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       /*
        * Intel XScale PXA255/270 processor support.
+       *
        * Copyright (c) 2006 Openedhand Ltd.
        * Written by Andrzej Zaborowski <balrog@zabor.org>
+       *
        * This code is licenced under the GPL.
        */
       #include "hw.h"
       #include "pxa.h"
       #include "sysemu.h"
       #include "pc.h"
       #include "i2c.h"
       #include "qemu-timer.h"
       #include "qemu-char.h"
       static struct {
           target_phys_addr_t io_base;
           int irqn;
       } pxa255_serial[] = {
           { 0x40100000, PXA2XX_PIC_FFUART },
           { 0x40200000, PXA2XX_PIC_BTUART },
           { 0x40700000, PXA2XX_PIC_STUART },
           { 0x41600000, PXA25X_PIC_HWUART },
           { 0, 0 }
       }, pxa270_serial[] = {
           { 0x40100000, PXA2XX_PIC_FFUART },
           { 0x40200000, PXA2XX_PIC_BTUART },
           { 0x40700000, PXA2XX_PIC_STUART },
           { 0, 0 }
       };
       typedef struct PXASSPDef {
           target_phys_addr_t io_base;
           int irqn;
       } PXASSPDef;
       #if 0
       static PXASSPDef pxa250_ssp[] = {
           { 0x41000000, PXA2XX_PIC_SSP },
           { 0, 0 }
       };
       #endif
       static PXASSPDef pxa255_ssp[] = {
           { 0x41000000, PXA2XX_PIC_SSP },
           { 0x41400000, PXA25X_PIC_NSSP },
           { 0, 0 }
       };
       #if 0
       static PXASSPDef pxa26x_ssp[] = {
           { 0x41000000, PXA2XX_PIC_SSP },
           { 0x41400000, PXA25X_PIC_NSSP },
           { 0x41500000, PXA26X_PIC_ASSP },
           { 0, 0 }
       };
       #endif
       static PXASSPDef pxa27x_ssp[] = {
           { 0x41000000, PXA2XX_PIC_SSP },
           { 0x41700000, PXA27X_PIC_SSP2 },
           { 0x41900000, PXA2XX_PIC_SSP3 },
           { 0, 0 }
       };
       #define PMCR        0x00        /* Power Manager Control register */
       #define PSSR        0x04        /* Power Manager Sleep Status register */
       #define PSPR        0x08        /* Power Manager Scratch-Pad register */
       #define PWER        0x0c        /* Power Manager Wake-Up Enable register */
       #define PRER        0x10        /* Power Manager Rising-Edge Detect Enable register */
       #define PFER        0x14        /* Power Manager Falling-Edge Detect Enable register */
       #define PEDR        0x18        /* Power Manager Edge-Detect Status register */
       #define PCFR        0x1c        /* Power Manager General Configuration register */
       #define PGSR0        0x20        /* Power Manager GPIO Sleep-State register 0 */
       #define PGSR1        0x24        /* Power Manager GPIO Sleep-State register 1 */
       #define PGSR2        0x28        /* Power Manager GPIO Sleep-State register 2 */
       #define PGSR3        0x2c        /* Power Manager GPIO Sleep-State register 3 */
       #define RCSR        0x30        /* Reset Controller Status register */
       #define PSLR        0x34        /* Power Manager Sleep Configuration register */
       #define PTSR        0x38        /* Power Manager Standby Configuration register */
       #define PVCR        0x40        /* Power Manager Voltage Change Control register */
       #define PUCR        0x4c        /* Power Manager USIM Card Control/Status register */
       #define PKWR        0x50        /* Power Manager Keyboard Wake-Up Enable register */
       #define PKSR        0x54        /* Power Manager Keyboard Level-Detect Status */
       #define PCMD0        0x80        /* Power Manager I2C Command register File 0 */
       #define PCMD31        0xfc        /* Power Manager I2C Command register File 31 */
       static uint32_t pxa2xx_pm_read(void *opaque, target_phys_addr_t addr)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           addr -= s->pm_base;
           switch (addr) {
           case PMCR ... PCMD31:
               if (addr & 3)
                   goto fail;
               return s->pm_regs[addr >> 2];
           default:
           fail:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_pm_write(void *opaque, target_phys_addr_t addr,
                       uint32_t value)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           addr -= s->pm_base;
           switch (addr) {
           case PMCR:
               s->pm_regs[addr >> 2] &= 0x15 & ~(value & 0x2a);
               s->pm_regs[addr >> 2] |= value & 0x15;
               break;
           case PSSR:        /* Read-clean registers */
           case RCSR:
           case PKSR:
               s->pm_regs[addr >> 2] &= ~value;
               break;
           default:        /* Read-write registers */
               if (addr >= PMCR && addr <= PCMD31 && !(addr & 3)) {
                   s->pm_regs[addr >> 2] = value;
                   break;
+              }
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
+      }
       static CPUReadMemoryFunc *pxa2xx_pm_readfn[] = {
           pxa2xx_pm_read,
           pxa2xx_pm_read,
           pxa2xx_pm_read,
       };
       static CPUWriteMemoryFunc *pxa2xx_pm_writefn[] = {
           pxa2xx_pm_write,
           pxa2xx_pm_write,
           pxa2xx_pm_write,
       };
       static void pxa2xx_pm_save(QEMUFile *f, void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           int i;
           for (i = 0; i < 0x40; i ++)
               qemu_put_be32s(f, &s->pm_regs[i]);
+      }
       static int pxa2xx_pm_load(QEMUFile *f, void *opaque, int version_id)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           int i;
           for (i = 0; i < 0x40; i ++)
               qemu_get_be32s(f, &s->pm_regs[i]);
           return 0;
+      }
       #define CCCR        0x00        /* Core Clock Configuration register */
       #define CKEN        0x04        /* Clock Enable register */
       #define OSCC        0x08        /* Oscillator Configuration register */
       #define CCSR        0x0c        /* Core Clock Status register */
       static uint32_t pxa2xx_cm_read(void *opaque, target_phys_addr_t addr)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           addr -= s->cm_base;
           switch (addr) {
           case CCCR:
           case CKEN:
           case OSCC:
               return s->cm_regs[addr >> 2];
           case CCSR:
               return s->cm_regs[CCCR >> 2] | (3 << 28);
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_cm_write(void *opaque, target_phys_addr_t addr,
                       uint32_t value)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           addr -= s->cm_base;
           switch (addr) {
           case CCCR:
           case CKEN:
               s->cm_regs[addr >> 2] = value;
               break;
           case OSCC:
               s->cm_regs[addr >> 2] &= ~0x6c;
               s->cm_regs[addr >> 2] |= value & 0x6e;
               if ((value >> 1) & 1)                        /* OON */
                   s->cm_regs[addr >> 2] |= 1 << 0;        /* Oscillator is now stable */
               break;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
+      }
       static CPUReadMemoryFunc *pxa2xx_cm_readfn[] = {
           pxa2xx_cm_read,
           pxa2xx_cm_read,
           pxa2xx_cm_read,
       };
       static CPUWriteMemoryFunc *pxa2xx_cm_writefn[] = {
           pxa2xx_cm_write,
           pxa2xx_cm_write,
           pxa2xx_cm_write,
       };
       static void pxa2xx_cm_save(QEMUFile *f, void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           int i;
           for (i = 0; i < 4; i ++)
               qemu_put_be32s(f, &s->cm_regs[i]);
           qemu_put_be32s(f, &s->clkcfg);
           qemu_put_be32s(f, &s->pmnc);
+      }
       static int pxa2xx_cm_load(QEMUFile *f, void *opaque, int version_id)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           int i;
           for (i = 0; i < 4; i ++)
               qemu_get_be32s(f, &s->cm_regs[i]);
           qemu_get_be32s(f, &s->clkcfg);
           qemu_get_be32s(f, &s->pmnc);
           return 0;
+      }
       static uint32_t pxa2xx_clkpwr_read(void *opaque, int op2, int reg, int crm)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           switch (reg) {
           case 6:        /* Clock Configuration register */
               return s->clkcfg;
           case 7:        /* Power Mode register */
               return 0;
           default:
               printf("%s: Bad register 0x%x\n", __FUNCTION__, reg);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_clkpwr_write(void *opaque, int op2, int reg, int crm,
                       uint32_t value)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           static const char *pwrmode[8] = {
               "Normal", "Idle", "Deep-idle", "Standby",
               "Sleep", "reserved (!)", "reserved (!)", "Deep-sleep",
           };
           switch (reg) {
           case 6:        /* Clock Configuration register */
               s->clkcfg = value & 0xf;
               if (value & 2)
                   printf("%s: CPU frequency change attempt\n", __FUNCTION__);
               break;
           case 7:        /* Power Mode register */
               if (value & 8)
                   printf("%s: CPU voltage change attempt\n", __FUNCTION__);
               switch (value & 7) {
               case 0:
                   /* Do nothing */
                   break;
               case 1:
                   /* Idle */
                   if (!(s->cm_regs[CCCR >> 2] & (1 << 31))) {        /* CPDIS */
                       cpu_interrupt(s->env, CPU_INTERRUPT_HALT);
                       break;
+                  }
                   /* Fall through.  */
               case 2:
                   /* Deep-Idle */
                   cpu_interrupt(s->env, CPU_INTERRUPT_HALT);
                   s->pm_regs[RCSR >> 2] |= 0x8;        /* Set GPR */
                   goto message;
               case 3:
                   s->env->uncached_cpsr =
                           ARM_CPU_MODE_SVC | CPSR_A | CPSR_F | CPSR_I;
                   s->env->cp15.c1_sys = 0;
                   s->env->cp15.c1_coproc = 0;
                   s->env->cp15.c2_base0 = 0;
                   s->env->cp15.c3 = 0;
                   s->pm_regs[PSSR >> 2] |= 0x8;        /* Set STS */
                   s->pm_regs[RCSR >> 2] |= 0x8;        /* Set GPR */
                   /*
                    * The scratch-pad register is almost universally used
                    * for storing the return address on suspend.  For the
                    * lack of a resuming bootloader, perform a jump
                    * directly to that address.
                    */
                   memset(s->env->regs, 0, 4 * 15);
                   s->env->regs[15] = s->pm_regs[PSPR >> 2];
       #if 0
                   buffer = 0xe59ff000;        /* ldr     pc, [pc, #0] */
                   cpu_physical_memory_write(0, &buffer, 4);
                   buffer = s->pm_regs[PSPR >> 2];
                   cpu_physical_memory_write(8, &buffer, 4);
       #endif
                   /* Suspend */
                   cpu_interrupt(cpu_single_env, CPU_INTERRUPT_HALT);
                   goto message;
               default:
               message:
                   printf("%s: machine entered %s mode\n", __FUNCTION__,
                                   pwrmode[value & 7]);
+              }
               break;
           default:
               printf("%s: Bad register 0x%x\n", __FUNCTION__, reg);
               break;
+          }
+      }
       /* Performace Monitoring Registers */
       #define CPPMNC                0        /* Performance Monitor Control register */
       #define CPCCNT                1        /* Clock Counter register */
       #define CPINTEN                4        /* Interrupt Enable register */
       #define CPFLAG                5        /* Overflow Flag register */
       #define CPEVTSEL        8        /* Event Selection register */
       #define CPPMN0                0        /* Performance Count register 0 */
       #define CPPMN1                1        /* Performance Count register 1 */
       #define CPPMN2                2        /* Performance Count register 2 */
       #define CPPMN3                3        /* Performance Count register 3 */
       static uint32_t pxa2xx_perf_read(void *opaque, int op2, int reg, int crm)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           switch (reg) {
           case CPPMNC:
               return s->pmnc;
           case CPCCNT:
               if (s->pmnc & 1)
                   return qemu_get_clock(vm_clock);
               else
                   return 0;
           case CPINTEN:
           case CPFLAG:
           case CPEVTSEL:
               return 0;
           default:
               printf("%s: Bad register 0x%x\n", __FUNCTION__, reg);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_perf_write(void *opaque, int op2, int reg, int crm,
                       uint32_t value)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           switch (reg) {
           case CPPMNC:
               s->pmnc = value;
               break;
           case CPCCNT:
           case CPINTEN:
           case CPFLAG:
           case CPEVTSEL:
               break;
           default:
               printf("%s: Bad register 0x%x\n", __FUNCTION__, reg);
               break;
+          }
+      }
       static uint32_t pxa2xx_cp14_read(void *opaque, int op2, int reg, int crm)
+      {
           switch (crm) {
           case 0:
               return pxa2xx_clkpwr_read(opaque, op2, reg, crm);
           case 1:
               return pxa2xx_perf_read(opaque, op2, reg, crm);
           case 2:
               switch (reg) {
               case CPPMN0:
               case CPPMN1:
               case CPPMN2:
               case CPPMN3:
                   return 0;
+              }
               /* Fall through */
           default:
               printf("%s: Bad register 0x%x\n", __FUNCTION__, reg);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_cp14_write(void *opaque, int op2, int reg, int crm,
                       uint32_t value)
+      {
           switch (crm) {
           case 0:
               pxa2xx_clkpwr_write(opaque, op2, reg, crm, value);
               break;
           case 1:
               pxa2xx_perf_write(opaque, op2, reg, crm, value);
               break;
           case 2:
               switch (reg) {
               case CPPMN0:
               case CPPMN1:
               case CPPMN2:
               case CPPMN3:
                   return;
+              }
               /* Fall through */
           default:
               printf("%s: Bad register 0x%x\n", __FUNCTION__, reg);
               break;
+          }
+      }
       #define MDCNFG                0x00        /* SDRAM Configuration register */
       #define MDREFR                0x04        /* SDRAM Refresh Control register */
       #define MSC0                0x08        /* Static Memory Control register 0 */
       #define MSC1                0x0c        /* Static Memory Control register 1 */
       #define MSC2                0x10        /* Static Memory Control register 2 */
       #define MECR                0x14        /* Expansion Memory Bus Config register */
       #define SXCNFG                0x1c        /* Synchronous Static Memory Config register */
       #define MCMEM0                0x28        /* PC Card Memory Socket 0 Timing register */
       #define MCMEM1                0x2c        /* PC Card Memory Socket 1 Timing register */
       #define MCATT0                0x30        /* PC Card Attribute Socket 0 register */
       #define MCATT1                0x34        /* PC Card Attribute Socket 1 register */
       #define MCIO0                0x38        /* PC Card I/O Socket 0 Timing register */
       #define MCIO1                0x3c        /* PC Card I/O Socket 1 Timing register */
       #define MDMRS                0x40        /* SDRAM Mode Register Set Config register */
       #define BOOT_DEF        0x44        /* Boot-time Default Configuration register */
       #define ARB_CNTL        0x48        /* Arbiter Control register */
       #define BSCNTR0                0x4c        /* Memory Buffer Strength Control register 0 */
       #define BSCNTR1                0x50        /* Memory Buffer Strength Control register 1 */
       #define LCDBSCNTR        0x54        /* LCD Buffer Strength Control register */
       #define MDMRSLP                0x58        /* Low Power SDRAM Mode Set Config register */
       #define BSCNTR2                0x5c        /* Memory Buffer Strength Control register 2 */
       #define BSCNTR3                0x60        /* Memory Buffer Strength Control register 3 */
       #define SA1110                0x64        /* SA-1110 Memory Compatibility register */
       static uint32_t pxa2xx_mm_read(void *opaque, target_phys_addr_t addr)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           addr -= s->mm_base;
           switch (addr) {
           case MDCNFG ... SA1110:
               if ((addr & 3) == 0)
                   return s->mm_regs[addr >> 2];
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_mm_write(void *opaque, target_phys_addr_t addr,
                       uint32_t value)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           addr -= s->mm_base;
           switch (addr) {
           case MDCNFG ... SA1110:
               if ((addr & 3) == 0) {
                   s->mm_regs[addr >> 2] = value;
                   break;
+              }
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
+      }
       static CPUReadMemoryFunc *pxa2xx_mm_readfn[] = {
           pxa2xx_mm_read,
           pxa2xx_mm_read,
           pxa2xx_mm_read,
       };
       static CPUWriteMemoryFunc *pxa2xx_mm_writefn[] = {
           pxa2xx_mm_write,
           pxa2xx_mm_write,
           pxa2xx_mm_write,
       };
       static void pxa2xx_mm_save(QEMUFile *f, void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           int i;
           for (i = 0; i < 0x1a; i ++)
               qemu_put_be32s(f, &s->mm_regs[i]);
+      }
       static int pxa2xx_mm_load(QEMUFile *f, void *opaque, int version_id)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           int i;
           for (i = 0; i < 0x1a; i ++)
               qemu_get_be32s(f, &s->mm_regs[i]);
           return 0;
+      }
       /* Synchronous Serial Ports */
       struct pxa2xx_ssp_s {
           target_phys_addr_t base;
           qemu_irq irq;
           int enable;
           uint32_t sscr[2];
           uint32_t sspsp;
           uint32_t ssto;
           uint32_t ssitr;
           uint32_t sssr;
           uint8_t sstsa;
           uint8_t ssrsa;
           uint8_t ssacd;
           uint32_t rx_fifo[16];
           int rx_level;
           int rx_start;
           uint32_t (*readfn)(void *opaque);
           void (*writefn)(void *opaque, uint32_t value);
           void *opaque;
       };
       #define SSCR0        0x00        /* SSP Control register 0 */
       #define SSCR1        0x04        /* SSP Control register 1 */
       #define SSSR        0x08        /* SSP Status register */
       #define SSITR        0x0c        /* SSP Interrupt Test register */
       #define SSDR        0x10        /* SSP Data register */
       #define SSTO        0x28        /* SSP Time-Out register */
       #define SSPSP        0x2c        /* SSP Programmable Serial Protocol register */
       #define SSTSA        0x30        /* SSP TX Time Slot Active register */
       #define SSRSA        0x34        /* SSP RX Time Slot Active register */
       #define SSTSS        0x38        /* SSP Time Slot Status register */
       #define SSACD        0x3c        /* SSP Audio Clock Divider register */
       /* Bitfields for above registers */
       #define SSCR0_SPI(x)        (((x) & 0x30) == 0x00)
       #define SSCR0_SSP(x)        (((x) & 0x30) == 0x10)
       #define SSCR0_UWIRE(x)        (((x) & 0x30) == 0x20)
       #define SSCR0_PSP(x)        (((x) & 0x30) == 0x30)
       #define SSCR0_SSE        (1 << 7)
       #define SSCR0_RIM        (1 << 22)
       #define SSCR0_TIM        (1 << 23)
       #define SSCR0_MOD        (1 << 31)
       #define SSCR0_DSS(x)        (((((x) >> 16) & 0x10) | ((x) & 0xf)) + 1)
       #define SSCR1_RIE        (1 << 0)
       #define SSCR1_TIE        (1 << 1)
       #define SSCR1_LBM        (1 << 2)
       #define SSCR1_MWDS        (1 << 5)
       #define SSCR1_TFT(x)        ((((x) >> 6) & 0xf) + 1)
       #define SSCR1_RFT(x)        ((((x) >> 10) & 0xf) + 1)
       #define SSCR1_EFWR        (1 << 14)
       #define SSCR1_PINTE        (1 << 18)
       #define SSCR1_TINTE        (1 << 19)
       #define SSCR1_RSRE        (1 << 20)
       #define SSCR1_TSRE        (1 << 21)
       #define SSCR1_EBCEI        (1 << 29)
       #define SSITR_INT        (7 << 5)
       #define SSSR_TNF        (1 << 2)
       #define SSSR_RNE        (1 << 3)
       #define SSSR_TFS        (1 << 5)
       #define SSSR_RFS        (1 << 6)
       #define SSSR_ROR        (1 << 7)
       #define SSSR_PINT        (1 << 18)
       #define SSSR_TINT        (1 << 19)
       #define SSSR_EOC        (1 << 20)
       #define SSSR_TUR        (1 << 21)
       #define SSSR_BCE        (1 << 23)
       #define SSSR_RW                0x00bc0080
       static void pxa2xx_ssp_int_update(struct pxa2xx_ssp_s *s)
+      {
           int level = 0;
           level |= s->ssitr & SSITR_INT;
           level |= (s->sssr & SSSR_BCE)  &&  (s->sscr[1] & SSCR1_EBCEI);
           level |= (s->sssr & SSSR_TUR)  && !(s->sscr[0] & SSCR0_TIM);
           level |= (s->sssr & SSSR_EOC)  &&  (s->sssr & (SSSR_TINT | SSSR_PINT));
           level |= (s->sssr & SSSR_TINT) &&  (s->sscr[1] & SSCR1_TINTE);
           level |= (s->sssr & SSSR_PINT) &&  (s->sscr[1] & SSCR1_PINTE);
           level |= (s->sssr & SSSR_ROR)  && !(s->sscr[0] & SSCR0_RIM);
           level |= (s->sssr & SSSR_RFS)  &&  (s->sscr[1] & SSCR1_RIE);
           level |= (s->sssr & SSSR_TFS)  &&  (s->sscr[1] & SSCR1_TIE);
           qemu_set_irq(s->irq, !!level);
+      }
       static void pxa2xx_ssp_fifo_update(struct pxa2xx_ssp_s *s)
+      {
           s->sssr &= ~(0xf << 12);        /* Clear RFL */
           s->sssr &= ~(0xf << 8);        /* Clear TFL */
           s->sssr &= ~SSSR_TNF;
           if (s->enable) {
               s->sssr |= ((s->rx_level - 1) & 0xf) << 12;
               if (s->rx_level >= SSCR1_RFT(s->sscr[1]))
                   s->sssr |= SSSR_RFS;
               else
                   s->sssr &= ~SSSR_RFS;
               if (0 <= SSCR1_TFT(s->sscr[1]))
                   s->sssr |= SSSR_TFS;
               else
                   s->sssr &= ~SSSR_TFS;
               if (s->rx_level)
                   s->sssr |= SSSR_RNE;
               else
                   s->sssr &= ~SSSR_RNE;
               s->sssr |= SSSR_TNF;
+          }
           pxa2xx_ssp_int_update(s);
+      }
       static uint32_t pxa2xx_ssp_read(void *opaque, target_phys_addr_t addr)
+      {
           struct pxa2xx_ssp_s *s = (struct pxa2xx_ssp_s *) opaque;
           uint32_t retval;
           addr -= s->base;
           switch (addr) {
           case SSCR0:
               return s->sscr[0];
           case SSCR1:
               return s->sscr[1];
           case SSPSP:
               return s->sspsp;
           case SSTO:
               return s->ssto;
           case SSITR:
               return s->ssitr;
           case SSSR:
               return s->sssr | s->ssitr;
           case SSDR:
               if (!s->enable)
                   return 0xffffffff;
               if (s->rx_level < 1) {
                   printf("%s: SSP Rx Underrun\n", __FUNCTION__);
                   return 0xffffffff;
+              }
               s->rx_level --;
               retval = s->rx_fifo[s->rx_start ++];
               s->rx_start &= 0xf;
               pxa2xx_ssp_fifo_update(s);
               return retval;
           case SSTSA:
               return s->sstsa;
           case SSRSA:
               return s->ssrsa;
           case SSTSS:
               return 0;
           case SSACD:
               return s->ssacd;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_ssp_write(void *opaque, target_phys_addr_t addr,
                       uint32_t value)
+      {
           struct pxa2xx_ssp_s *s = (struct pxa2xx_ssp_s *) opaque;
           addr -= s->base;
           switch (addr) {
           case SSCR0:
               s->sscr[0] = value & 0xc7ffffff;
               s->enable = value & SSCR0_SSE;
               if (value & SSCR0_MOD)
                   printf("%s: Attempt to use network mode\n", __FUNCTION__);
               if (s->enable && SSCR0_DSS(value) < 4)
                   printf("%s: Wrong data size: %i bits\n", __FUNCTION__,
                                   SSCR0_DSS(value));
               if (!(value & SSCR0_SSE)) {
                   s->sssr = 0;
                   s->ssitr = 0;
                   s->rx_level = 0;
+              }
               pxa2xx_ssp_fifo_update(s);
               break;
           case SSCR1:
               s->sscr[1] = value;
               if (value & (SSCR1_LBM | SSCR1_EFWR))
                   printf("%s: Attempt to use SSP test mode\n", __FUNCTION__);
               pxa2xx_ssp_fifo_update(s);
               break;
           case SSPSP:
               s->sspsp = value;
               break;
           case SSTO:
               s->ssto = value;
               break;
           case SSITR:
               s->ssitr = value & SSITR_INT;
               pxa2xx_ssp_int_update(s);
               break;
           case SSSR:
               s->sssr &= ~(value & SSSR_RW);
               pxa2xx_ssp_int_update(s);
               break;
           case SSDR:
               if (SSCR0_UWIRE(s->sscr[0])) {
                   if (s->sscr[1] & SSCR1_MWDS)
                       value &= 0xffff;
                   else
                       value &= 0xff;
               } else
                   /* Note how 32bits overflow does no harm here */
                   value &= (1 << SSCR0_DSS(s->sscr[0])) - 1;
               /* Data goes from here to the Tx FIFO and is shifted out from
                * there directly to the slave, no need to buffer it.
                */
               if (s->enable) {
                   if (s->writefn)
                       s->writefn(s->opaque, value);
                   if (s->rx_level < 0x10) {
                       if (s->readfn)
                           s->rx_fifo[(s->rx_start + s->rx_level ++) & 0xf] =
                                   s->readfn(s->opaque);
                       else
                           s->rx_fifo[(s->rx_start + s->rx_level ++) & 0xf] = 0x0;
                   } else
                       s->sssr |= SSSR_ROR;
+              }
               pxa2xx_ssp_fifo_update(s);
               break;
           case SSTSA:
               s->sstsa = value;
               break;
           case SSRSA:
               s->ssrsa = value;
               break;
           case SSACD:
               s->ssacd = value;
               break;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
+      }
       void pxa2xx_ssp_attach(struct pxa2xx_ssp_s *port,
                       uint32_t (*readfn)(void *opaque),
                       void (*writefn)(void *opaque, uint32_t value), void *opaque)
+      {
           if (!port) {
               printf("%s: no such SSP\n", __FUNCTION__);
               exit(-1);
+          }
           port->opaque = opaque;
           port->readfn = readfn;
           port->writefn = writefn;
+      }
       static CPUReadMemoryFunc *pxa2xx_ssp_readfn[] = {
           pxa2xx_ssp_read,
           pxa2xx_ssp_read,
           pxa2xx_ssp_read,
       };
       static CPUWriteMemoryFunc *pxa2xx_ssp_writefn[] = {
           pxa2xx_ssp_write,
           pxa2xx_ssp_write,
           pxa2xx_ssp_write,
       };
       static void pxa2xx_ssp_save(QEMUFile *f, void *opaque)
+      {
           struct pxa2xx_ssp_s *s = (struct pxa2xx_ssp_s *) opaque;
           int i;
           qemu_put_be32(f, s->enable);
           qemu_put_be32s(f, &s->sscr[0]);
           qemu_put_be32s(f, &s->sscr[1]);
           qemu_put_be32s(f, &s->sspsp);
           qemu_put_be32s(f, &s->ssto);
           qemu_put_be32s(f, &s->ssitr);
           qemu_put_be32s(f, &s->sssr);
           qemu_put_8s(f, &s->sstsa);
           qemu_put_8s(f, &s->ssrsa);
           qemu_put_8s(f, &s->ssacd);
           qemu_put_byte(f, s->rx_level);
           for (i = 0; i < s->rx_level; i ++)
               qemu_put_byte(f, s->rx_fifo[(s->rx_start + i) & 0xf]);
+      }
       static int pxa2xx_ssp_load(QEMUFile *f, void *opaque, int version_id)
+      {
           struct pxa2xx_ssp_s *s = (struct pxa2xx_ssp_s *) opaque;
           int i;
           s->enable = qemu_get_be32(f);
           qemu_get_be32s(f, &s->sscr[0]);
           qemu_get_be32s(f, &s->sscr[1]);
           qemu_get_be32s(f, &s->sspsp);
           qemu_get_be32s(f, &s->ssto);
           qemu_get_be32s(f, &s->ssitr);
           qemu_get_be32s(f, &s->sssr);
           qemu_get_8s(f, &s->sstsa);
           qemu_get_8s(f, &s->ssrsa);
           qemu_get_8s(f, &s->ssacd);
           s->rx_level = qemu_get_byte(f);
           s->rx_start = 0;
           for (i = 0; i < s->rx_level; i ++)
               s->rx_fifo[i] = qemu_get_byte(f);
           return 0;
+      }
       /* Real-Time Clock */
       #define RCNR                0x00        /* RTC Counter register */
       #define RTAR                0x04        /* RTC Alarm register */
       #define RTSR                0x08        /* RTC Status register */
       #define RTTR                0x0c        /* RTC Timer Trim register */
       #define RDCR                0x10        /* RTC Day Counter register */
       #define RYCR                0x14        /* RTC Year Counter register */
       #define RDAR1                0x18        /* RTC Wristwatch Day Alarm register 1 */
       #define RYAR1                0x1c        /* RTC Wristwatch Year Alarm register 1 */
       #define RDAR2                0x20        /* RTC Wristwatch Day Alarm register 2 */
       #define RYAR2                0x24        /* RTC Wristwatch Year Alarm register 2 */
       #define SWCR                0x28        /* RTC Stopwatch Counter register */
       #define SWAR1                0x2c        /* RTC Stopwatch Alarm register 1 */
       #define SWAR2                0x30        /* RTC Stopwatch Alarm register 2 */
       #define RTCPICR                0x34        /* RTC Periodic Interrupt Counter register */
       #define PIAR                0x38        /* RTC Periodic Interrupt Alarm register */
       static inline void pxa2xx_rtc_int_update(struct pxa2xx_state_s *s)
+      {
           qemu_set_irq(s->pic[PXA2XX_PIC_RTCALARM], !!(s->rtsr & 0x2553));
+      }
       static void pxa2xx_rtc_hzupdate(struct pxa2xx_state_s *s)
+      {
           int64_t rt = qemu_get_clock(rt_clock);
           s->last_rcnr += ((rt - s->last_hz) << 15) /
                   (1000 * ((s->rttr & 0xffff) + 1));
           s->last_rdcr += ((rt - s->last_hz) << 15) /
                   (1000 * ((s->rttr & 0xffff) + 1));
           s->last_hz = rt;
+      }
       static void pxa2xx_rtc_swupdate(struct pxa2xx_state_s *s)
+      {
           int64_t rt = qemu_get_clock(rt_clock);
           if (s->rtsr & (1 << 12))
               s->last_swcr += (rt - s->last_sw) / 10;
           s->last_sw = rt;
+      }
       static void pxa2xx_rtc_piupdate(struct pxa2xx_state_s *s)
+      {
           int64_t rt = qemu_get_clock(rt_clock);
           if (s->rtsr & (1 << 15))
               s->last_swcr += rt - s->last_pi;
           s->last_pi = rt;
+      }
       static inline void pxa2xx_rtc_alarm_update(struct pxa2xx_state_s *s,
                       uint32_t rtsr)
+      {
           if ((rtsr & (1 << 2)) && !(rtsr & (1 << 0)))
               qemu_mod_timer(s->rtc_hz, s->last_hz +
                       (((s->rtar - s->last_rcnr) * 1000 *
                         ((s->rttr & 0xffff) + 1)) >> 15));
           else
               qemu_del_timer(s->rtc_hz);
           if ((rtsr & (1 << 5)) && !(rtsr & (1 << 4)))
               qemu_mod_timer(s->rtc_rdal1, s->last_hz +
                       (((s->rdar1 - s->last_rdcr) * 1000 *
                         ((s->rttr & 0xffff) + 1)) >> 15)); /* TODO: fixup */
           else
               qemu_del_timer(s->rtc_rdal1);
           if ((rtsr & (1 << 7)) && !(rtsr & (1 << 6)))
               qemu_mod_timer(s->rtc_rdal2, s->last_hz +
                       (((s->rdar2 - s->last_rdcr) * 1000 *
                         ((s->rttr & 0xffff) + 1)) >> 15)); /* TODO: fixup */
           else
               qemu_del_timer(s->rtc_rdal2);
           if ((rtsr & 0x1200) == 0x1200 && !(rtsr & (1 << 8)))
               qemu_mod_timer(s->rtc_swal1, s->last_sw +
                               (s->swar1 - s->last_swcr) * 10); /* TODO: fixup */
           else
               qemu_del_timer(s->rtc_swal1);
           if ((rtsr & 0x1800) == 0x1800 && !(rtsr & (1 << 10)))
               qemu_mod_timer(s->rtc_swal2, s->last_sw +
                               (s->swar2 - s->last_swcr) * 10); /* TODO: fixup */
           else
               qemu_del_timer(s->rtc_swal2);
           if ((rtsr & 0xc000) == 0xc000 && !(rtsr & (1 << 13)))
               qemu_mod_timer(s->rtc_pi, s->last_pi +
                               (s->piar & 0xffff) - s->last_rtcpicr);
           else
               qemu_del_timer(s->rtc_pi);
+      }
       static inline void pxa2xx_rtc_hz_tick(void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           s->rtsr |= (1 << 0);
           pxa2xx_rtc_alarm_update(s, s->rtsr);
           pxa2xx_rtc_int_update(s);
+      }
       static inline void pxa2xx_rtc_rdal1_tick(void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           s->rtsr |= (1 << 4);
           pxa2xx_rtc_alarm_update(s, s->rtsr);
           pxa2xx_rtc_int_update(s);
+      }
       static inline void pxa2xx_rtc_rdal2_tick(void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           s->rtsr |= (1 << 6);
           pxa2xx_rtc_alarm_update(s, s->rtsr);
           pxa2xx_rtc_int_update(s);
+      }
       static inline void pxa2xx_rtc_swal1_tick(void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           s->rtsr |= (1 << 8);
           pxa2xx_rtc_alarm_update(s, s->rtsr);
           pxa2xx_rtc_int_update(s);
+      }
       static inline void pxa2xx_rtc_swal2_tick(void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           s->rtsr |= (1 << 10);
           pxa2xx_rtc_alarm_update(s, s->rtsr);
           pxa2xx_rtc_int_update(s);
+      }
       static inline void pxa2xx_rtc_pi_tick(void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           s->rtsr |= (1 << 13);
           pxa2xx_rtc_piupdate(s);
           s->last_rtcpicr = 0;
           pxa2xx_rtc_alarm_update(s, s->rtsr);
           pxa2xx_rtc_int_update(s);
+      }
       static uint32_t pxa2xx_rtc_read(void *opaque, target_phys_addr_t addr)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           addr -= s->rtc_base;
           switch (addr) {
           case RTTR:
               return s->rttr;
           case RTSR:
               return s->rtsr;
           case RTAR:
               return s->rtar;
           case RDAR1:
               return s->rdar1;
           case RDAR2:
               return s->rdar2;
           case RYAR1:
               return s->ryar1;
           case RYAR2:
               return s->ryar2;
           case SWAR1:
               return s->swar1;
           case SWAR2:
               return s->swar2;
           case PIAR:
               return s->piar;
           case RCNR:
               return s->last_rcnr + ((qemu_get_clock(rt_clock) - s->last_hz) << 15) /
                       (1000 * ((s->rttr & 0xffff) + 1));
           case RDCR:
               return s->last_rdcr + ((qemu_get_clock(rt_clock) - s->last_hz) << 15) /
                       (1000 * ((s->rttr & 0xffff) + 1));
           case RYCR:
               return s->last_rycr;
           case SWCR:
               if (s->rtsr & (1 << 12))
                   return s->last_swcr + (qemu_get_clock(rt_clock) - s->last_sw) / 10;
               else
                   return s->last_swcr;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_rtc_write(void *opaque, target_phys_addr_t addr,
                       uint32_t value)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           addr -= s->rtc_base;
           switch (addr) {
           case RTTR:
               if (!(s->rttr & (1 << 31))) {
                   pxa2xx_rtc_hzupdate(s);
                   s->rttr = value;
                   pxa2xx_rtc_alarm_update(s, s->rtsr);
+              }
               break;
           case RTSR:
               if ((s->rtsr ^ value) & (1 << 15))
                   pxa2xx_rtc_piupdate(s);
               if ((s->rtsr ^ value) & (1 << 12))
                   pxa2xx_rtc_swupdate(s);
               if (((s->rtsr ^ value) & 0x4aac) | (value & ~0xdaac))
                   pxa2xx_rtc_alarm_update(s, value);
               s->rtsr = (value & 0xdaac) | (s->rtsr & ~(value & ~0xdaac));
               pxa2xx_rtc_int_update(s);
               break;
           case RTAR:
               s->rtar = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case RDAR1:
               s->rdar1 = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case RDAR2:
               s->rdar2 = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case RYAR1:
               s->ryar1 = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case RYAR2:
               s->ryar2 = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case SWAR1:
               pxa2xx_rtc_swupdate(s);
               s->swar1 = value;
               s->last_swcr = 0;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case SWAR2:
               s->swar2 = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case PIAR:
               s->piar = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case RCNR:
               pxa2xx_rtc_hzupdate(s);
               s->last_rcnr = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case RDCR:
               pxa2xx_rtc_hzupdate(s);
               s->last_rdcr = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case RYCR:
               s->last_rycr = value;
               break;
           case SWCR:
               pxa2xx_rtc_swupdate(s);
               s->last_swcr = value;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           case RTCPICR:
               pxa2xx_rtc_piupdate(s);
               s->last_rtcpicr = value & 0xffff;
               pxa2xx_rtc_alarm_update(s, s->rtsr);
               break;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
+          }
+      }
       static CPUReadMemoryFunc *pxa2xx_rtc_readfn[] = {
           pxa2xx_rtc_read,
           pxa2xx_rtc_read,
           pxa2xx_rtc_read,
       };
       static CPUWriteMemoryFunc *pxa2xx_rtc_writefn[] = {
           pxa2xx_rtc_write,
           pxa2xx_rtc_write,
           pxa2xx_rtc_write,
       };
       static void pxa2xx_rtc_init(struct pxa2xx_state_s *s)
+      {
           struct tm tm;
           int wom;
           s->rttr = 0x7fff;
           s->rtsr = 0;
           qemu_get_timedate(&tm, 0);
           wom = ((tm.tm_mday - 1) / 7) + 1;
           s->last_rcnr = (uint32_t) mktime(&tm);
           s->last_rdcr = (wom << 20) | ((tm.tm_wday + 1) << 17) |
                   (tm.tm_hour << 12) | (tm.tm_min << 6) | tm.tm_sec;
           s->last_rycr = ((tm.tm_year + 1900) << 9) |
                   ((tm.tm_mon + 1) << 5) | tm.tm_mday;
           s->last_swcr = (tm.tm_hour << 19) |
                   (tm.tm_min << 13) | (tm.tm_sec << 7);
           s->last_rtcpicr = 0;
           s->last_hz = s->last_sw = s->last_pi = qemu_get_clock(rt_clock);
           s->rtc_hz    = qemu_new_timer(rt_clock, pxa2xx_rtc_hz_tick,    s);
           s->rtc_rdal1 = qemu_new_timer(rt_clock, pxa2xx_rtc_rdal1_tick, s);
           s->rtc_rdal2 = qemu_new_timer(rt_clock, pxa2xx_rtc_rdal2_tick, s);
           s->rtc_swal1 = qemu_new_timer(rt_clock, pxa2xx_rtc_swal1_tick, s);
           s->rtc_swal2 = qemu_new_timer(rt_clock, pxa2xx_rtc_swal2_tick, s);
           s->rtc_pi    = qemu_new_timer(rt_clock, pxa2xx_rtc_pi_tick,    s);
+      }
       static void pxa2xx_rtc_save(QEMUFile *f, void *opaque)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           pxa2xx_rtc_hzupdate(s);
           pxa2xx_rtc_piupdate(s);
           pxa2xx_rtc_swupdate(s);
           qemu_put_be32s(f, &s->rttr);
           qemu_put_be32s(f, &s->rtsr);
           qemu_put_be32s(f, &s->rtar);
           qemu_put_be32s(f, &s->rdar1);
           qemu_put_be32s(f, &s->rdar2);
           qemu_put_be32s(f, &s->ryar1);
           qemu_put_be32s(f, &s->ryar2);
           qemu_put_be32s(f, &s->swar1);
           qemu_put_be32s(f, &s->swar2);
           qemu_put_be32s(f, &s->piar);
           qemu_put_be32s(f, &s->last_rcnr);
           qemu_put_be32s(f, &s->last_rdcr);
           qemu_put_be32s(f, &s->last_rycr);
           qemu_put_be32s(f, &s->last_swcr);
           qemu_put_be32s(f, &s->last_rtcpicr);
           qemu_put_be64s(f, (uint64_t *) &s->last_hz);
           qemu_put_be64s(f, (uint64_t *) &s->last_sw);
           qemu_put_be64s(f, (uint64_t *) &s->last_pi);
+      }
       static int pxa2xx_rtc_load(QEMUFile *f, void *opaque, int version_id)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           qemu_get_be32s(f, &s->rttr);
           qemu_get_be32s(f, &s->rtsr);
           qemu_get_be32s(f, &s->rtar);
           qemu_get_be32s(f, &s->rdar1);
           qemu_get_be32s(f, &s->rdar2);
           qemu_get_be32s(f, &s->ryar1);
           qemu_get_be32s(f, &s->ryar2);
           qemu_get_be32s(f, &s->swar1);
           qemu_get_be32s(f, &s->swar2);
           qemu_get_be32s(f, &s->piar);
           qemu_get_be32s(f, &s->last_rcnr);
           qemu_get_be32s(f, &s->last_rdcr);
           qemu_get_be32s(f, &s->last_rycr);
           qemu_get_be32s(f, &s->last_swcr);
           qemu_get_be32s(f, &s->last_rtcpicr);
           qemu_get_be64s(f, (uint64_t *) &s->last_hz);
           qemu_get_be64s(f, (uint64_t *) &s->last_sw);
           qemu_get_be64s(f, (uint64_t *) &s->last_pi);
           pxa2xx_rtc_alarm_update(s, s->rtsr);
           return 0;
+      }
       /* I2C Interface */
       struct pxa2xx_i2c_s {
           i2c_slave slave;
           i2c_bus *bus;
           target_phys_addr_t base;
           qemu_irq irq;
           uint16_t control;
           uint16_t status;
           uint8_t ibmr;
           uint8_t data;
       };
       #define IBMR        0x80        /* I2C Bus Monitor register */
       #define IDBR        0x88        /* I2C Data Buffer register */
       #define ICR        0x90        /* I2C Control register */
       #define ISR        0x98        /* I2C Status register */
       #define ISAR        0xa0        /* I2C Slave Address register */
       static void pxa2xx_i2c_update(struct pxa2xx_i2c_s *s)
+      {
           uint16_t level = 0;
           level |= s->status & s->control & (1 << 10);                /* BED */
           level |= (s->status & (1 << 7)) && (s->control & (1 << 9));        /* IRF */
           level |= (s->status & (1 << 6)) && (s->control & (1 << 8));        /* ITE */
           level |= s->status & (1 << 9);                                /* SAD */
           qemu_set_irq(s->irq, !!level);
+      }
       /* These are only stubs now.  */
       static void pxa2xx_i2c_event(i2c_slave *i2c, enum i2c_event event)
+      {
           struct pxa2xx_i2c_s *s = (struct pxa2xx_i2c_s *) i2c;
           switch (event) {
           case I2C_START_SEND:
               s->status |= (1 << 9);                                /* set SAD */
               s->status &= ~(1 << 0);                                /* clear RWM */
               break;
           case I2C_START_RECV:
               s->status |= (1 << 9);                                /* set SAD */
               s->status |= 1 << 0;                                /* set RWM */
               break;
           case I2C_FINISH:
               s->status |= (1 << 4);                                /* set SSD */
               break;
           case I2C_NACK:
               s->status |= 1 << 1;                                /* set ACKNAK */
               break;
+          }
           pxa2xx_i2c_update(s);
+      }
       static int pxa2xx_i2c_rx(i2c_slave *i2c)
+      {
           struct pxa2xx_i2c_s *s = (struct pxa2xx_i2c_s *) i2c;
           if ((s->control & (1 << 14)) || !(s->control & (1 << 6)))
               return 0;
           if (s->status & (1 << 0)) {                        /* RWM */
               s->status |= 1 << 6;                        /* set ITE */
+          }
           pxa2xx_i2c_update(s);
           return s->data;
+      }
       static int pxa2xx_i2c_tx(i2c_slave *i2c, uint8_t data)
+      {
           struct pxa2xx_i2c_s *s = (struct pxa2xx_i2c_s *) i2c;
           if ((s->control & (1 << 14)) || !(s->control & (1 << 6)))
               return 1;
           if (!(s->status & (1 << 0))) {                /* RWM */
               s->status |= 1 << 7;                        /* set IRF */
               s->data = data;
+          }
           pxa2xx_i2c_update(s);
           return 1;
+      }
       static uint32_t pxa2xx_i2c_read(void *opaque, target_phys_addr_t addr)
+      {
           struct pxa2xx_i2c_s *s = (struct pxa2xx_i2c_s *) opaque;
           addr -= s->base;
           switch (addr) {
           case ICR:
               return s->control;
           case ISR:
               return s->status | (i2c_bus_busy(s->bus) << 2);
           case ISAR:
               return s->slave.address;
           case IDBR:
               return s->data;
           case IBMR:
               if (s->status & (1 << 2))
                   s->ibmr ^= 3;        /* Fake SCL and SDA pin changes */
               else
                   s->ibmr = 0;
               return s->ibmr;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_i2c_write(void *opaque, target_phys_addr_t addr,
                       uint32_t value)
+      {
           struct pxa2xx_i2c_s *s = (struct pxa2xx_i2c_s *) opaque;
           int ack;
           addr -= s->base;
           switch (addr) {
           case ICR:
               s->control = value & 0xfff7;
               if ((value & (1 << 3)) && (value & (1 << 6))) {        /* TB and IUE */
                   /* TODO: slave mode */
                   if (value & (1 << 0)) {                        /* START condition */
                       if (s->data & 1)
                           s->status |= 1 << 0;                /* set RWM */
                       else
                           s->status &= ~(1 << 0);                /* clear RWM */
                       ack = !i2c_start_transfer(s->bus, s->data >> 1, s->data & 1);
                   } else {
                       if (s->status & (1 << 0)) {                /* RWM */
                           s->data = i2c_recv(s->bus);
                           if (value & (1 << 2))                /* ACKNAK */
                               i2c_nack(s->bus);
                           ack = 1;
                       } else
                           ack = !i2c_send(s->bus, s->data);
+                  }
                   if (value & (1 << 1))                        /* STOP condition */
                       i2c_end_transfer(s->bus);
                   if (ack) {
                       if (value & (1 << 0))                        /* START condition */
                           s->status |= 1 << 6;                /* set ITE */
                       else
                           if (s->status & (1 << 0))                /* RWM */
                               s->status |= 1 << 7;                /* set IRF */
                           else
                               s->status |= 1 << 6;                /* set ITE */
                       s->status &= ~(1 << 1);                        /* clear ACKNAK */
                   } else {
                       s->status |= 1 << 6;                        /* set ITE */
                       s->status |= 1 << 10;                        /* set BED */
                       s->status |= 1 << 1;                        /* set ACKNAK */
+                  }
+              }
               if (!(value & (1 << 3)) && (value & (1 << 6)))        /* !TB and IUE */
                   if (value & (1 << 4))                        /* MA */
                       i2c_end_transfer(s->bus);
               pxa2xx_i2c_update(s);
               break;
           case ISR:
               s->status &= ~(value & 0x07f0);
               pxa2xx_i2c_update(s);
               break;
           case ISAR:
               i2c_set_slave_address(&s->slave, value & 0x7f);
               break;
           case IDBR:
               s->data = value & 0xff;
               break;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
+          }
+      }
       static CPUReadMemoryFunc *pxa2xx_i2c_readfn[] = {
           pxa2xx_i2c_read,
           pxa2xx_i2c_read,
           pxa2xx_i2c_read,
       };
       static CPUWriteMemoryFunc *pxa2xx_i2c_writefn[] = {
           pxa2xx_i2c_write,
           pxa2xx_i2c_write,
           pxa2xx_i2c_write,
       };
       static void pxa2xx_i2c_save(QEMUFile *f, void *opaque)
+      {
           struct pxa2xx_i2c_s *s = (struct pxa2xx_i2c_s *) opaque;
           qemu_put_be16s(f, &s->control);
           qemu_put_be16s(f, &s->status);
           qemu_put_8s(f, &s->ibmr);
           qemu_put_8s(f, &s->data);
           i2c_bus_save(f, s->bus);
           i2c_slave_save(f, &s->slave);
+      }
       static int pxa2xx_i2c_load(QEMUFile *f, void *opaque, int version_id)
+      {
           struct pxa2xx_i2c_s *s = (struct pxa2xx_i2c_s *) opaque;
           qemu_get_be16s(f, &s->control);
           qemu_get_be16s(f, &s->status);
           qemu_get_8s(f, &s->ibmr);
           qemu_get_8s(f, &s->data);
           i2c_bus_load(f, s->bus);
           i2c_slave_load(f, &s->slave);
           return 0;
+      }
       struct pxa2xx_i2c_s *pxa2xx_i2c_init(target_phys_addr_t base,
                       qemu_irq irq, uint32_t page_size)
+      {
           int iomemtype;
           struct pxa2xx_i2c_s *s = (struct pxa2xx_i2c_s *)
                   i2c_slave_init(i2c_init_bus(), 0, sizeof(struct pxa2xx_i2c_s));
           s->base = base;
           s->irq = irq;
           s->slave.event = pxa2xx_i2c_event;
           s->slave.recv = pxa2xx_i2c_rx;
           s->slave.send = pxa2xx_i2c_tx;
           s->bus = i2c_init_bus();
           iomemtype = cpu_register_io_memory(0, pxa2xx_i2c_readfn,
                           pxa2xx_i2c_writefn, s);
           cpu_register_physical_memory(s->base & ~page_size, page_size, iomemtype);
           register_savevm("pxa2xx_i2c", base, 0,
                           pxa2xx_i2c_save, pxa2xx_i2c_load, s);
           return s;
+      }
       i2c_bus *pxa2xx_i2c_bus(struct pxa2xx_i2c_s *s)
+      {
           return s->bus;
+      }
       /* PXA Inter-IC Sound Controller */
       static void pxa2xx_i2s_reset(struct pxa2xx_i2s_s *i2s)
+      {
           i2s->rx_len = 0;
           i2s->tx_len = 0;
           i2s->fifo_len = 0;
           i2s->clk = 0x1a;
           i2s->control[0] = 0x00;
           i2s->control[1] = 0x00;
           i2s->status = 0x00;
           i2s->mask = 0x00;
+      }
       #define SACR_TFTH(val)        ((val >> 8) & 0xf)
       #define SACR_RFTH(val)        ((val >> 12) & 0xf)
       #define SACR_DREC(val)        (val & (1 << 3))
       #define SACR_DPRL(val)        (val & (1 << 4))
       static inline void pxa2xx_i2s_update(struct pxa2xx_i2s_s *i2s)
+      {
           int rfs, tfs;
           rfs = SACR_RFTH(i2s->control[0]) < i2s->rx_len &&
                   !SACR_DREC(i2s->control[1]);
           tfs = (i2s->tx_len || i2s->fifo_len < SACR_TFTH(i2s->control[0])) &&
                   i2s->enable && !SACR_DPRL(i2s->control[1]);
           pxa2xx_dma_request(i2s->dma, PXA2XX_RX_RQ_I2S, rfs);
           pxa2xx_dma_request(i2s->dma, PXA2XX_TX_RQ_I2S, tfs);
           i2s->status &= 0xe0;
           if (i2s->fifo_len < 16 || !i2s->enable)
               i2s->status |= 1 << 0;                        /* TNF */
           if (i2s->rx_len)
               i2s->status |= 1 << 1;                        /* RNE */
           if (i2s->enable)
               i2s->status |= 1 << 2;                        /* BSY */
           if (tfs)
               i2s->status |= 1 << 3;                        /* TFS */
           if (rfs)
               i2s->status |= 1 << 4;                        /* RFS */
           if (!(i2s->tx_len && i2s->enable))
               i2s->status |= i2s->fifo_len << 8;        /* TFL */
           i2s->status |= MAX(i2s->rx_len, 0xf) << 12;        /* RFL */
           qemu_set_irq(i2s->irq, i2s->status & i2s->mask);
+      }
       #define SACR0        0x00        /* Serial Audio Global Control register */
       #define SACR1        0x04        /* Serial Audio I2S/MSB-Justified Control register */
       #define SASR0        0x0c        /* Serial Audio Interface and FIFO Status register */
       #define SAIMR        0x14        /* Serial Audio Interrupt Mask register */
       #define SAICR        0x18        /* Serial Audio Interrupt Clear register */
       #define SADIV        0x60        /* Serial Audio Clock Divider register */
       #define SADR        0x80        /* Serial Audio Data register */
       static uint32_t pxa2xx_i2s_read(void *opaque, target_phys_addr_t addr)
+      {
           struct pxa2xx_i2s_s *s = (struct pxa2xx_i2s_s *) opaque;
           addr -= s->base;
           switch (addr) {
           case SACR0:
               return s->control[0];
           case SACR1:
               return s->control[1];
           case SASR0:
               return s->status;
           case SAIMR:
               return s->mask;
           case SAICR:
               return 0;
           case SADIV:
               return s->clk;
           case SADR:
               if (s->rx_len > 0) {
                   s->rx_len --;
                   pxa2xx_i2s_update(s);
                   return s->codec_in(s->opaque);
+              }
               return 0;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_i2s_write(void *opaque, target_phys_addr_t addr,
                       uint32_t value)
+      {
           struct pxa2xx_i2s_s *s = (struct pxa2xx_i2s_s *) opaque;
           uint32_t *sample;
           addr -= s->base;
           switch (addr) {
           case SACR0:
               if (value & (1 << 3))                                /* RST */
                   pxa2xx_i2s_reset(s);
               s->control[0] = value & 0xff3d;
               if (!s->enable && (value & 1) && s->tx_len) {        /* ENB */
                   for (sample = s->fifo; s->fifo_len > 0; s->fifo_len --, sample ++)
                       s->codec_out(s->opaque, *sample);
                   s->status &= ~(1 << 7);                        /* I2SOFF */
+              }
               if (value & (1 << 4))                                /* EFWR */
                   printf("%s: Attempt to use special function\n", __FUNCTION__);
               s->enable = ((value ^ 4) & 5) == 5;                /* ENB && !RST*/
               pxa2xx_i2s_update(s);
               break;
           case SACR1:
               s->control[1] = value & 0x0039;
               if (value & (1 << 5))                                /* ENLBF */
                   printf("%s: Attempt to use loopback function\n", __FUNCTION__);
               if (value & (1 << 4))                                /* DPRL */
                   s->fifo_len = 0;
               pxa2xx_i2s_update(s);
               break;
           case SAIMR:
               s->mask = value & 0x0078;
               pxa2xx_i2s_update(s);
               break;
           case SAICR:
               s->status &= ~(value & (3 << 5));
               pxa2xx_i2s_update(s);
               break;
           case SADIV:
               s->clk = value & 0x007f;
               break;
           case SADR:
               if (s->tx_len && s->enable) {
                   s->tx_len --;
                   pxa2xx_i2s_update(s);
                   s->codec_out(s->opaque, value);
               } else if (s->fifo_len < 16) {
                   s->fifo[s->fifo_len ++] = value;
                   pxa2xx_i2s_update(s);
+              }
               break;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
+          }
+      }
       static CPUReadMemoryFunc *pxa2xx_i2s_readfn[] = {
           pxa2xx_i2s_read,
           pxa2xx_i2s_read,
           pxa2xx_i2s_read,
       };
       static CPUWriteMemoryFunc *pxa2xx_i2s_writefn[] = {
           pxa2xx_i2s_write,
           pxa2xx_i2s_write,
           pxa2xx_i2s_write,
       };
       static void pxa2xx_i2s_save(QEMUFile *f, void *opaque)
+      {
           struct pxa2xx_i2s_s *s = (struct pxa2xx_i2s_s *) opaque;
           qemu_put_be32s(f, &s->control[0]);
           qemu_put_be32s(f, &s->control[1]);
           qemu_put_be32s(f, &s->status);
           qemu_put_be32s(f, &s->mask);
           qemu_put_be32s(f, &s->clk);
           qemu_put_be32(f, s->enable);
           qemu_put_be32(f, s->rx_len);
           qemu_put_be32(f, s->tx_len);
           qemu_put_be32(f, s->fifo_len);
+      }
       static int pxa2xx_i2s_load(QEMUFile *f, void *opaque, int version_id)
+      {
           struct pxa2xx_i2s_s *s = (struct pxa2xx_i2s_s *) opaque;
           qemu_get_be32s(f, &s->control[0]);
           qemu_get_be32s(f, &s->control[1]);
           qemu_get_be32s(f, &s->status);
           qemu_get_be32s(f, &s->mask);
           qemu_get_be32s(f, &s->clk);
           s->enable = qemu_get_be32(f);
           s->rx_len = qemu_get_be32(f);
           s->tx_len = qemu_get_be32(f);
           s->fifo_len = qemu_get_be32(f);
           return 0;
+      }
       static void pxa2xx_i2s_data_req(void *opaque, int tx, int rx)
+      {
           struct pxa2xx_i2s_s *s = (struct pxa2xx_i2s_s *) opaque;
           uint32_t *sample;
           /* Signal FIFO errors */
           if (s->enable && s->tx_len)
               s->status |= 1 << 5;                /* TUR */
           if (s->enable && s->rx_len)
               s->status |= 1 << 6;                /* ROR */
           /* Should be tx - MIN(tx, s->fifo_len) but we don't really need to
            * handle the cases where it makes a difference.  */
           s->tx_len = tx - s->fifo_len;
           s->rx_len = rx;
           /* Note that is s->codec_out wasn't set, we wouldn't get called.  */
           if (s->enable)
               for (sample = s->fifo; s->fifo_len; s->fifo_len --, sample ++)
                   s->codec_out(s->opaque, *sample);
           pxa2xx_i2s_update(s);
+      }
       static struct pxa2xx_i2s_s *pxa2xx_i2s_init(target_phys_addr_t base,
                       qemu_irq irq, struct pxa2xx_dma_state_s *dma)
+      {
           int iomemtype;
           struct pxa2xx_i2s_s *s = (struct pxa2xx_i2s_s *)
                   qemu_mallocz(sizeof(struct pxa2xx_i2s_s));
           s->base = base;
           s->irq = irq;
           s->dma = dma;
           s->data_req = pxa2xx_i2s_data_req;
           pxa2xx_i2s_reset(s);
           iomemtype = cpu_register_io_memory(0, pxa2xx_i2s_readfn,
                           pxa2xx_i2s_writefn, s);
           cpu_register_physical_memory(s->base & 0xfff00000, 0x100000, iomemtype);
           register_savevm("pxa2xx_i2s", base, 0,
                           pxa2xx_i2s_save, pxa2xx_i2s_load, s);
           return s;
+      }
       /* PXA Fast Infra-red Communications Port */
       struct pxa2xx_fir_s {
           target_phys_addr_t base;
           qemu_irq irq;
           struct pxa2xx_dma_state_s *dma;
           int enable;
           CharDriverState *chr;
           uint8_t control[3];
           uint8_t status[2];
           int rx_len;
           int rx_start;
           uint8_t rx_fifo[64];
       };
       static void pxa2xx_fir_reset(struct pxa2xx_fir_s *s)
+      {
           s->control[0] = 0x00;
           s->control[1] = 0x00;
           s->control[2] = 0x00;
           s->status[0] = 0x00;
           s->status[1] = 0x00;
           s->enable = 0;
+      }
       static inline void pxa2xx_fir_update(struct pxa2xx_fir_s *s)
+      {
           static const int tresh[4] = { 8, 16, 32, 0 };
           int intr = 0;
           if ((s->control[0] & (1 << 4)) &&                        /* RXE */
                           s->rx_len >= tresh[s->control[2] & 3])        /* TRIG */
               s->status[0] |= 1 << 4;                                /* RFS */
           else
               s->status[0] &= ~(1 << 4);                        /* RFS */
           if (s->control[0] & (1 << 3))                        /* TXE */
               s->status[0] |= 1 << 3;                                /* TFS */
           else
               s->status[0] &= ~(1 << 3);                        /* TFS */
           if (s->rx_len)
               s->status[1] |= 1 << 2;                                /* RNE */
           else
               s->status[1] &= ~(1 << 2);                        /* RNE */
           if (s->control[0] & (1 << 4))                        /* RXE */
               s->status[1] |= 1 << 0;                                /* RSY */
           else
               s->status[1] &= ~(1 << 0);                        /* RSY */
           intr |= (s->control[0] & (1 << 5)) &&                /* RIE */
                   (s->status[0] & (1 << 4));                        /* RFS */
           intr |= (s->control[0] & (1 << 6)) &&                /* TIE */
                   (s->status[0] & (1 << 3));                        /* TFS */
           intr |= (s->control[2] & (1 << 4)) &&                /* TRAIL */
                   (s->status[0] & (1 << 6));                        /* EOC */
           intr |= (s->control[0] & (1 << 2)) &&                /* TUS */
                   (s->status[0] & (1 << 1));                        /* TUR */
           intr |= s->status[0] & 0x25;                        /* FRE, RAB, EIF */
           pxa2xx_dma_request(s->dma, PXA2XX_RX_RQ_ICP, (s->status[0] >> 4) & 1);
           pxa2xx_dma_request(s->dma, PXA2XX_TX_RQ_ICP, (s->status[0] >> 3) & 1);
           qemu_set_irq(s->irq, intr && s->enable);
+      }
       #define ICCR0        0x00        /* FICP Control register 0 */
       #define ICCR1        0x04        /* FICP Control register 1 */
       #define ICCR2        0x08        /* FICP Control register 2 */
       #define ICDR        0x0c        /* FICP Data register */
       #define ICSR0        0x14        /* FICP Status register 0 */
       #define ICSR1        0x18        /* FICP Status register 1 */
       #define ICFOR        0x1c        /* FICP FIFO Occupancy Status register */
       static uint32_t pxa2xx_fir_read(void *opaque, target_phys_addr_t addr)
+      {
           struct pxa2xx_fir_s *s = (struct pxa2xx_fir_s *) opaque;
           uint8_t ret;
           addr -= s->base;
           switch (addr) {
           case ICCR0:
               return s->control[0];
           case ICCR1:
               return s->control[1];
           case ICCR2:
               return s->control[2];
           case ICDR:
               s->status[0] &= ~0x01;
               s->status[1] &= ~0x72;
               if (s->rx_len) {
                   s->rx_len --;
                   ret = s->rx_fifo[s->rx_start ++];
                   s->rx_start &= 63;
                   pxa2xx_fir_update(s);
                   return ret;
+              }
               printf("%s: Rx FIFO underrun.\n", __FUNCTION__);
               break;
           case ICSR0:
               return s->status[0];
           case ICSR1:
               return s->status[1] | (1 << 3);                        /* TNF */
           case ICFOR:
               return s->rx_len;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
               break;
+          }
           return 0;
+      }
       static void pxa2xx_fir_write(void *opaque, target_phys_addr_t addr,
                       uint32_t value)
+      {
           struct pxa2xx_fir_s *s = (struct pxa2xx_fir_s *) opaque;
           uint8_t ch;
           addr -= s->base;
           switch (addr) {
           case ICCR0:
               s->control[0] = value;
               if (!(value & (1 << 4)))                        /* RXE */
                   s->rx_len = s->rx_start = 0;
               if (!(value & (1 << 3)))                        /* TXE */
                   /* Nop */;
               s->enable = value & 1;                                /* ITR */
               if (!s->enable)
                   s->status[0] = 0;
               pxa2xx_fir_update(s);
               break;
           case ICCR1:
               s->control[1] = value;
               break;
           case ICCR2:
               s->control[2] = value & 0x3f;
               pxa2xx_fir_update(s);
               break;
           case ICDR:
               if (s->control[2] & (1 << 2))                        /* TXP */
                   ch = value;
               else
                   ch = ~value;
               if (s->chr && s->enable && (s->control[0] & (1 << 3)))        /* TXE */
                   qemu_chr_write(s->chr, &ch, 1);
               break;
           case ICSR0:
               s->status[0] &= ~(value & 0x66);
               pxa2xx_fir_update(s);
               break;
           case ICFOR:
               break;
           default:
               printf("%s: Bad register " REG_FMT "\n", __FUNCTION__, addr);
+          }
+      }
       static CPUReadMemoryFunc *pxa2xx_fir_readfn[] = {
           pxa2xx_fir_read,
           pxa2xx_fir_read,
           pxa2xx_fir_read,
       };
       static CPUWriteMemoryFunc *pxa2xx_fir_writefn[] = {
           pxa2xx_fir_write,
           pxa2xx_fir_write,
           pxa2xx_fir_write,
       };
       static int pxa2xx_fir_is_empty(void *opaque)
+      {
           struct pxa2xx_fir_s *s = (struct pxa2xx_fir_s *) opaque;
           return (s->rx_len < 64);
+      }
       static void pxa2xx_fir_rx(void *opaque, const uint8_t *buf, int size)
+      {
           struct pxa2xx_fir_s *s = (struct pxa2xx_fir_s *) opaque;
           if (!(s->control[0] & (1 << 4)))                        /* RXE */
               return;
           while (size --) {
               s->status[1] |= 1 << 4;                                /* EOF */
               if (s->rx_len >= 64) {
                   s->status[1] |= 1 << 6;                        /* ROR */
                   break;
+              }
               if (s->control[2] & (1 << 3))                        /* RXP */
                   s->rx_fifo[(s->rx_start + s->rx_len ++) & 63] = *(buf ++);
               else
                   s->rx_fifo[(s->rx_start + s->rx_len ++) & 63] = ~*(buf ++);
+          }
           pxa2xx_fir_update(s);
+      }
       static void pxa2xx_fir_event(void *opaque, int event)
+      {
+      }
       static void pxa2xx_fir_save(QEMUFile *f, void *opaque)
+      {
           struct pxa2xx_fir_s *s = (struct pxa2xx_fir_s *) opaque;
           int i;
           qemu_put_be32(f, s->enable);
           qemu_put_8s(f, &s->control[0]);
           qemu_put_8s(f, &s->control[1]);
           qemu_put_8s(f, &s->control[2]);
           qemu_put_8s(f, &s->status[0]);
           qemu_put_8s(f, &s->status[1]);
           qemu_put_byte(f, s->rx_len);
           for (i = 0; i < s->rx_len; i ++)
               qemu_put_byte(f, s->rx_fifo[(s->rx_start + i) & 63]);
+      }
       static int pxa2xx_fir_load(QEMUFile *f, void *opaque, int version_id)
+      {
           struct pxa2xx_fir_s *s = (struct pxa2xx_fir_s *) opaque;
           int i;
           s->enable = qemu_get_be32(f);
           qemu_get_8s(f, &s->control[0]);
           qemu_get_8s(f, &s->control[1]);
           qemu_get_8s(f, &s->control[2]);
           qemu_get_8s(f, &s->status[0]);
           qemu_get_8s(f, &s->status[1]);
           s->rx_len = qemu_get_byte(f);
           s->rx_start = 0;
           for (i = 0; i < s->rx_len; i ++)
               s->rx_fifo[i] = qemu_get_byte(f);
           return 0;
+      }
       static struct pxa2xx_fir_s *pxa2xx_fir_init(target_phys_addr_t base,
                       qemu_irq irq, struct pxa2xx_dma_state_s *dma,
                       CharDriverState *chr)
+      {
           int iomemtype;
           struct pxa2xx_fir_s *s = (struct pxa2xx_fir_s *)
                   qemu_mallocz(sizeof(struct pxa2xx_fir_s));
           s->base = base;
           s->irq = irq;
           s->dma = dma;
           s->chr = chr;
           pxa2xx_fir_reset(s);
           iomemtype = cpu_register_io_memory(0, pxa2xx_fir_readfn,
                           pxa2xx_fir_writefn, s);
           cpu_register_physical_memory(s->base, 0x1000, iomemtype);
           if (chr)
               qemu_chr_add_handlers(chr, pxa2xx_fir_is_empty,
                               pxa2xx_fir_rx, pxa2xx_fir_event, s);
           register_savevm("pxa2xx_fir", 0, 0, pxa2xx_fir_save, pxa2xx_fir_load, s);
           return s;
+      }
       static void pxa2xx_reset(void *opaque, int line, int level)
+      {
           struct pxa2xx_state_s *s = (struct pxa2xx_state_s *) opaque;
           if (level && (s->pm_regs[PCFR >> 2] & 0x10)) {        /* GPR_EN */
               cpu_reset(s->env);
               /* TODO: reset peripherals */
+          }
+      }
       /* Initialise a PXA270 integrated chip (ARM based core).  */
       struct pxa2xx_state_s *pxa270_init(unsigned int sdram_size,
                       DisplayState *ds, const char *revision)
+      {
           struct pxa2xx_state_s *s;
           struct pxa2xx_ssp_s *ssp;
           int iomemtype, i;
           int index;
           s = (struct pxa2xx_state_s *) qemu_mallocz(sizeof(struct pxa2xx_state_s));
           if (revision && strncmp(revision, "pxa27", 5)) {
               fprintf(stderr, "Machine requires a PXA27x processor.\n");
               exit(1);
+          }
           if (!revision)
               revision = "pxa270";
           s->env = cpu_init(revision);
           if (!s->env) {
               fprintf(stderr, "Unable to find CPU definition\n");
               exit(1);
+          }
           s->reset = qemu_allocate_irqs(pxa2xx_reset, s, 1)[0];
           /* SDRAM & Internal Memory Storage */
           cpu_register_physical_memory(PXA2XX_SDRAM_BASE,
                           sdram_size, qemu_ram_alloc(sdram_size) | IO_MEM_RAM);
           cpu_register_physical_memory(PXA2XX_INTERNAL_BASE,
 x40000, qemu_ram_alloc(0x40000) | IO_MEM_RAM);
           s->pic = pxa2xx_pic_init(0x40d00000, s->env);
           s->dma = pxa27x_dma_init(0x40000000, s->pic[PXA2XX_PIC_DMA]);
           pxa27x_timer_init(0x40a00000, &s->pic[PXA2XX_PIC_OST_0],
                           s->pic[PXA27X_PIC_OST_4_11]);
           s->gpio = pxa2xx_gpio_init(0x40e00000, s->env, s->pic, 121);
           index = drive_get_index(IF_SD, 0, 0);
           if (index == -1) {
               fprintf(stderr, "qemu: missing SecureDigital device\n");
               exit(1);
+          }
           s->mmc = pxa2xx_mmci_init(0x41100000, drives_table[index].bdrv,
                                     s->pic[PXA2XX_PIC_MMC], s->dma);
           for (i = 0; pxa270_serial[i].io_base; i ++)
               if (serial_hds[i])
                   serial_mm_init(pxa270_serial[i].io_base, 2,
                                  s->pic[pxa270_serial[i].irqn], 14857000/16,
                                  serial_hds[i], 1);
               else
                   break;
           if (serial_hds[i])
               s->fir = pxa2xx_fir_init(0x40800000, s->pic[PXA2XX_PIC_ICP],
                               s->dma, serial_hds[i]);
           if (ds)
               s->lcd = pxa2xx_lcdc_init(0x44000000, s->pic[PXA2XX_PIC_LCD], ds);
           s->cm_base = 0x41300000;
           s->cm_regs[CCCR >> 2] = 0x02000210;        /* 416.0 MHz */
           s->clkcfg = 0x00000009;                /* Turbo mode active */
           iomemtype = cpu_register_io_memory(0, pxa2xx_cm_readfn,
                           pxa2xx_cm_writefn, s);
           cpu_register_physical_memory(s->cm_base, 0x1000, iomemtype);
           register_savevm("pxa2xx_cm", 0, 0, pxa2xx_cm_save, pxa2xx_cm_load, s);
           cpu_arm_set_cp_io(s->env, 14, pxa2xx_cp14_read, pxa2xx_cp14_write, s);
           s->mm_base = 0x48000000;
           s->mm_regs[MDMRS >> 2] = 0x00020002;
           s->mm_regs[MDREFR >> 2] = 0x03ca4000;
           s->mm_regs[MECR >> 2] = 0x00000001;        /* Two PC Card sockets */
           iomemtype = cpu_register_io_memory(0, pxa2xx_mm_readfn,
                           pxa2xx_mm_writefn, s);
           cpu_register_physical_memory(s->mm_base, 0x1000, iomemtype);
           register_savevm("pxa2xx_mm", 0, 0, pxa2xx_mm_save, pxa2xx_mm_load, s);
           s->pm_base = 0x40f00000;
           iomemtype = cpu_register_io_memory(0, pxa2xx_pm_readfn,
                           pxa2xx_pm_writefn, s);
           cpu_register_physical_memory(s->pm_base, 0x100, iomemtype);
           register_savevm("pxa2xx_pm", 0, 0, pxa2xx_pm_save, pxa2xx_pm_load, s);
           for (i = 0; pxa27x_ssp[i].io_base; i ++);
           s->ssp = (struct pxa2xx_ssp_s **)
                   qemu_mallocz(sizeof(struct pxa2xx_ssp_s *) * i);
           ssp = (struct pxa2xx_ssp_s *)
                   qemu_mallocz(sizeof(struct pxa2xx_ssp_s) * i);
           for (i = 0; pxa27x_ssp[i].io_base; i ++) {
               s->ssp[i] = &ssp[i];
               ssp[i].base = pxa27x_ssp[i].io_base;
               ssp[i].irq = s->pic[pxa27x_ssp[i].irqn];
               iomemtype = cpu_register_io_memory(0, pxa2xx_ssp_readfn,
                               pxa2xx_ssp_writefn, &ssp[i]);
               cpu_register_physical_memory(ssp[i].base, 0x1000, iomemtype);
               register_savevm("pxa2xx_ssp", i, 0,
                               pxa2xx_ssp_save, pxa2xx_ssp_load, s);
+          }
           if (usb_enabled) {
               usb_ohci_init_pxa(0x4c000000, 3, -1, s->pic[PXA2XX_PIC_USBH1]);
+          }
           s->pcmcia[0] = pxa2xx_pcmcia_init(0x20000000);
           s->pcmcia[1] = pxa2xx_pcmcia_init(0x30000000);
           s->rtc_base = 0x40900000;
           iomemtype = cpu_register_io_memory(0, pxa2xx_rtc_readfn,
                           pxa2xx_rtc_writefn, s);
           cpu_register_physical_memory(s->rtc_base, 0x1000, iomemtype);
           pxa2xx_rtc_init(s);
           register_savevm("pxa2xx_rtc", 0, 0, pxa2xx_rtc_save, pxa2xx_rtc_load, s);
           s->i2c[0] = pxa2xx_i2c_init(0x40301600, s->pic[PXA2XX_PIC_I2C], 0xffff);
           s->i2c[1] = pxa2xx_i2c_init(0x40f00100, s->pic[PXA2XX_PIC_PWRI2C], 0xff);
           s->i2s = pxa2xx_i2s_init(0x40400000, s->pic[PXA2XX_PIC_I2S], s->dma);
           s->kp = pxa27x_keypad_init(0x41500000, s->pic[PXA2XX_PIC_KEYPAD]);
           /* GPIO1 resets the processor */
           /* The handler can be overridden by board-specific code */
           pxa2xx_gpio_out_set(s->gpio, 1, s->reset);
           return s;
+      }
       /* Initialise a PXA255 integrated chip (ARM based core).  */
       struct pxa2xx_state_s *pxa255_init(unsigned int sdram_size,
                       DisplayState *ds)
+      {
           struct pxa2xx_state_s *s;
           struct pxa2xx_ssp_s *ssp;
           int iomemtype, i;
           int index;
           s = (struct pxa2xx_state_s *) qemu_mallocz(sizeof(struct pxa2xx_state_s));
           s->env = cpu_init("pxa255");
           if (!s->env) {
               fprintf(stderr, "Unable to find CPU definition\n");
               exit(1);
+          }
           s->reset = qemu_allocate_irqs(pxa2xx_reset, s, 1)[0];
           /* SDRAM & Internal Memory Storage */
           cpu_register_physical_memory(PXA2XX_SDRAM_BASE, sdram_size,
                           qemu_ram_alloc(sdram_size) | IO_MEM_RAM);
           cpu_register_physical_memory(PXA2XX_INTERNAL_BASE, PXA2XX_INTERNAL_SIZE,
                           qemu_ram_alloc(PXA2XX_INTERNAL_SIZE) | IO_MEM_RAM);
           s->pic = pxa2xx_pic_init(0x40d00000, s->env);
           s->dma = pxa255_dma_init(0x40000000, s->pic[PXA2XX_PIC_DMA]);
           pxa25x_timer_init(0x40a00000, &s->pic[PXA2XX_PIC_OST_0]);
           s->gpio = pxa2xx_gpio_init(0x40e00000, s->env, s->pic, 85);
           index = drive_get_index(IF_SD, 0, 0);
           if (index == -1) {
               fprintf(stderr, "qemu: missing SecureDigital device\n");
               exit(1);
+          }
           s->mmc = pxa2xx_mmci_init(0x41100000, drives_table[index].bdrv,
                                     s->pic[PXA2XX_PIC_MMC], s->dma);
           for (i = 0; pxa255_serial[i].io_base; i ++)
               if (serial_hds[i])
                   serial_mm_init(pxa255_serial[i].io_base, 2,
                                  s->pic[pxa255_serial[i].irqn], 14745600/16,
                                  serial_hds[i], 1);
               else
                   break;
           if (serial_hds[i])
               s->fir = pxa2xx_fir_init(0x40800000, s->pic[PXA2XX_PIC_ICP],
                               s->dma, serial_hds[i]);
           if (ds)
               s->lcd = pxa2xx_lcdc_init(0x44000000, s->pic[PXA2XX_PIC_LCD], ds);
           s->cm_base = 0x41300000;
           s->cm_regs[CCCR >> 2] = 0x02000210;        /* 416.0 MHz */
           s->clkcfg = 0x00000009;                /* Turbo mode active */
           iomemtype = cpu_register_io_memory(0, pxa2xx_cm_readfn,
                           pxa2xx_cm_writefn, s);
           cpu_register_physical_memory(s->cm_base, 0x1000, iomemtype);
           register_savevm("pxa2xx_cm", 0, 0, pxa2xx_cm_save, pxa2xx_cm_load, s);
           cpu_arm_set_cp_io(s->env, 14, pxa2xx_cp14_read, pxa2xx_cp14_write, s);
           s->mm_base = 0x48000000;
           s->mm_regs[MDMRS >> 2] = 0x00020002;
           s->mm_regs[MDREFR >> 2] = 0x03ca4000;
           s->mm_regs[MECR >> 2] = 0x00000001;        /* Two PC Card sockets */
           iomemtype = cpu_register_io_memory(0, pxa2xx_mm_readfn,
                           pxa2xx_mm_writefn, s);
           cpu_register_physical_memory(s->mm_base, 0x1000, iomemtype);
           register_savevm("pxa2xx_mm", 0, 0, pxa2xx_mm_save, pxa2xx_mm_load, s);
           s->pm_base = 0x40f00000;
           iomemtype = cpu_register_io_memory(0, pxa2xx_pm_readfn,
                           pxa2xx_pm_writefn, s);
           cpu_register_physical_memory(s->pm_base, 0x100, iomemtype);
           register_savevm("pxa2xx_pm", 0, 0, pxa2xx_pm_save, pxa2xx_pm_load, s);
           for (i = 0; pxa255_ssp[i].io_base; i ++);
           s->ssp = (struct pxa2xx_ssp_s **)
                   qemu_mallocz(sizeof(struct pxa2xx_ssp_s *) * i);
           ssp = (struct pxa2xx_ssp_s *)
                   qemu_mallocz(sizeof(struct pxa2xx_ssp_s) * i);
           for (i = 0; pxa255_ssp[i].io_base; i ++) {
               s->ssp[i] = &ssp[i];
               ssp[i].base = pxa255_ssp[i].io_base;
               ssp[i].irq = s->pic[pxa255_ssp[i].irqn];
               iomemtype = cpu_register_io_memory(0, pxa2xx_ssp_readfn,
                               pxa2xx_ssp_writefn, &ssp[i]);
               cpu_register_physical_memory(ssp[i].base, 0x1000, iomemtype);
               register_savevm("pxa2xx_ssp", i, 0,
                               pxa2xx_ssp_save, pxa2xx_ssp_load, s);
+          }
           if (usb_enabled) {
               usb_ohci_init_pxa(0x4c000000, 3, -1, s->pic[PXA2XX_PIC_USBH1]);
+          }
           s->pcmcia[0] = pxa2xx_pcmcia_init(0x20000000);
           s->pcmcia[1] = pxa2xx_pcmcia_init(0x30000000);
           s->rtc_base = 0x40900000;
           iomemtype = cpu_register_io_memory(0, pxa2xx_rtc_readfn,
                           pxa2xx_rtc_writefn, s);
           cpu_register_physical_memory(s->rtc_base, 0x1000, iomemtype);
           pxa2xx_rtc_init(s);
           register_savevm("pxa2xx_rtc", 0, 0, pxa2xx_rtc_save, pxa2xx_rtc_load, s);
           s->i2c[0] = pxa2xx_i2c_init(0x40301600, s->pic[PXA2XX_PIC_I2C], 0xffff);
           s->i2c[1] = pxa2xx_i2c_init(0x40f00100, s->pic[PXA2XX_PIC_PWRI2C], 0xff);
           s->i2s = pxa2xx_i2s_init(0x40400000, s->pic[PXA2XX_PIC_I2S], s->dma);
           /* GPIO1 resets the processor */
           /* The handler can be overridden by board-specific code */
           pxa2xx_gpio_out_set(s->gpio, 1, s->reset);
           return s;
+      }

Archipelago » qemu

root / hw / pxa2xx.c @ b3c7724c