@@ -45,6 +45,7 @@ obj-$(CONFIG_RASPI) += bcm2835_property.o
obj-$(CONFIG_SLAVIO) += slavio_misc.o
obj-$(CONFIG_ZYNQ) += zynq_slcr.o
obj-$(CONFIG_ZYNQ) += zynq-xadc.o
+obj-$(CONFIG_ZYNQ) += xilinx_zynqmp_crf.o
obj-$(CONFIG_STM32F2XX_SYSCFG) += stm32f2xx_syscfg.o
obj-$(CONFIG_MIPS_CPS) += mips_cmgcr.o
obj-$(CONFIG_MIPS_CPS) += mips_cpc.o
new file mode 100644
@@ -0,0 +1,968 @@
+/*
+ * QEMU model of the CRF_APB APB control registers for clock controller. The
+ * RST_ctrl_fpd will be added to this as well
+ *
+ * Copyright (c) 2014 Xilinx Inc.
+ *
+ * Autogenerated by xregqemu.py 2014-01-22.
+ *
+ * Permission is hereby granted, free of charge, to any person obtaining a copy
+ * of this software and associated documentation files (the "Software"), to deal
+ * in the Software without restriction, including without limitation the rights
+ * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
+ * copies of the Software, and to permit persons to whom the Software is
+ * furnished to do so, subject to the following conditions:
+ *
+ * The above copyright notice and this permission notice shall be included in
+ * all copies or substantial portions of the Software.
+ *
+ * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
+ * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
+ * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
+ * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
+ * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
+ * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
+ * THE SOFTWARE.
+ */
+
+#include "qemu/osdep.h"
+#include "hw/sysbus.h"
+#include "hw/register.h"
+#include "qemu/bitops.h"
+#include "qemu/log.h"
+#include "qemu/qemu-clock.h"
+
+#ifndef XILINX_CRF_APB_ERR_DEBUG
+#define XILINX_CRF_APB_ERR_DEBUG 0
+#endif
+
+#define TYPE_XILINX_CRF_APB "xlnx.zynqmp_crf"
+
+#define XILINX_CRF_APB(obj) \
+ OBJECT_CHECK(CRF_APB, (obj), TYPE_XILINX_CRF_APB)
+
+REG32(ERR_CTRL, 0x0)
+ FIELD(ERR_CTRL, SLVERR_ENABLE, 0, 1)
+REG32(IR_STATUS, 0x4)
+ FIELD(IR_STATUS, ADDR_DECODE_ERR, 0, 1)
+REG32(IR_MASK, 0x8)
+ FIELD(IR_MASK, ADDR_DECODE_ERR, 0, 1)
+REG32(IR_ENABLE, 0xc)
+ FIELD(IR_ENABLE, ADDR_DECODE_ERR, 0, 1)
+REG32(IR_DISABLE, 0x10)
+ FIELD(IR_DISABLE, ADDR_DECODE_ERR, 0, 1)
+REG32(CRF_ECO, 0x18)
+REG32(APLL_CTRL, 0x20)
+ FIELD(APLL_CTRL, POST_SRC, 24, 3)
+ FIELD(APLL_CTRL, PRE_SRC, 20, 3)
+ FIELD(APLL_CTRL, CLKOUTDIV, 17, 1)
+ FIELD(APLL_CTRL, DIV2, 16, 1)
+ FIELD(APLL_CTRL, FBDIV, 8, 7)
+ FIELD(APLL_CTRL, BYPASS, 3, 1)
+ FIELD(APLL_CTRL, RESET, 0, 1)
+REG32(APLL_CFG, 0x24)
+ FIELD(APLL_CFG, LOCK_DLY, 25, 7)
+ FIELD(APLL_CFG, LOCK_CNT, 13, 10)
+ FIELD(APLL_CFG, LFHF, 10, 2)
+ FIELD(APLL_CFG, CP, 5, 4)
+ FIELD(APLL_CFG, RES, 0, 4)
+REG32(APLL_FRAC_CFG, 0x28)
+ FIELD(APLL_FRAC_CFG, ENABLED, 31, 1)
+ FIELD(APLL_FRAC_CFG, SEED, 22, 3)
+ FIELD(APLL_FRAC_CFG, ALGRTHM, 19, 1)
+ FIELD(APLL_FRAC_CFG, ORDER, 18, 1)
+ FIELD(APLL_FRAC_CFG, DATA, 0, 16)
+REG32(DPLL_CTRL, 0x2c)
+ FIELD(DPLL_CTRL, POST_SRC, 24, 3)
+ FIELD(DPLL_CTRL, PRE_SRC, 20, 3)
+ FIELD(DPLL_CTRL, CLKOUTDIV, 17, 1)
+ FIELD(DPLL_CTRL, DIV2, 16, 1)
+ FIELD(DPLL_CTRL, FBDIV, 8, 7)
+ FIELD(DPLL_CTRL, BYPASS, 3, 1)
+ FIELD(DPLL_CTRL, RESET, 0, 1)
+REG32(DPLL_CFG, 0x30)
+ FIELD(DPLL_CFG, LOCK_DLY, 25, 7)
+ FIELD(DPLL_CFG, LOCK_CNT, 13, 10)
+ FIELD(DPLL_CFG, LFHF, 10, 2)
+ FIELD(DPLL_CFG, CP, 5, 4)
+ FIELD(DPLL_CFG, RES, 0, 4)
+REG32(DPLL_FRAC_CFG, 0x34)
+ FIELD(DPLL_FRAC_CFG, ENABLED, 31, 1)
+ FIELD(DPLL_FRAC_CFG, SEED, 22, 3)
+ FIELD(DPLL_FRAC_CFG, ALGRTHM, 19, 1)
+ FIELD(DPLL_FRAC_CFG, ORDER, 18, 1)
+ FIELD(DPLL_FRAC_CFG, DATA, 0, 16)
+REG32(VPLL_CTRL, 0x38)
+ FIELD(VPLL_CTRL, POST_SRC, 24, 3)
+ FIELD(VPLL_CTRL, PRE_SRC, 20, 3)
+ FIELD(VPLL_CTRL, CLKOUTDIV, 17, 1)
+ FIELD(VPLL_CTRL, DIV2, 16, 1)
+ FIELD(VPLL_CTRL, FBDIV, 8, 7)
+ FIELD(VPLL_CTRL, BYPASS, 3, 1)
+ FIELD(VPLL_CTRL, RESET, 0, 1)
+REG32(VPLL_CFG, 0x3c)
+ FIELD(VPLL_CFG, LOCK_DLY, 25, 7)
+ FIELD(VPLL_CFG, LOCK_CNT, 13, 10)
+ FIELD(VPLL_CFG, LFHF, 10, 2)
+ FIELD(VPLL_CFG, CP, 5, 4)
+ FIELD(VPLL_CFG, RES, 0, 4)
+REG32(VPLL_FRAC_CFG, 0x40)
+ FIELD(VPLL_FRAC_CFG, ENABLED, 31, 1)
+ FIELD(VPLL_FRAC_CFG, SEED, 22, 3)
+ FIELD(VPLL_FRAC_CFG, ALGRTHM, 19, 1)
+ FIELD(VPLL_FRAC_CFG, ORDER, 18, 1)
+ FIELD(VPLL_FRAC_CFG, DATA, 0, 16)
+REG32(PLL_STATUS, 0x44)
+ FIELD(PLL_STATUS, VPLL_STABLE, 5, 1)
+ FIELD(PLL_STATUS, DPLL_STABLE, 4, 1)
+ FIELD(PLL_STATUS, APLL_STABLE, 3, 1)
+ FIELD(PLL_STATUS, VPLL_LOCK, 2, 1)
+ FIELD(PLL_STATUS, DPLL_LOCK, 1, 1)
+ FIELD(PLL_STATUS, APLL_LOCK, 0, 1)
+REG32(APLL_TO_LPD_CTRL, 0x48)
+ FIELD(APLL_TO_LPD_CTRL, DIVISOR0, 8, 6)
+REG32(DPLL_TO_LPD_CTRL, 0x4c)
+ FIELD(DPLL_TO_LPD_CTRL, DIVISOR0, 8, 6)
+REG32(VPLL_TO_LPD_CTRL, 0x50)
+ FIELD(VPLL_TO_LPD_CTRL, DIVISOR0, 8, 6)
+REG32(CPU_A9_CTRL, 0x60)
+ FIELD(CPU_A9_CTRL, A9CLKSTOP, 26, 2)
+ FIELD(CPU_A9_CTRL, CLKACT_HALF, 25, 1)
+ FIELD(CPU_A9_CTRL, CLKACT_FULL, 24, 1)
+ FIELD(CPU_A9_CTRL, DIVISOR0, 8, 6)
+ FIELD(CPU_A9_CTRL, SRCSEL, 0, 3)
+REG32(DBG_TRACE_CTRL, 0x64)
+ FIELD(DBG_TRACE_CTRL, CLKACT, 24, 1)
+ FIELD(DBG_TRACE_CTRL, DIVISOR0, 8, 6)
+ FIELD(DBG_TRACE_CTRL, SRCSEL, 0, 3)
+REG32(DBG_FPD_CTRL, 0x68)
+ FIELD(DBG_FPD_CTRL, CLKACT, 24, 1)
+ FIELD(DBG_FPD_CTRL, DIVISOR0, 8, 6)
+ FIELD(DBG_FPD_CTRL, SRCSEL, 0, 3)
+REG32(DP_VIDEO_REF_CTRL, 0x70)
+ FIELD(DP_VIDEO_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DP_VIDEO_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DP_VIDEO_REF_CTRL, SRCSEL, 0, 3)
+REG32(DP_AUDIO_REF_CTRL, 0x74)
+ FIELD(DP_AUDIO_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DP_AUDIO_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DP_AUDIO_REF_CTRL, SRCSEL, 0, 3)
+REG32(DP_LINK_REF_CTRL, 0x78)
+ FIELD(DP_LINK_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DP_LINK_REF_CTRL, DIVISOR1, 16, 6)
+ FIELD(DP_LINK_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DP_LINK_REF_CTRL, SRCSEL, 0, 3)
+REG32(DP_STC_REF_CTRL, 0x7c)
+ FIELD(DP_STC_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DP_STC_REF_CTRL, DIVISOR1, 16, 6)
+ FIELD(DP_STC_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DP_STC_REF_CTRL, SRCSEL, 0, 3)
+REG32(DDR_CTRL, 0x80)
+ FIELD(DDR_CTRL, CLKACT, 24, 1)
+ FIELD(DDR_CTRL, DIVISOR0, 8, 6)
+ FIELD(DDR_CTRL, SRCSEL, 0, 3)
+REG32(GPU_REF_CTRL, 0x84)
+ FIELD(GPU_REF_CTRL, PP1_CLKACT, 26, 1)
+ FIELD(GPU_REF_CTRL, PP0_CLKACT, 25, 1)
+ FIELD(GPU_REF_CTRL, CLKACT, 24, 1)
+ FIELD(GPU_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(GPU_REF_CTRL, SRCSEL, 0, 3)
+REG32(AFI0_REF_CTRL, 0x88)
+ FIELD(AFI0_REF_CTRL, CLKACT, 24, 1)
+ FIELD(AFI0_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(AFI0_REF_CTRL, SRCSEL, 0, 3)
+REG32(AFI1_REF_CTRL, 0x8c)
+ FIELD(AFI1_REF_CTRL, CLKACT, 24, 1)
+ FIELD(AFI1_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(AFI1_REF_CTRL, SRCSEL, 0, 3)
+REG32(AFI2_REF_CTRL, 0x90)
+ FIELD(AFI2_REF_CTRL, CLKACT, 24, 1)
+ FIELD(AFI2_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(AFI2_REF_CTRL, SRCSEL, 0, 3)
+REG32(AFI3_REF_CTRL, 0x94)
+ FIELD(AFI3_REF_CTRL, CLKACT, 24, 1)
+ FIELD(AFI3_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(AFI3_REF_CTRL, SRCSEL, 0, 3)
+REG32(AFI4_REF_CTRL, 0x98)
+ FIELD(AFI4_REF_CTRL, CLKACT, 24, 1)
+ FIELD(AFI4_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(AFI4_REF_CTRL, SRCSEL, 0, 3)
+REG32(AFI5_REF_CTRL, 0x9c)
+ FIELD(AFI5_REF_CTRL, CLKACT, 24, 1)
+ FIELD(AFI5_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(AFI5_REF_CTRL, SRCSEL, 0, 3)
+REG32(SATA_REF_CTRL, 0xa0)
+ FIELD(SATA_REF_CTRL, CLKACT, 24, 1)
+ FIELD(SATA_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(SATA_REF_CTRL, SRCSEL, 0, 3)
+REG32(PCIE_REF_CTRL, 0xb4)
+ FIELD(PCIE_REF_CTRL, CLKACT, 24, 1)
+ FIELD(PCIE_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(PCIE_REF_CTRL, SRCSEL, 0, 3)
+REG32(GDMA_REF_CTRL, 0xb8)
+ FIELD(GDMA_REF_CTRL, CLKACT, 24, 1)
+ FIELD(GDMA_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(GDMA_REF_CTRL, SRCSEL, 0, 3)
+REG32(DPDMA_REF_CTRL, 0xbc)
+ FIELD(DPDMA_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DPDMA_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DPDMA_REF_CTRL, SRCSEL, 0, 3)
+REG32(TOPSW_MAIN_CTRL, 0xc0)
+ FIELD(TOPSW_MAIN_CTRL, CLKACT, 24, 1)
+ FIELD(TOPSW_MAIN_CTRL, DIVISOR0, 8, 6)
+ FIELD(TOPSW_MAIN_CTRL, SRCSEL, 0, 3)
+REG32(TOPSW_LSBUS_CTRL, 0xc4)
+ FIELD(TOPSW_LSBUS_CTRL, CLKACT, 24, 1)
+ FIELD(TOPSW_LSBUS_CTRL, DIVISOR0, 8, 6)
+ FIELD(TOPSW_LSBUS_CTRL, SRCSEL, 0, 3)
+REG32(GTGREF0_REF_CTRL, 0xc8)
+ FIELD(GTGREF0_REF_CTRL, CLKACT, 24, 1)
+ FIELD(GTGREF0_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(GTGREF0_REF_CTRL, SRCSEL, 0, 3)
+REG32(GTGREF1_REF_CTRL, 0xcc)
+ FIELD(GTGREF1_REF_CTRL, CLKACT, 24, 1)
+ FIELD(GTGREF1_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(GTGREF1_REF_CTRL, SRCSEL, 0, 3)
+REG32(DFT300_REF_CTRL, 0xd0)
+ FIELD(DFT300_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DFT300_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DFT300_REF_CTRL, SRCSEL, 0, 3)
+REG32(DFT270_REF_CTRL, 0xd4)
+ FIELD(DFT270_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DFT270_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DFT270_REF_CTRL, SRCSEL, 0, 3)
+REG32(DFT250_REF_CTRL, 0xd8)
+ FIELD(DFT250_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DFT250_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DFT250_REF_CTRL, SRCSEL, 0, 3)
+REG32(DFT125_REF_CTRL, 0xdc)
+ FIELD(DFT125_REF_CTRL, CLKACT, 24, 1)
+ FIELD(DFT125_REF_CTRL, DIVISOR0, 8, 6)
+ FIELD(DFT125_REF_CTRL, SRCSEL, 0, 3)
+
+REG32(RST_FPD_TOP, 0x100)
+ FIELD(RST_FPD_TOP, PCIE_BRDG_RESET, 18, 1)
+ FIELD(RST_FPD_TOP, PCIE_CTRL_RESET, 17, 1)
+ FIELD(RST_FPD_TOP, DP_RESET, 16, 1)
+ FIELD(RST_FPD_TOP, AFI_FM5_RESET, 12, 1)
+ FIELD(RST_FPD_TOP, AFI_FM4_RESET, 11, 1)
+ FIELD(RST_FPD_TOP, AFI_FM3_RESET, 10, 1)
+ FIELD(RST_FPD_TOP, AFI_FM2_RESET, 9, 1)
+ FIELD(RST_FPD_TOP, AFI_FM1_RESET, 8, 1)
+ FIELD(RST_FPD_TOP, AFI_FM0_RESET, 7, 1)
+ FIELD(RST_FPD_TOP, GDMA_RESET, 6, 1)
+ FIELD(RST_FPD_TOP, GPU_PP1_RESET, 5, 1)
+ FIELD(RST_FPD_TOP, GPU_PP0_RESET, 4, 1)
+ FIELD(RST_FPD_TOP, GPU_RESET, 3, 1)
+ FIELD(RST_FPD_TOP, GT_RESET, 2, 1)
+ FIELD(RST_FPD_TOP, SATA_RESET, 1, 1)
+REG32(RST_FPD_APU, 0x104)
+ FIELD(RST_FPD_APU, PERI_RESET, 13, 1)
+ FIELD(RST_FPD_APU, SCU_RESET, 12, 1)
+ FIELD(RST_FPD_APU, CPU1_AWDT_RESET, 9, 1)
+ FIELD(RST_FPD_APU, CPU0_AWDT_RESET, 8, 1)
+ FIELD(RST_FPD_APU, CPU1_CP14_RESET, 5, 1)
+ FIELD(RST_FPD_APU, CPU0_CP14_RESET, 4, 1)
+ FIELD(RST_FPD_APU, CPU3_A9_RESET, 3, 1)
+ FIELD(RST_FPD_APU, CPU2_A9_RESET, 2, 1)
+ FIELD(RST_FPD_APU, CPU1_A9_RESET, 1, 1)
+ FIELD(RST_FPD_APU, CPU0_A9_RESET, 0, 1)
+REG32(RST_DDR_SS, 0x108)
+ FIELD(RST_DDR_SS, DDR_RESET, 3, 1)
+ FIELD(RST_DDR_SS, APM_RESET, 2, 1)
+ FIELD(RST_DDR_SS, QOS_RESET, 1, 1)
+ FIELD(RST_DDR_SS, XMPU_RESET, 0, 1)
+
+#define R_MAX (R_RST_DDR_SS + 1)
+
+typedef struct CRF_APB {
+ SysBusDevice parent_obj;
+ MemoryRegion iomem;
+ qemu_irq irq_ir;
+
+ uint32_t regs[R_MAX];
+ RegisterInfo regs_info[R_MAX];
+
+ /* input clocks */
+ QEMUClock *pss_ref_clk;
+ QEMUClock *video_clk;
+ QEMUClock *pss_alt_ref_clk;
+ QEMUClock *aux_refclk;
+ QEMUClock *gt_crx_ref_clk;
+
+ /* internal clocks */
+ QEMUClock *apll_clk;
+ QEMUClock *dpll_clk;
+ QEMUClock *vpll_clk;
+
+ /* output clocks */
+ QEMUClock *acpu_clk;
+ QEMUClock *dbg_trace;
+ QEMUClock *dbg_fdp;
+ QEMUClock *dp_video_ref;
+ QEMUClock *dp_audio_ref;
+ QEMUClock *dp_stc_ref;
+ QEMUClock *ddr;
+ QEMUClock *gpu_ref;
+ QEMUClock *sata_ref;
+ QEMUClock *pcie_ref;
+ QEMUClock *gdma_ref;
+ QEMUClock *dpdma_ref;
+ QEMUClock *topsw_main;
+ QEMUClock *topsw_lsbus;
+ QEMUClock *dbg_tstmp;
+ QEMUClock *apll_to_lpd;
+ QEMUClock *dpll_to_lpd;
+ QEMUClock *vpll_to_lpd;
+} CRF_APB;
+
+static uint64_t apll_to_lpd_update_rate(void *opaque, uint64_t input_rate);
+static uint64_t dpll_to_lpd_update_rate(void *opaque, uint64_t input_rate);
+static uint64_t vpll_to_lpd_update_rate(void *opaque, uint64_t input_rate);
+static uint64_t apll_update_rate(void *opaque, uint64_t input_rate);
+static uint64_t dpll_update_rate(void *opaque, uint64_t input_rate);
+static uint64_t vpll_update_rate(void *opaque, uint64_t input_rate);
+static uint64_t dp_video_update_rate(void *opaque, uint64_t input_rate);
+
+/* Clock array */
+ClockInitElement crf_clock[] = {
+ /* input clocks */
+ DEVICE_CLOCK(CRF_APB, pss_ref_clk, NULL),
+ DEVICE_CLOCK(CRF_APB, video_clk, NULL),
+ DEVICE_CLOCK(CRF_APB, pss_alt_ref_clk, NULL),
+ DEVICE_CLOCK(CRF_APB, aux_refclk, NULL),
+ DEVICE_CLOCK(CRF_APB, gt_crx_ref_clk, NULL),
+ /* internal clocks */
+ DEVICE_CLOCK(CRF_APB, apll_clk, apll_update_rate),
+ DEVICE_CLOCK(CRF_APB, dpll_clk, dpll_update_rate),
+ DEVICE_CLOCK(CRF_APB, vpll_clk, vpll_update_rate),
+ /* output clocks */
+ DEVICE_CLOCK(CRF_APB, acpu_clk, NULL),
+ DEVICE_CLOCK(CRF_APB, dbg_trace, NULL),
+ DEVICE_CLOCK(CRF_APB, dbg_fdp, NULL),
+ DEVICE_CLOCK(CRF_APB, dp_video_ref, dp_video_update_rate),
+ DEVICE_CLOCK(CRF_APB, dp_audio_ref, NULL),
+ DEVICE_CLOCK(CRF_APB, dp_stc_ref, NULL),
+ DEVICE_CLOCK(CRF_APB, ddr, NULL),
+ DEVICE_CLOCK(CRF_APB, gpu_ref, NULL),
+ DEVICE_CLOCK(CRF_APB, sata_ref, NULL),
+ DEVICE_CLOCK(CRF_APB, pcie_ref, NULL),
+ DEVICE_CLOCK(CRF_APB, gdma_ref, NULL),
+ DEVICE_CLOCK(CRF_APB, dpdma_ref, NULL),
+ DEVICE_CLOCK(CRF_APB, topsw_main, NULL),
+ DEVICE_CLOCK(CRF_APB, topsw_lsbus, NULL),
+ DEVICE_CLOCK(CRF_APB, dbg_tstmp, NULL),
+ DEVICE_CLOCK(CRF_APB, apll_to_lpd, apll_to_lpd_update_rate),
+ DEVICE_CLOCK(CRF_APB, dpll_to_lpd, dpll_to_lpd_update_rate),
+ DEVICE_CLOCK(CRF_APB, vpll_to_lpd, vpll_to_lpd_update_rate),
+ DEVICE_CLOCK_END()
+};
+
+static const MemoryRegionOps crf_apb_ops = {
+ .read = register_read_memory,
+ .write = register_write_memory,
+ .endianness = DEVICE_LITTLE_ENDIAN,
+ .valid = {
+ .min_access_size = 4,
+ .max_access_size = 4,
+ },
+};
+
+static void ir_update_irq(CRF_APB *s)
+{
+ bool pending = s->regs[R_IR_STATUS] & ~s->regs[R_IR_MASK];
+ qemu_set_irq(s->irq_ir, pending);
+}
+
+static void ir_status_postw(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+ ir_update_irq(s);
+}
+
+static uint64_t ir_enable_prew(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+ uint32_t val = val64;
+
+ s->regs[R_IR_MASK] &= ~val;
+ ir_update_irq(s);
+ return 0;
+}
+
+static uint64_t ir_disable_prew(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+ uint32_t val = val64;
+
+ s->regs[R_IR_MASK] |= val;
+ ir_update_irq(s);
+ return 0;
+}
+
+enum clk_src {
+ VIDEO_CLK = 4,
+ PSS_ALT_REF_CLK = 5,
+ AUX_REF_CLK = 6,
+ GT_CRX_REF_CLK = 7,
+ PSS_REF_CLK = 0
+};
+
+static void apll_to_lpd_postw(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+
+ qemu_clk_refresh(s->apll_to_lpd);
+}
+
+static uint64_t apll_to_lpd_update_rate(void *opaque, uint64_t input_rate)
+{
+ CRF_APB *s = XILINX_CRF_APB(opaque);
+ uint32_t divisor = FIELD_EX32(s->regs[R_APLL_TO_LPD_CTRL],
+ APLL_TO_LPD_CTRL,
+ DIVISOR0);
+
+ if (!divisor) {
+ return 0.0f;
+ } else {
+ return input_rate / (float)divisor;
+ }
+}
+
+static void dpll_to_lpd_postw(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+
+ qemu_clk_refresh(s->dpll_to_lpd);
+}
+
+static uint64_t dpll_to_lpd_update_rate(void *opaque, uint64_t input_rate)
+{
+ CRF_APB *s = XILINX_CRF_APB(opaque);
+ uint32_t divisor = FIELD_EX32(s->regs[R_DPLL_TO_LPD_CTRL],
+ DPLL_TO_LPD_CTRL,
+ DIVISOR0);
+
+ if (!divisor) {
+ return 0.0f;
+ } else {
+ return input_rate / (float)divisor;
+ }
+}
+
+static void vpll_to_lpd_postw(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+
+ qemu_clk_refresh(s->vpll_to_lpd);
+}
+
+static uint64_t vpll_to_lpd_update_rate(void *opaque, uint64_t input_rate)
+{
+ CRF_APB *s = XILINX_CRF_APB(opaque);
+ uint32_t divisor = FIELD_EX32(s->regs[R_VPLL_TO_LPD_CTRL],
+ VPLL_TO_LPD_CTRL, DIVISOR0);
+
+ if (!divisor) {
+ return 0;
+ } else {
+ return input_rate / (float)divisor;
+ }
+}
+
+static void apll_ctrl_postw(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+ uint32_t source = FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, BYPASS)
+ ? FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, POST_SRC)
+ : FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, PRE_SRC);
+
+ /*
+ * We must ensure that only one clock is bound to the apll internal clock.
+ */
+ qemu_clk_unbind(s->pss_ref_clk, s->apll_clk);
+ qemu_clk_unbind(s->video_clk, s->apll_clk);
+ qemu_clk_unbind(s->pss_alt_ref_clk, s->apll_clk);
+ qemu_clk_unbind(s->aux_refclk, s->apll_clk);
+ qemu_clk_unbind(s->gt_crx_ref_clk, s->apll_clk);
+
+ switch (source) {
+ case VIDEO_CLK:
+ qemu_clk_bind(s->video_clk, s->apll_clk);
+ break;
+ case PSS_ALT_REF_CLK:
+ qemu_clk_bind(s->pss_alt_ref_clk, s->apll_clk);
+ break;
+ case AUX_REF_CLK:
+ qemu_clk_bind(s->aux_refclk, s->apll_clk);
+ break;
+ case GT_CRX_REF_CLK:
+ qemu_clk_bind(s->gt_crx_ref_clk, s->apll_clk);
+ break;
+ default:
+ qemu_clk_bind(s->pss_ref_clk, s->apll_clk);
+ break;
+ }
+}
+
+static void dpll_ctrl_postw(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+ uint32_t source = FIELD_EX32(s->regs[R_DPLL_CTRL], DPLL_CTRL, BYPASS)
+ ? FIELD_EX32(s->regs[R_DPLL_CTRL], DPLL_CTRL, POST_SRC)
+ : FIELD_EX32(s->regs[R_DPLL_CTRL], DPLL_CTRL, PRE_SRC);
+
+ /*
+ * We must ensure that only one clock is bound to the dpll internal clock.
+ */
+ qemu_clk_unbind(s->pss_ref_clk, s->dpll_clk);
+ qemu_clk_unbind(s->video_clk, s->dpll_clk);
+ qemu_clk_unbind(s->pss_alt_ref_clk, s->dpll_clk);
+ qemu_clk_unbind(s->aux_refclk, s->dpll_clk);
+ qemu_clk_unbind(s->gt_crx_ref_clk, s->dpll_clk);
+
+ switch (source) {
+ case VIDEO_CLK:
+ qemu_clk_bind(s->video_clk, s->dpll_clk);
+ break;
+ case PSS_ALT_REF_CLK:
+ qemu_clk_bind(s->pss_alt_ref_clk, s->dpll_clk);
+ break;
+ case AUX_REF_CLK:
+ qemu_clk_bind(s->aux_refclk, s->dpll_clk);
+ break;
+ case GT_CRX_REF_CLK:
+ qemu_clk_bind(s->gt_crx_ref_clk, s->dpll_clk);
+ break;
+ default:
+ qemu_clk_bind(s->pss_ref_clk, s->dpll_clk);
+ break;
+ }
+}
+
+static void vpll_ctrl_postw(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+ uint32_t source = FIELD_EX32(s->regs[R_VPLL_CTRL], VPLL_CTRL, BYPASS)
+ ? FIELD_EX32(s->regs[R_VPLL_CTRL], VPLL_CTRL, POST_SRC)
+ : FIELD_EX32(s->regs[R_VPLL_CTRL], VPLL_CTRL, PRE_SRC);
+
+ /*
+ * We must ensure that only one clock is bound to the vpll internal clock.
+ */
+ qemu_clk_unbind(s->pss_ref_clk, s->vpll_clk);
+ qemu_clk_unbind(s->video_clk, s->vpll_clk);
+ qemu_clk_unbind(s->pss_alt_ref_clk, s->vpll_clk);
+ qemu_clk_unbind(s->aux_refclk, s->vpll_clk);
+ qemu_clk_unbind(s->gt_crx_ref_clk, s->vpll_clk);
+
+ switch (source) {
+ case VIDEO_CLK:
+ qemu_clk_bind(s->video_clk, s->vpll_clk);
+ break;
+ case PSS_ALT_REF_CLK:
+ qemu_clk_bind(s->pss_alt_ref_clk, s->vpll_clk);
+ break;
+ case AUX_REF_CLK:
+ qemu_clk_bind(s->aux_refclk, s->vpll_clk);
+ break;
+ case GT_CRX_REF_CLK:
+ qemu_clk_bind(s->gt_crx_ref_clk, s->vpll_clk);
+ break;
+ default:
+ qemu_clk_bind(s->pss_ref_clk, s->vpll_clk);
+ break;
+ }
+}
+
+/*
+ * This happen when apll get updated.
+ * As we ensure that only one clk_pin can drive apll we can just do the
+ * computation from input_rate.
+ */
+static uint64_t apll_update_rate(void *opaque, uint64_t input_rate)
+{
+ CRF_APB *s = XILINX_CRF_APB(opaque);
+ bool bypass = FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, BYPASS);
+ bool reset = FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, RESET);
+ float div2 = FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, DIV2) ? 0.5f
+ : 1.0f;
+ float integer = (float)(FIELD_EX32(s->regs[R_APLL_CTRL],
+ APLL_CTRL, FBDIV));
+ float frac = FIELD_EX32(s->regs[R_APLL_FRAC_CFG], APLL_FRAC_CFG, ENABLED)
+ ? (float)(FIELD_EX32(s->regs[R_APLL_FRAC_CFG],
+ APLL_FRAC_CFG, DATA))
+ / 65536.0f
+ : 0.0f;
+
+ if (bypass) {
+ return input_rate;
+ } else {
+ if (reset) {
+ /*
+ * This is not supposed to happen user must ensure that BYPASS is
+ * set before the PLL are reset.
+ */
+ qemu_log_mask(LOG_GUEST_ERROR,
+ "APLL is reseted but not bypassed.");
+ return 0;
+ } else {
+ return input_rate * div2 * (integer + frac);
+ }
+ }
+}
+
+/*
+ * This happen when dpll get updated.
+ * As we ensure that only one clk_pin can drive dpll we can just do the
+ * computation from input_rate.
+ */
+static uint64_t dpll_update_rate(void *opaque, uint64_t input_rate)
+{
+ CRF_APB *s = XILINX_CRF_APB(opaque);
+ bool bypass = FIELD_EX32(s->regs[R_DPLL_CTRL], DPLL_CTRL, BYPASS);
+ bool reset = FIELD_EX32(s->regs[R_DPLL_CTRL], DPLL_CTRL, RESET);
+ float div2 = FIELD_EX32(s->regs[R_DPLL_CTRL], DPLL_CTRL, DIV2) ? 0.5f
+ : 1.0f;
+ float integer = (float)(FIELD_EX32(s->regs[R_DPLL_CTRL], DPLL_CTRL,
+ FBDIV));
+ float frac = FIELD_EX32(s->regs[R_DPLL_FRAC_CFG], DPLL_FRAC_CFG, ENABLED)
+ ? (float)(FIELD_EX32(s->regs[R_DPLL_FRAC_CFG],
+ DPLL_FRAC_CFG, DATA))
+ / 65536.0f
+ : 0.0f;
+
+ if (bypass) {
+ return input_rate;
+ } else {
+ if (reset) {
+ /*
+ * This is not supposed to happen user must ensure that BYPASS is
+ * set before the PLL are reset.
+ */
+ qemu_log_mask(LOG_GUEST_ERROR,
+ "DPLL is reseted but not bypassed.");
+ return 0;
+ } else {
+ return input_rate * div2 * (integer + frac);
+ }
+ }
+}
+
+/*
+ * This happen when vpll get updated.
+ * As we ensure that only one clk_pin can drive vpll we can just do the
+ * computation from input_rate.
+ */
+static uint64_t vpll_update_rate(void *opaque, uint64_t input_rate)
+{
+ CRF_APB *s = XILINX_CRF_APB(opaque);
+ bool bypass = FIELD_EX32(s->regs[R_VPLL_CTRL], VPLL_CTRL, BYPASS);
+ bool reset = FIELD_EX32(s->regs[R_VPLL_CTRL], VPLL_CTRL, RESET);
+ float div2 = FIELD_EX32(s->regs[R_VPLL_CTRL], VPLL_CTRL, DIV2) ? 0.5f
+ : 1.0f;
+ float integer = (float)(FIELD_EX32(s->regs[R_VPLL_CTRL], VPLL_CTRL,
+ FBDIV));
+ float frac = FIELD_EX32(s->regs[R_VPLL_FRAC_CFG], VPLL_FRAC_CFG, ENABLED)
+ ? (float)(FIELD_EX32(s->regs[R_VPLL_FRAC_CFG],
+ VPLL_FRAC_CFG, DATA))
+ / 65536.0f
+ : 0.0f;
+
+ if (bypass) {
+ return input_rate;
+ } else {
+ if (reset) {
+ /*
+ * This is not supposed to happen user must ensure that BYPASS is
+ * set before the PLL are reset.
+ */
+ qemu_log_mask(LOG_GUEST_ERROR,
+ "VPLL is reseted but not bypassed.");
+ return 0;
+ } else {
+ return input_rate * div2 * (integer + frac);
+ }
+ }
+}
+
+/*
+ * FIXME: Only DP video reference clock is modeled here, others are missing.
+ */
+static uint64_t dp_video_update_rate(void *opaque, uint64_t input_rate)
+{
+ CRF_APB *s = XILINX_CRF_APB(opaque);
+ bool clock_act = FIELD_EX32(s->regs[R_DP_VIDEO_REF_CTRL],
+ DP_VIDEO_REF_CTRL, CLKACT);
+ uint32_t divisor0 = FIELD_EX32(s->regs[R_DP_VIDEO_REF_CTRL],
+ DP_VIDEO_REF_CTRL, DIVISOR0);
+
+ if ((!divisor0) || (!clock_act)) {
+ return 0.0f;
+ } else {
+ return input_rate / (float)(divisor0);
+ }
+}
+
+static void dp_video_ref_ctrl_postw(RegisterInfo *reg, uint64_t val64)
+{
+ CRF_APB *s = XILINX_CRF_APB(reg->opaque);
+ uint32_t source = FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, BYPASS)
+ ? FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, POST_SRC)
+ : FIELD_EX32(s->regs[R_APLL_CTRL], APLL_CTRL, PRE_SRC);
+
+ /*
+ * We must ensure that only one clock is bound to the dp_video_ref
+ * internal clock, so the callback have always the right rate in it.
+ */
+ qemu_clk_unbind(s->vpll_clk, s->dp_video_ref);
+ qemu_clk_unbind(s->dpll_clk, s->dp_video_ref);
+
+ switch (source) {
+ case 0x00:
+ qemu_clk_bind(s->vpll_clk, s->dp_video_ref);
+ break;
+ case 0x02:
+ qemu_clk_bind(s->dpll_clk, s->dp_video_ref);
+ break;
+ default:
+ abort();
+ break;
+ }
+}
+
+static RegisterAccessInfo crf_apb_regs_info[] = {
+ { .name = "ERR_CTRL", .addr = A_ERR_CTRL,
+ },{ .name = "IR_STATUS", .addr = A_IR_STATUS,
+ .w1c = 0x1,
+ .post_write = ir_status_postw,
+ },{ .name = "IR_MASK", .addr = A_IR_MASK,
+ .reset = 0x1,
+ .ro = 0x1,
+ },{ .name = "IR_ENABLE", .addr = A_IR_ENABLE,
+ .pre_write = ir_enable_prew,
+ },{ .name = "IR_DISABLE", .addr = A_IR_DISABLE,
+ .pre_write = ir_disable_prew,
+ },{ .name = "CRF_ECO", .addr = A_CRF_ECO,
+ },{ .name = "APLL_CTRL", .addr = A_APLL_CTRL,
+ .reset = 0x2809,
+ .rsvd = 0xf88c80f6L,
+ .post_write = apll_ctrl_postw,
+ },{ .name = "APLL_CFG", .addr = A_APLL_CFG,
+ .rsvd = 0x1801210,
+ },{ .name = "APLL_FRAC_CFG", .addr = A_APLL_FRAC_CFG,
+ .rsvd = 0x7e330000,
+ },{ .name = "DPLL_CTRL", .addr = A_DPLL_CTRL,
+ .reset = 0x2809,
+ .rsvd = 0xf88c80f6L,
+ .post_write = dpll_ctrl_postw,
+ },{ .name = "DPLL_CFG", .addr = A_DPLL_CFG,
+ .rsvd = 0x1801210,
+ },{ .name = "DPLL_FRAC_CFG", .addr = A_DPLL_FRAC_CFG,
+ .rsvd = 0x7e330000,
+ },{ .name = "VPLL_CTRL", .addr = A_VPLL_CTRL,
+ .reset = 0x2809,
+ .rsvd = 0xf88c80f6L,
+ .post_write = vpll_ctrl_postw,
+ },{ .name = "VPLL_CFG", .addr = A_VPLL_CFG,
+ .rsvd = 0x1801210,
+ },{ .name = "VPLL_FRAC_CFG", .addr = A_VPLL_FRAC_CFG,
+ .rsvd = 0x7e330000,
+ },{ .name = "PLL_STATUS", .addr = A_PLL_STATUS,
+ .reset = 0x3f,
+ .rsvd = 0xc0,
+ .ro = 0x3f,
+ },{ .name = "APLL_TO_LPD_CTRL", .addr = A_APLL_TO_LPD_CTRL,
+ .reset = 0x400,
+ .rsvd = 0xc0ff,
+ .post_write = apll_to_lpd_postw,
+ },{ .name = "DPLL_TO_LPD_CTRL", .addr = A_DPLL_TO_LPD_CTRL,
+ .reset = 0x400,
+ .rsvd = 0xc0ff,
+ .post_write = dpll_to_lpd_postw,
+ },{ .name = "VPLL_TO_LPD_CTRL", .addr = A_VPLL_TO_LPD_CTRL,
+ .reset = 0x400,
+ .rsvd = 0xc0ff,
+ .post_write = vpll_to_lpd_postw,
+ },{ .name = "CPU_A9_CTRL", .addr = A_CPU_A9_CTRL,
+ .reset = 0xf000400,
+ .rsvd = 0xf0ffc0f8L,
+ },{ .name = "DBG_TRACE_CTRL", .addr = A_DBG_TRACE_CTRL,
+ .reset = 0x2500,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "DBG_FPD_CTRL", .addr = A_DBG_FPD_CTRL,
+ .reset = 0x1002500,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "DP_VIDEO_REF_CTRL", .addr = A_DP_VIDEO_REF_CTRL,
+ .reset = 0x1002300,
+ .rsvd = 0xfeffc0f8L,
+ .post_write = dp_video_ref_ctrl_postw,
+ },{ .name = "DP_AUDIO_REF_CTRL", .addr = A_DP_AUDIO_REF_CTRL,
+ .reset = 0x1002300,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "DP_LINK_REF_CTRL", .addr = A_DP_LINK_REF_CTRL,
+ .reset = 0x1203200,
+ .rsvd = 0xfec0c0f8L,
+ },{ .name = "DP_STC_REF_CTRL", .addr = A_DP_STC_REF_CTRL,
+ .reset = 0x1203200,
+ .rsvd = 0xfec0c0f8L,
+ },{ .name = "DDR_CTRL", .addr = A_DDR_CTRL,
+ .reset = 0x1000500,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "GPU_REF_CTRL", .addr = A_GPU_REF_CTRL,
+ .reset = 0x1500,
+ .rsvd = 0xf8ffc0f8L,
+ },{ .name = "AFI0_REF_CTRL", .addr = A_AFI0_REF_CTRL,
+ .reset = 0x600,
+ .rsvd = 0x7effc0f8,
+ },{ .name = "AFI1_REF_CTRL", .addr = A_AFI1_REF_CTRL,
+ .reset = 0x600,
+ .rsvd = 0x7effc0f8,
+ },{ .name = "AFI2_REF_CTRL", .addr = A_AFI2_REF_CTRL,
+ .reset = 0x600,
+ .rsvd = 0x7effc0f8,
+ },{ .name = "AFI3_REF_CTRL", .addr = A_AFI3_REF_CTRL,
+ .reset = 0x600,
+ .rsvd = 0x7effc0f8,
+ },{ .name = "AFI4_REF_CTRL", .addr = A_AFI4_REF_CTRL,
+ .reset = 0x600,
+ .rsvd = 0x7effc0f8,
+ },{ .name = "AFI5_REF_CTRL", .addr = A_AFI5_REF_CTRL,
+ .reset = 0x600,
+ .rsvd = 0x7effc0f8,
+ },{ .name = "SATA_REF_CTRL", .addr = A_SATA_REF_CTRL,
+ .reset = 0x1001600,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "PCIE_REF_CTRL", .addr = A_PCIE_REF_CTRL,
+ .reset = 0x1500,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "GDMA_REF_CTRL", .addr = A_GDMA_REF_CTRL,
+ .reset = 0x1000500,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "DPDMA_REF_CTRL", .addr = A_DPDMA_REF_CTRL,
+ .reset = 0x1000500,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "TOPSW_MAIN_CTRL", .addr = A_TOPSW_MAIN_CTRL,
+ .reset = 0x1000500,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "TOPSW_LSBUS_CTRL", .addr = A_TOPSW_LSBUS_CTRL,
+ .reset = 0x1000800,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "GTGREF0_REF_CTRL", .addr = A_GTGREF0_REF_CTRL,
+ .reset = 0x800,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "GTGREF1_REF_CTRL", .addr = A_GTGREF1_REF_CTRL,
+ .reset = 0x800,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "DFT300_REF_CTRL", .addr = A_DFT300_REF_CTRL,
+ .reset = 0x800,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "DFT270_REF_CTRL", .addr = A_DFT270_REF_CTRL,
+ .reset = 0x800,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "DFT250_REF_CTRL", .addr = A_DFT250_REF_CTRL,
+ .reset = 0x800,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "DFT125_REF_CTRL", .addr = A_DFT125_REF_CTRL,
+ .reset = 0x800,
+ .rsvd = 0xfeffc0f8L,
+ },{ .name = "RST_FPD_TOP", .addr = A_RST_FPD_TOP,
+ .reset = 0x71ffe,
+ .rsvd = 0xf8e001,
+ },{ .name = "RST_FPD_APU", .addr = A_RST_FPD_APU,
+ .reset = 0x334f,
+ .rsvd = 0xffcccc,
+ },{ .name = "RST_DDR_SS", .addr = A_RST_DDR_SS,
+ .reset = 0xf,
+ .rsvd = 0xf0,
+ }
+};
+
+static void crf_apb_reset(DeviceState *dev)
+{
+ CRF_APB *s = XILINX_CRF_APB(dev);
+ unsigned int i;
+
+ for (i = 0; i < ARRAY_SIZE(s->regs_info); ++i) {
+ register_reset(&s->regs_info[i]);
+ }
+
+ ir_update_irq(s);
+
+ /*
+ * During reset, the clock selection registers bound the clock like this.
+ */
+ qemu_clk_bind(s->pss_ref_clk, s->apll_clk);
+ qemu_clk_bind(s->pss_ref_clk, s->dpll_clk);
+ qemu_clk_bind(s->pss_ref_clk, s->vpll_clk);
+ qemu_clk_bind(s->vpll_clk, s->dp_video_ref);
+}
+
+static void crf_apb_realize(DeviceState *d, Error **errp)
+{
+ CRF_APB *s = XILINX_CRF_APB(d);
+
+ qemu_clk_bind(s->apll_clk, s->apll_to_lpd);
+ qemu_clk_bind(s->dpll_clk, s->dpll_to_lpd);
+ qemu_clk_bind(s->vpll_clk, s->vpll_to_lpd);
+
+ crf_apb_reset(d);
+}
+
+static void crf_apb_init(Object *obj)
+{
+ CRF_APB *s = XILINX_CRF_APB(obj);
+ SysBusDevice *sbd = SYS_BUS_DEVICE(obj);
+ RegisterInfoArray *reg_array;
+
+ memory_region_init(&s->iomem, obj, TYPE_XILINX_CRF_APB, R_MAX * 4);
+ reg_array = register_init_block32(DEVICE(obj), crf_apb_regs_info,
+ ARRAY_SIZE(crf_apb_regs_info),
+ s->regs_info, s->regs,
+ &crf_apb_ops,
+ XILINX_CRF_APB_ERR_DEBUG,
+ R_RST_DDR_SS);
+ memory_region_add_subregion(&s->iomem,
+ A_ERR_CTRL,
+ ®_array->mem);
+
+ sysbus_init_mmio(sbd, &s->iomem);
+ sysbus_init_irq(sbd, &s->irq_ir);
+
+ qemu_clk_init_device(obj, crf_clock);
+}
+
+static const VMStateDescription vmstate_crf_apb = {
+ .name = TYPE_XILINX_CRF_APB,
+ .version_id = 1,
+ .minimum_version_id = 1,
+ .minimum_version_id_old = 1,
+ .fields = (VMStateField[]) {
+ VMSTATE_UINT32_ARRAY(regs, CRF_APB, R_MAX),
+ VMSTATE_END_OF_LIST(),
+ }
+};
+
+static void crf_apb_class_init(ObjectClass *klass, void *data)
+{
+ DeviceClass *dc = DEVICE_CLASS(klass);
+
+ dc->reset = crf_apb_reset;
+ dc->vmsd = &vmstate_crf_apb;
+ dc->realize = crf_apb_realize;
+}
+
+static const TypeInfo crf_apb_info = {
+ .name = TYPE_XILINX_CRF_APB,
+ .parent = TYPE_SYS_BUS_DEVICE,
+ .instance_size = sizeof(CRF_APB),
+ .class_init = crf_apb_class_init,
+ .instance_init = crf_apb_init,
+};
+
+static void crf_apb_register_types(void)
+{
+ type_register_static(&crf_apb_info);
+}
+
+type_init(crf_apb_register_types)
From: KONRAD Frederic <fred.konrad@greensocs.com> This introduce Xilinx zynqmp-crf. It is extracted from the qemu xilinx tree (02d2f0203dd489ed30d9c8d90c14a52c57332b25) and is used as an example for the clock framework. --- hw/misc/Makefile.objs | 1 + hw/misc/xilinx_zynqmp_crf.c | 968 ++++++++++++++++++++++++++++++++++++++++++++ 2 files changed, 969 insertions(+) create mode 100644 hw/misc/xilinx_zynqmp_crf.c