root / hw / eccmemctl.c @ ed23fbd9
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/*
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* QEMU Sparc Sun4m ECC memory controller emulation
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*
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* Copyright (c) 2007 Robert Reif
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*
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* Permission is hereby granted, free of charge, to any person obtaining a copy
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* of this software and associated documentation files (the "Software"), to deal
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* in the Software without restriction, including without limitation the rights
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* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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* copies of the Software, and to permit persons to whom the Software is
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* furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in
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* all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
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* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
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* THE SOFTWARE.
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*/
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#include "hw.h" |
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#include "sun4m.h" |
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#include "sysemu.h" |
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//#define DEBUG_ECC
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#ifdef DEBUG_ECC
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#define DPRINTF(fmt, args...) \
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do { printf("ECC: " fmt , ##args); } while (0) |
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#else
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#define DPRINTF(fmt, args...)
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#endif
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/* There are 3 versions of this chip used in SMP sun4m systems:
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* MCC (version 0, implementation 0) SS-600MP
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* EMC (version 0, implementation 1) SS-10
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* SMC (version 0, implementation 2) SS-10SX and SS-20
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*/
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/* Register indexes */
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#define ECC_MER 0 /* Memory Enable Register */ |
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#define ECC_MDR 1 /* Memory Delay Register */ |
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#define ECC_MFSR 2 /* Memory Fault Status Register */ |
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#define ECC_VCR 3 /* Video Configuration Register */ |
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#define ECC_MFAR0 4 /* Memory Fault Address Register 0 */ |
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#define ECC_MFAR1 5 /* Memory Fault Address Register 1 */ |
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#define ECC_DR 6 /* Diagnostic Register */ |
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#define ECC_ECR0 7 /* Event Count Register 0 */ |
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#define ECC_ECR1 8 /* Event Count Register 1 */ |
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/* ECC fault control register */
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#define ECC_MER_EE 0x00000001 /* Enable ECC checking */ |
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#define ECC_MER_EI 0x00000002 /* Enable Interrupts on |
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correctable errors */
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#define ECC_MER_MRR0 0x00000004 /* SIMM 0 */ |
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#define ECC_MER_MRR1 0x00000008 /* SIMM 1 */ |
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#define ECC_MER_MRR2 0x00000010 /* SIMM 2 */ |
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#define ECC_MER_MRR3 0x00000020 /* SIMM 3 */ |
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#define ECC_MER_MRR4 0x00000040 /* SIMM 4 */ |
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#define ECC_MER_MRR5 0x00000080 /* SIMM 5 */ |
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#define ECC_MER_MRR6 0x00000100 /* SIMM 6 */ |
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#define ECC_MER_MRR7 0x00000200 /* SIMM 7 */ |
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#define ECC_MER_REU 0x00000200 /* Memory Refresh Enable (600MP) */ |
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#define ECC_MER_MRR 0x000003fc /* MRR mask */ |
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#define ECC_MEM_A 0x00000400 /* Memory controller addr map select */ |
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#define ECC_MER_DCI 0x00000800 /* Disables Coherent Invalidate ACK */ |
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#define ECC_MER_VER 0x0f000000 /* Version */ |
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#define ECC_MER_IMPL 0xf0000000 /* Implementation */ |
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/* ECC memory delay register */
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#define ECC_MDR_RRI 0x000003ff /* Refresh Request Interval */ |
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#define ECC_MDR_MI 0x00001c00 /* MIH Delay */ |
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#define ECC_MDR_CI 0x0000e000 /* Coherent Invalidate Delay */ |
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#define ECC_MDR_MDL 0x001f0000 /* MBus Master arbitration delay */ |
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#define ECC_MDR_MDH 0x03e00000 /* MBus Master arbitration delay */ |
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#define ECC_MDR_GAD 0x7c000000 /* Graphics Arbitration Delay */ |
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#define ECC_MDR_RSC 0x80000000 /* Refresh load control */ |
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#define ECC_MDR_MASK 0x7fffffff |
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/* ECC fault status register */
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#define ECC_MFSR_CE 0x00000001 /* Correctable error */ |
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#define ECC_MFSR_BS 0x00000002 /* C2 graphics bad slot access */ |
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#define ECC_MFSR_TO 0x00000004 /* Timeout on write */ |
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#define ECC_MFSR_UE 0x00000008 /* Uncorrectable error */ |
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#define ECC_MFSR_DW 0x000000f0 /* Index of double word in block */ |
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#define ECC_MFSR_SYND 0x0000ff00 /* Syndrome for correctable error */ |
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#define ECC_MFSR_ME 0x00010000 /* Multiple errors */ |
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#define ECC_MFSR_C2ERR 0x00020000 /* C2 graphics error */ |
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/* ECC fault address register 0 */
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#define ECC_MFAR0_PADDR 0x0000000f /* PA[32-35] */ |
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#define ECC_MFAR0_TYPE 0x000000f0 /* Transaction type */ |
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#define ECC_MFAR0_SIZE 0x00000700 /* Transaction size */ |
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#define ECC_MFAR0_CACHE 0x00000800 /* Mapped cacheable */ |
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#define ECC_MFAR0_LOCK 0x00001000 /* Error occurred in atomic cycle */ |
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#define ECC_MFAR0_BMODE 0x00002000 /* Boot mode */ |
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#define ECC_MFAR0_VADDR 0x003fc000 /* VA[12-19] (superset bits) */ |
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#define ECC_MFAR0_S 0x08000000 /* Supervisor mode */ |
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#define ECC_MFARO_MID 0xf0000000 /* Module ID */ |
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/* ECC diagnostic register */
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#define ECC_DR_CBX 0x00000001 |
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#define ECC_DR_CB0 0x00000002 |
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#define ECC_DR_CB1 0x00000004 |
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#define ECC_DR_CB2 0x00000008 |
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#define ECC_DR_CB4 0x00000010 |
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#define ECC_DR_CB8 0x00000020 |
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#define ECC_DR_CB16 0x00000040 |
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#define ECC_DR_CB32 0x00000080 |
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#define ECC_DR_DMODE 0x00000c00 |
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#define ECC_NREGS 9 |
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#define ECC_SIZE (ECC_NREGS * sizeof(uint32_t)) |
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#define ECC_ADDR_MASK 0x1f |
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#define ECC_DIAG_SIZE 4 |
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#define ECC_DIAG_MASK (ECC_DIAG_SIZE - 1) |
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typedef struct ECCState { |
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qemu_irq irq; |
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uint32_t regs[ECC_NREGS]; |
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uint8_t diag[ECC_DIAG_SIZE]; |
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} ECCState; |
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static void ecc_mem_writel(void *opaque, target_phys_addr_t addr, uint32_t val) |
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{ |
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ECCState *s = opaque; |
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switch ((addr & ECC_ADDR_MASK) >> 2) { |
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case ECC_MER:
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s->regs[ECC_MER] = (s->regs[ECC_MER] & (ECC_MER_VER | ECC_MER_IMPL)) | |
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(val & ~(ECC_MER_VER | ECC_MER_IMPL)); |
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DPRINTF("Write memory enable %08x\n", val);
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break;
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case ECC_MDR:
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s->regs[ECC_MDR] = val & ECC_MDR_MASK; |
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DPRINTF("Write memory delay %08x\n", val);
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break;
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case ECC_MFSR:
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s->regs[ECC_MFSR] = val; |
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DPRINTF("Write memory fault status %08x\n", val);
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break;
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case ECC_VCR:
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s->regs[ECC_VCR] = val; |
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DPRINTF("Write slot configuration %08x\n", val);
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break;
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case ECC_DR:
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s->regs[ECC_DR] = val; |
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DPRINTF("Write diagnosiic %08x\n", val);
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break;
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case ECC_ECR0:
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s->regs[ECC_ECR0] = val; |
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DPRINTF("Write event count 1 %08x\n", val);
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break;
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case ECC_ECR1:
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s->regs[ECC_ECR0] = val; |
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DPRINTF("Write event count 2 %08x\n", val);
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break;
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} |
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} |
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static uint32_t ecc_mem_readl(void *opaque, target_phys_addr_t addr) |
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{ |
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ECCState *s = opaque; |
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uint32_t ret = 0;
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switch ((addr & ECC_ADDR_MASK) >> 2) { |
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case ECC_MER:
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ret = s->regs[ECC_MER]; |
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DPRINTF("Read memory enable %08x\n", ret);
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break;
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case ECC_MDR:
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ret = s->regs[ECC_MDR]; |
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DPRINTF("Read memory delay %08x\n", ret);
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break;
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case ECC_MFSR:
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ret = s->regs[ECC_MFSR]; |
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DPRINTF("Read memory fault status %08x\n", ret);
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break;
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case ECC_VCR:
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ret = s->regs[ECC_VCR]; |
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DPRINTF("Read slot configuration %08x\n", ret);
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break;
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case ECC_MFAR0:
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ret = s->regs[ECC_MFAR0]; |
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DPRINTF("Read memory fault address 0 %08x\n", ret);
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break;
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case ECC_MFAR1:
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ret = s->regs[ECC_MFAR1]; |
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DPRINTF("Read memory fault address 1 %08x\n", ret);
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break;
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case ECC_DR:
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ret = s->regs[ECC_DR]; |
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DPRINTF("Read diagnostic %08x\n", ret);
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break;
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case ECC_ECR0:
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ret = s->regs[ECC_ECR0]; |
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DPRINTF("Read event count 1 %08x\n", ret);
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break;
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case ECC_ECR1:
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ret = s->regs[ECC_ECR0]; |
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DPRINTF("Read event count 2 %08x\n", ret);
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break;
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} |
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return ret;
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} |
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static CPUReadMemoryFunc *ecc_mem_read[3] = { |
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NULL,
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NULL,
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ecc_mem_readl, |
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}; |
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static CPUWriteMemoryFunc *ecc_mem_write[3] = { |
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NULL,
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NULL,
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ecc_mem_writel, |
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}; |
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static void ecc_diag_mem_writeb(void *opaque, target_phys_addr_t addr, |
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uint32_t val) |
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{ |
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ECCState *s = opaque; |
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DPRINTF("Write diagnostic[%d] = %02x\n", (int)(addr & ECC_DIAG_MASK), val); |
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s->diag[addr & ECC_DIAG_MASK] = val; |
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} |
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static uint32_t ecc_diag_mem_readb(void *opaque, target_phys_addr_t addr) |
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{ |
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ECCState *s = opaque; |
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uint32_t ret = s->diag[addr & ECC_DIAG_MASK]; |
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DPRINTF("Read diagnostic[%d] = %02x\n", (int)(addr & ECC_DIAG_MASK), ret); |
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return ret;
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} |
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static CPUReadMemoryFunc *ecc_diag_mem_read[3] = { |
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ecc_diag_mem_readb, |
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NULL,
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NULL,
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}; |
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static CPUWriteMemoryFunc *ecc_diag_mem_write[3] = { |
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ecc_diag_mem_writeb, |
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NULL,
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NULL,
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}; |
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static int ecc_load(QEMUFile *f, void *opaque, int version_id) |
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{ |
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ECCState *s = opaque; |
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int i;
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if (version_id != 2) |
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return -EINVAL;
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for (i = 0; i < ECC_NREGS; i++) |
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qemu_get_be32s(f, &s->regs[i]); |
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for (i = 0; i < ECC_DIAG_SIZE; i++) |
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qemu_get_8s(f, &s->diag[i]); |
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return 0; |
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} |
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static void ecc_save(QEMUFile *f, void *opaque) |
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{ |
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ECCState *s = opaque; |
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int i;
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for (i = 0; i < ECC_NREGS; i++) |
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qemu_put_be32s(f, &s->regs[i]); |
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for (i = 0; i < ECC_DIAG_SIZE; i++) |
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qemu_put_8s(f, &s->diag[i]); |
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} |
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static void ecc_reset(void *opaque) |
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{ |
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ECCState *s = opaque; |
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s->regs[ECC_MER] &= (ECC_MER_VER | ECC_MER_IMPL); |
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s->regs[ECC_MER] |= ECC_MER_MRR; |
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s->regs[ECC_MDR] = 0x20;
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s->regs[ECC_MFSR] = 0;
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s->regs[ECC_VCR] = 0;
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s->regs[ECC_MFAR0] = 0x07c00000;
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s->regs[ECC_MFAR1] = 0;
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s->regs[ECC_DR] = 0;
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s->regs[ECC_ECR0] = 0;
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s->regs[ECC_ECR1] = 0;
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} |
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void * ecc_init(target_phys_addr_t base, qemu_irq irq, uint32_t version)
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{ |
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int ecc_io_memory;
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ECCState *s; |
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s = qemu_mallocz(sizeof(ECCState));
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if (!s)
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return NULL; |
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s->regs[0] = version;
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s->irq = irq; |
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ecc_io_memory = cpu_register_io_memory(0, ecc_mem_read, ecc_mem_write, s);
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cpu_register_physical_memory(base, ECC_SIZE, ecc_io_memory); |
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if (version == 0) { // SS-600MP only |
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ecc_io_memory = cpu_register_io_memory(0, ecc_diag_mem_read,
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ecc_diag_mem_write, s); |
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cpu_register_physical_memory(base + 0x1000, ECC_DIAG_SIZE,
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ecc_io_memory); |
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} |
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register_savevm("ECC", base, 2, ecc_save, ecc_load, s); |
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qemu_register_reset(ecc_reset, s); |
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ecc_reset(s); |
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return s;
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} |