOVM is LDM in this case), which loads CPSR not from memory but * from SPSR due to `.S'. */ #define RFEV7(r) WORD $(0xf8900a00 | (r) << 16) #define RFEV7W(r) WORD $(0xf8900a00 | (r) << 16 | 0x00200000) /* RFE.W */ #define RFEV7DB(r) WORD $(0xf9100a00 | (r) << 16) /* RFE.DB */ #define RFEV7DBW(r) WORD $(0xf9100a00 | (r) << 16 | 0x00200000) /* RFE.DB.W */ #define CKPSR(psr, tmp, bad) #define CKCPSR(psrtmp, tmp, bad) /* return with cpu id in r and condition codes set from "r == 0" */ #define CPUID(r) \ MFCP CpSC, 0, r, C(CpID), C(CpIDidct), CpIDmpid; \ AND.S $(MAXMACH-1), r /* mask out non-cpu-id bits */