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authorMike Jones <mjjones@us.ibm.com>2012-06-08 08:53:00 -0500
committerA. Patrick Williams III <iawillia@us.ibm.com>2012-06-11 11:27:14 -0500
commit3a295ce2d7f731a0c8ce226871d4949ceaefddbb (patch)
treeed0800e8b32763750465db56e6ff2be6c7fc8dbd /src
parentcf254661375fe14c9cbca03d1dd23400737d6950 (diff)
downloadtalos-hostboot-3a295ce2d7f731a0c8ce226871d4949ceaefddbb.tar.gz
talos-hostboot-3a295ce2d7f731a0c8ce226871d4949ceaefddbb.zip
Integrate updated mss_ddr_phy_reset.C
Mark Fredrickson requested in 05/31/2012 that we pick up this modified HWP (v1.7) We already integrated an earlier version (v1.4). The code is tweaked a little and the error handling is vastly improved. Change-Id: I3ce02b948a06bdd7c0765f8f9fd7523205048585 Reviewed-on: http://gfw160.austin.ibm.com:8080/gerrit/1180 Tested-by: Jenkins Server Reviewed-by: A. Patrick Williams III <iawillia@us.ibm.com>
Diffstat (limited to 'src')
-rw-r--r--src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.C1000
-rw-r--r--src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.H57
2 files changed, 637 insertions, 420 deletions
diff --git a/src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.C b/src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.C
index b3aee3a57..57d7a439c 100644
--- a/src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.C
+++ b/src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.C
@@ -1,26 +1,27 @@
-// IBM_PROLOG_BEGIN_TAG
-// This is an automatically generated prolog.
-//
-// $Source: src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.C $
-//
-// IBM CONFIDENTIAL
-//
-// COPYRIGHT International Business Machines Corp. 2012
-//
-// p1
-//
-// Object Code Only (OCO) source materials
-// Licensed Internal Code Source Materials
-// IBM HostBoot Licensed Internal Code
-//
-// The source code for this program is not published or other-
-// wise divested of its trade secrets, irrespective of what has
-// been deposited with the U.S. Copyright Office.
-//
-// Origin: 30
-//
-// IBM_PROLOG_END
-// $Id: mss_ddr_phy_reset.C,v 1.4 2012/02/22 18:36:36 mfred Exp $
+/* IBM_PROLOG_BEGIN_TAG
+ * This is an automatically generated prolog.
+ *
+ * $Source: src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.C $
+ *
+ * IBM CONFIDENTIAL
+ *
+ * COPYRIGHT International Business Machines Corp. 2012
+ *
+ * p1
+ *
+ * Object Code Only (OCO) source materials
+ * Licensed Internal Code Source Materials
+ * IBM HostBoot Licensed Internal Code
+ *
+ * The source code for this program is not published or other-
+ * wise divested of its trade secrets, irrespective of what has
+ * been deposited with the U.S. Copyright Office.
+ *
+ * Origin: 30
+ *
+ * IBM_PROLOG_END_TAG
+ */
+// $Id: mss_ddr_phy_reset.C,v 1.7 2012/05/31 18:27:54 mfred Exp $
// $Source: /afs/awd/projects/eclipz/KnowledgeBase/.cvsroot/eclipz/chips/centaur/working/procedures/ipl/fapi/mss_ddr_phy_reset.C,v $
//------------------------------------------------------------------------------
// *! (C) Copyright International Business Machines Corp. 2011
@@ -43,21 +44,19 @@
#include <fapi.H>
#include <cen_scom_addresses.H>
+#include <mss_ddr_phy_reset.H>
+
+// Constants
+const uint64_t DELAY_100NS = 100; // general purpose 100 ns delay for HW mode (2000 sim cycles if simclk = 20ghz)
+const uint64_t DELAY_1US = 1000; // general purpose 1 usec delay for HW mode (20000 sim cycles if simclk = 20ghz)
+const uint64_t DELAY_100US = 100000; // general purpose 100 usec delay for HW mode (2000000 sim cycles if simclk = 20ghz)
+const uint64_t DELAY_2000SIMCYCLES = 2000; // general purpose 2000 sim cycle delay for sim mode (100 ns if simclk = 20Ghz)
+const uint64_t DELAY_20000SIMCYCLES = 20000; // general purpose 20000 sim cycle delay for sim mode (1 usec if simclk = 20Ghz)
+const uint64_t DELAY_2000000SIMCYCLES = 2000000; // general purpose 2000000 sim cycle delay for sim mode (100 usec if simclk = 20Ghz)
-uint64_t delay_1ns = 1; // general purpose 1 ns delay for HW mode (20 sim cycles if simclk - 20ghz)
-uint64_t delay_10ns = 10; // general purpose 10 ns delay for HW mode (200 sim cycles if simclk - 20ghz)
-uint64_t delay_100ns = 100; // general purpose 100 ns delay for HW mode (2000 sim cycles if simclk - 20ghz)
-uint64_t delay_1us = 1000; // general purpose 1 usec delay for HW mode (20000 sim cycles if simclk - 20ghz)
-uint64_t delay_10us = 10000; // general purpose 10 usec delay for HW mode (200000 sim cycles if simclk - 20ghz)
-uint64_t delay_100us = 100000; // general purpose 100 usec delay for HW mode (2000000 sim cycles if simclk - 20ghz)
-uint64_t delay_1ms = 1000000; // general purpose 1 ms delay for HW mode (20000000 sim cycles if simclk - 20ghz)
-uint64_t delay_20simcycles = 20; // general purpose 20 sim cycle delay for sim mode (1 ns if simclk = 20Ghz)
-uint64_t delay_200simcycles = 200; // general purpose 200 sim cycle delay for sim mode (10 ns if simclk = 20Ghz)
-uint64_t delay_2000simcycles = 2000; // general purpose 2000 sim cycle delay for sim mode (100 ns if simclk = 20Ghz)
-uint64_t delay_20000simcycles = 20000; // general purpose 20000 sim cycle delay for sim mode (1 usec if simclk = 20Ghz)
-uint64_t delay_200000simcycles = 200000; // general purpose 200000 sim cycle delay for sim mode (10 usec if simclk = 20Ghz)
-uint64_t delay_2000000simcycles = 2000000; // general purpose 2000000 sim cycle delay for sim mode (100 usec if simclk = 20Ghz)
-uint64_t delay_20000000simcycles = 20000000; // general purpose 20000000 sim cycle delay for sim mode (1 ms if simclk = 20Ghz)
+const uint16_t DP18_PLL_EXP_LOCK_STATUS = 0xF800; // DP18 PLL lock status that is expected at the conclusion of this procedure.
+const uint16_t AD32S_PLL_EXP_LOCK_STATUS = 0xC000; // AD32S PLL lock status that is expected at the conclusion of this procedure.
+const uint16_t MAX_POLL_LOOPS = 10; // Loop 10 times during PLL lock polling
extern "C" {
@@ -65,362 +64,568 @@ extern "C" {
using namespace fapi;
-//ReturnCode mss_ddr_phy_reset(Target i_target, bool i_parm1, uint32_t i_parm2) {
-ReturnCode mss_ddr_phy_reset(Target i_target) {
- ReturnCode l_rc;
- ecmdDataBufferBase data;
- ecmdDataBufferBase mask;
- ecmdDataBufferBase i_data, j_data, k_data, l_data;
- i_data.setBitLength(64);
- j_data.setBitLength(64);
- k_data.setBitLength(64);
- l_data.setBitLength(64);
- uint32_t poll_count = 0;
- uint32_t done_polling = 0;
- uint8_t dram_gen = 0;
-
- FAPI_INF("");
- FAPI_INF("********* *********************** *********");
- FAPI_INF("********* mss_ddr_phy_reset start *********");
- FAPI_INF("********* *********************** *********");
-
- //FAPI_INF("mss_ddr_phy_reset::My parms are:");
- //FAPI_INF(" ::i_parm1 = %d", i_parm1);
- //FAPI_INF(" ::i_parm2 = %d", i_parm2);
-
- //l_rc = fapiGetScom(i_target, 0x000F0012, data );
- //if (l_rc) {
- // FAPI_ERR("fapiGetScom() failed."); return l_rc;
- //}
- //data.flushTo1();
- //data.clearBit(0);
- //data.clearBit(31);
- //l_rc = fapiPutScom(i_target, 0x000F0012, data );
- //if (l_rc) {
- // FAPI_ERR("fapiGetScom() failed."); return l_rc;
- //}
-
- //
- // Here are the specific instructions from section 14.7.2 of the Centaur Chip Specification:
- //
- // Run cen_ddr_phy_reset.C prepares the DDR PLLs. These PLLs were previously configured via scan init, but have
- // been held in reset. At this point the PLL GP bit is deasserted to take the PLLs out of reset.
- // Note - this is done in the cen_startclocks.C procedure.
- //
- // The cen_ddr_phy_reset.C now resets the DDR PHY logic. This process will NOT destroy any configuration values
- // previously loaded via the init file. The intent is for the initialized phase rotator configuration to remain valid after the
- // soft reset completes. If this assumption fails to hold true, it will require replacing this step with a PHY hard reset,
- // and then using inband configuration writes to restore all the DDR Configuration Registers.
- //
- // The following steps must be performed as part of the PHY reset procedure.
-
-
-
- //
- // 1. Drive all control signals to the PHY to their inactive state, idle state, or inactive value.
- // (Note: The chip should already be in this state.)
- FAPI_DBG("Step 1: All control signals to the PHYs should already be set to their inactive state, idle state, or inactive values.\n");
-
-
-
- //
- // 2. For DD0: Assert dfi_reset_all (GP4 bit 5 = "1") for at least 32 memory clock cycles. This signal DOES
- // erradicate all DDR configuration register initialization, thereby requiring the DDR registers to be reprogrammed
- // via SCOM after the PHY reset sequence completes.
- // For DD1: Set mcbist_ddr_dfi_reset_recover ="1" (CCS_MODEQ(25) SCOM Addr: 0x030106A7 & 0x03010EA7)
- // for at least 32 memory clock cycles. This signal does NOT reset the configuration registers
- // within the PHY.
-
- FAPI_DBG("Step 2: MBA CCS_MODEQ(25), Setting mcbist_ddr_dfi_reset_recover = 1 for DDR PHY soft reset.\n");
- l_rc = fapiGetScom( i_target, MEM_MBA01_CCS_MODEQ_0x030106A7, data); if ( l_rc ) return l_rc;
- data.setBit(25);
- l_rc = fapiPutScom( i_target, MEM_MBA01_CCS_MODEQ_0x030106A7, data); if ( l_rc ) return l_rc;
-
- fapiDelay(delay_100ns, delay_2000simcycles); // wait 2000 simcycles (in sim mode) OR 100 nS (in hw mode)
-
-
-
- //
- // 3. For DD0: Deassert dfi_reset_all (GP4 bit 5 = "0")
- // For DD1: Deassert mcbist_ddr_dfi_reset_recover = "0" (CCS_MODEQ(25) SCOM Addr: 0x030106A7 0x03010EA7)
- FAPI_DBG("Step 3: MBA CCS_MODEQ(25), Setting mcbist_ddr_dfi_reset_recover = 0 to release soft reset.\n");
- l_rc = fapiGetScom( i_target, MEM_MBA01_CCS_MODEQ_0x030106A7, data); if ( l_rc ) return l_rc;
- data.clearBit(25);
- l_rc = fapiPutScom( i_target, MEM_MBA01_CCS_MODEQ_0x030106A7, data); if ( l_rc ) return l_rc;
-
-
-
- //
- // 4. Write 0x0008 to PC IO PVT N/P FET driver control registers to assert ZCTL reset
- // and reset the internal impedance controller.(SCOM Addr: 0x8000C0140301143F, 0x8000C0140301183F, 0x8001C0140301143F, 0x8001C0140301183F)
- FAPI_DBG("Step 4: Write 0x0008 to PC IO PVT N/P FET driver control registers to assert ZCTL reset.\n");
- i_data.setHalfWord(3, 0x0008);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0_0x8000C0140301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1_0x8001C0140301143F, i_data); if ( l_rc ) return l_rc;
-
-
-
- //
- // 5. Write 0x0000 to PC IO PVT N/P FET driver control registers to deassert ZCTL reset
- // (SCOM Addr: 0x8000C0140301143F, 0x8000C0140301183F, 0x8001C0140301143F, 0x8001C0140301183F)
- FAPI_DBG("Step 5: Write 0x0000 to PC IO PVT N/P FET driver control registers to deassert ZCTL reset.\n");
- i_data.setHalfWord(3, 0x0000);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0_0x8000C0140301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1_0x8001C0140301143F, i_data); if ( l_rc ) return l_rc;
-
-
-
- //
- // 6. For DD0: 32 memory clock cycles after asserting dfi_reset_recover, program the following registers
- // to all zeros for DDR3. Set to 0x1202 for DDR4
- // -- Set PC Configuration 0 to 0x0000 for DDR3 or 0x1202 for DDR4
- // (SCOM Addr: 0x8000C00C0301143F, 0x8000C00C0301183F, 0x8001C00C0301143F, 0x8001C00C0301183F)
- // -- Set ADR PLL/VREG Configuration 0 to 0x0000 (SCOM Addr: 0x800080300301143F, 0x800084300301143F, 0x800180300301143F, 0x800184300301143F,
- // 0x800080300301183F, 0x800084300301183F, 0x800180300301183F, 0x800184300301183F)
- // -- Set ADR PLL/VREG Configuration 1 to 0x0040 (SCOM Addr: 0x800080310301143F, 0x800084310301143F, 0x800180310301143F, 0x800184310301143F,
- // 0x800080310301183F, 0x800084310301183F, 0x800180310301183F, 0x800184310301183F)
- // -- Set DP18 PLL/VREG Configuration 0 to 0x0000 (SCOM Addr: 0x800000760301143F, 0x800004760301143F, 0x800008760301143F, 0x80000C760301143F, 0x800010760301143F,
- // 0x800000760301183F, 0x800004760301183F, 0x800008760301183F, 0x80000C760301183F, 0x800010760301183F,
- // 0x800100760301143F, 0x800104760301143F, 0x800108760301143F, 0x80010C760301143F, 0x800110760301143F,
- // 0x800100760301183F, 0x800104760301183F, 0x800108760301183F, 0x80010C760301183F, 0x800110760301183F)
- // -- Set DP18 PLL/VREG Configuration 1 to 0x0040 (SCOM Addr: 0x800000770301143F, 0x800004770301143F, 0x800008770301143F, 0x80000C770301143F, 0x800010770301143F,
- // 0x800000770301183F, 0x800004770301183F, 0x800008770301183F, 0x80000C770301183F, 0x800010770301183F,
- // 0x800100770301143F, 0x800104770301143F, 0x800108770301143F, 0x80010C770301143F, 0x800110770301143F,
- // 0x800100770301183F, 0x800104770301183F, 0x800108770301183F, 0x80010C770301183F, 0x800110770301183F)
- // For DD1; This step might be able to be skipped if the PLL registers will be scan initialized to the proper values.
-
- // Step 6a: selects either 0x0000 (for DDR3) or 0x1202 (for DDR4) based on the dram_generation attribute
- l_rc = FAPI_ATTR_GET( ATTR_EFF_DRAM_GEN, &i_target, dram_gen); if ( l_rc ) return l_rc;
- if (dram_gen == ENUM_ATTR_EFF_DRAM_GEN_DDR4)
- {
- FAPI_DBG("Step 6a: Set PC Configuration 0 to 0x1202 for DDR4.\n");
- i_data.setHalfWord(3, 0x1202);
- }
- else
- {
- FAPI_DBG("Step 6a: Set PC Configuration 0 to 0x0000 for DDR3.\n");
- i_data.setHalfWord(3, 0x0000);
- }
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_CONFIG0_P0_0x8000C00C0301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_CONFIG0_P1_0x8001C00C0301143F, i_data); if ( l_rc ) return l_rc;
-
- FAPI_DBG("Step 6b: Set ADR PLL/VREG Configuration 0 to 0x0000.\n");
- i_data.setHalfWord(3, 0x0000);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_PLL_VREG_CONFIG_0_P0_ADR32S0_0x800080300301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_PLL_VREG_CONFIG_0_P1_ADR32S0_0x800180300301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_PLL_VREG_CONFIG_0_P0_ADR32S1_0x800084300301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_PLL_VREG_CONFIG_0_P1_ADR32S1_0x800184300301143F, i_data); if ( l_rc ) return l_rc;
-
- FAPI_DBG("Step 6c: Set ADR PLL/VREG Configuration 1 to 0x0040.\n");
- i_data.setHalfWord(3, 0x0040);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_PLL_VREG_CONFIG_1_P0_ADR32S0_0x800080310301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_PLL_VREG_CONFIG_1_P1_ADR32S0_0x800180310301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_PLL_VREG_CONFIG_1_P0_ADR32S1_0x800084310301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_PLL_VREG_CONFIG_1_P1_ADR32S1_0x800184310301143F, i_data); if ( l_rc ) return l_rc;
-
- FAPI_DBG("Step 6d: Set DP18 PLL/VREG Configuration 0 to 0x0000.\n");
- i_data.setHalfWord(3, 0x0000);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P0_0_0x800000760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P1_0_0x800100760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P0_1_0x800004760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P1_1_0x800104760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P0_2_0x800008760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P1_2_0x800108760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P0_3_0x80000C760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P1_3_0x80010C760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P0_4_0x800010760301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG0_P1_4_0x800110760301143F, i_data); if ( l_rc ) return l_rc;
-
- FAPI_DBG("Step 6e: Set DP18 PLL/VREG Configuration 1 to 0x0040.\n");
- i_data.setHalfWord(3, 0x0040);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P0_0_0x800000770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P1_0_0x800100770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P0_1_0x800004770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P1_1_0x800104770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P0_2_0x800008770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P1_2_0x800108770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P0_3_0x80000C770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P1_3_0x80010C770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P0_4_0x800010770301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_PLL_CONFIG1_P1_4_0x800110770301143F, i_data); if ( l_rc ) return l_rc;
-
-
-
- //
- // 7. Wait at least 1 microsecond. This is the required PLL reset time. (This may be skipped for DD1)
- FAPI_DBG("Step 7: PLL reset delay is not required for Centaur DD1.\n");
- // This delay should not be required for DD1
- // fapiDelay(delay_1us, delay_20000simcycles); // wait 20000 simcycles (in sim mode) OR 1 usec (in hw mode)
-
-
-
- //
- // 8. Write 0x4000 into the PC Resets Registers. This deasserts the PLL_RESET and leaves the SYSCLK_RESET bit active
- // (SCOM Addr: 0x8000C00E0301143F, 0x8001C00E0301143F, 0x8000C00E0301183F, 0x8001C00E0301183F)
- FAPI_DBG("Step 8: Write 0x4000 into the PC Resets Registers. This deasserts the PLL_RESET and leaves the SYSCLK_RESET bit active.\n");
- i_data.setHalfWord(3, 0x4000);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_RESETS_P0_0x8000C00E0301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_RESETS_P1_0x8001C00E0301143F, i_data); if ( l_rc ) return l_rc;
-
-
-
- //
- // 9. Wait at least 1 millisecond to allow the PLLs to lock. Otherwise, poll the PC DP18 PLL Lock Status
- // and the PC AD32S PLL Lock Status to determine if all PLLs have locked.
- // PC DP18 PLL Lock Status should be 0xF800: (SCOM Addr: 0x8000C0000301143F, 0x8001C0000301143F, 0x8000C0000301183F, 0x8001C0000301183F)
- // PC AD32S PLL Lock Status should be 0xC000: (SCOM Addr: 0x8000C0010301143F, 0x8001C0010301143F, 0x8000C0010301183F, 0x8001C0010301183F)
- FAPI_DBG("Step 9: Poll until DP18 and AD32S PLLs have locked....\n");
- // fapiDelay(delay_1ms, delay_20000000simcycles); // wait 20000000 simcycles (in sim mode) OR 1 mS (in hw mode)
+fapi::ReturnCode mss_ddr_phy_reset(const fapi::Target & i_target)
+{
+ // Target is centaur.mba
+
+ fapi::ReturnCode rc;
+ uint32_t rc_ecmd = 0;
+ uint32_t poll_count = 0;
+ uint32_t done_polling = 0;
+ ecmdDataBufferBase i_data, j_data, k_data, l_data;
+
+
+ FAPI_INF("********* mss_ddr_phy_reset start *********");
do
- {
- fapiDelay(delay_1us, delay_20000simcycles); // wait 20000 simcycles (in sim mode) OR 1 usec (in hw mode)
- done_polling = 1;
- l_rc = fapiGetScom( i_target, DPHY01_DDRPHY_PC_DP18_PLL_LOCK_STATUS_P0_0x8000C0000301143F, i_data); if ( l_rc ) return l_rc;
- if ( i_data.getHalfWord(3) != 0xF800 ) done_polling = 0;
- l_rc = fapiGetScom( i_target, DPHY01_DDRPHY_PC_DP18_PLL_LOCK_STATUS_P1_0x8001C0000301143F, j_data); if ( l_rc ) return l_rc;
- if ( j_data.getHalfWord(3) != 0xF800 ) done_polling = 0;
- l_rc = fapiGetScom( i_target, DPHY01_DDRPHY_PC_AD32S_PLL_LOCK_STATUS_P0_0x8000C0010301143F, k_data); if ( l_rc ) return l_rc;
- if ( k_data.getHalfWord(3) != 0xC000 ) done_polling = 0;
- l_rc = fapiGetScom( i_target, DPHY01_DDRPHY_PC_AD32S_PLL_LOCK_STATUS_P1_0x8001C0010301143F, l_data); if ( l_rc ) return l_rc;
- if ( l_data.getHalfWord(3) != 0xC000 ) done_polling = 0;
-
-
-// FAPI_INF("Polling Loop = %i", poll_count);
-// if ( i_data.getHalfWord(3) != 0xF800 ) FAPI_ERR("DP18 0x0C000 PLL failed to lock! Lock Status = %04X",i_data.getHalfWord(3));
-// if ( j_data.getHalfWord(3) != 0xF800 ) FAPI_ERR("DP18 0x1C000 PLL failed to lock! Lock Status = %04X",j_data.getHalfWord(3));
-// if ( k_data.getHalfWord(3) != 0xC000 ) FAPI_ERR("AD32S 0x0C001 PLL failed to lock! Lock Status = %04X",k_data.getHalfWord(3));
-// if ( l_data.getHalfWord(3) != 0xC000 ) FAPI_ERR("AD32S 0x1C001 PLL failed to lock! Lock Status = %04X",l_data.getHalfWord(3));
-
-
- poll_count++;
- } while ((done_polling == 0) && (poll_count < 10)); // Poll until PLLs are locked.
-
- if (poll_count == 10)
- {
- FAPI_ERR("DP18 and/or AD32S PLLs failed to lock!");
- if ( i_data.getHalfWord(3) != 0xF800 ) FAPI_ERR("DP18 0x0C000 PLL failed to lock! Lock Status = %04X",i_data.getHalfWord(3));
- if ( j_data.getHalfWord(3) != 0xF800 ) FAPI_ERR("DP18 0x1C000 PLL failed to lock! Lock Status = %04X",j_data.getHalfWord(3));
- if ( k_data.getHalfWord(3) != 0xC000 ) FAPI_ERR("AD32S 0x0C001 PLL failed to lock! Lock Status = %04X",k_data.getHalfWord(3));
- if ( l_data.getHalfWord(3) != 0xC000 ) FAPI_ERR("AD32S 0x1C001 PLL failed to lock! Lock Status = %04X",l_data.getHalfWord(3));
- }
- else
- {
- FAPI_INF("DP18 and AD32S PLLs are now locked.");
- }
-
-
-
- //
- // 10.Write '8024'x into the ADR SysClk Phase Rotator Control Registers and into the DP18 SysClk Phase Rotator Control Registers.
- // This takes the dphy_nclk/SysClk alignment circuit out of reset and puts the dphy_nclk/SysClk alignment circuit into the Continuous Update Mode.
- // ADR SysClk PR Control Registers : (SCOM Addr: 0x800080320301143F, 0x800084320301143F, 0x800180320301143F, 0x800184320301143F,
- // 0x800080320301183F, 0x800084320301183F, 0x800180320301183F, 0x800184320301183F)
- // DP18 SysClk PR Control Registers : (SCOM Addr: 0x800000070301143F, 0x800004070301143F, 0x800008070301143F, 0x80000C070301143F, 0x800010070301143F,
- // 0x800000070301183F, 0x800004070301183F, 0x800008070301183F, 0x80000C070301183F, 0x800010070301183F,
- // 0x800100070301143F, 0x800104070301143F, 0x800108070301143F, 0x80010C070301143F, 0x800110070301143F,
- // 0x800100070301183F, 0x800104070301183F, 0x800108070301183F, 0x80010C070301183F, 0x800110070301183F)
- FAPI_DBG("Step 10: Write '8024'x into the ADR SysClk Phase Rotator Control Registers and into the DP18 SysClk Phase Rotator Control Registers.\n");
- i_data.setHalfWord(3, 0x8024);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S0_0x800080320301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S0_0x800180320301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S1_0x800084320301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S1_0x800184320301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_0_0x800000070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_0_0x800100070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_1_0x800004070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_1_0x800104070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_2_0x800008070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_2_0x800108070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_3_0x80000C070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_3_0x80010C070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_4_0x800010070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_4_0x800110070301143F, i_data); if ( l_rc ) return l_rc;
-
-
-
- //
- // 11.Wait at least 5932 memory clock cycles to allow the clock alignment circuit to perform initial alignment.
- FAPI_DBG("Step 11: Wait at least 5932 memory clock cycles to allow the clock alignment circuit to perform initial alignment.\n");
- fapiDelay(delay_100us, delay_2000000simcycles); // wait 2000000 simcycles (in sim mode) OR 100 usec (in hw mode)
-
-
-
- //
- // 12.Write 0x0000 into the PC Resets Register. This deasserts the SysClk Reset
- // (SCOM Addr: 0x8000C00E0301143F, 0x8001C00E0301143F, 0x8000C00E0301183F, 0x8001C00E0301183F)
- FAPI_DBG("Step 12: Write 0x0000 into the PC Resets Register. This deasserts the SysClk Reset.\n");
- i_data.setHalfWord(3, 0x0000);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_RESETS_P0_0x8000C00E0301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_RESETS_P1_0x8001C00E0301143F, i_data); if ( l_rc ) return l_rc;
-
-
-
- //
- // 13.Write '8020'x into the ADR SysClk Phase Rotator Control Registers and into the DP18 SysClk Phase Rotator Control Registers.
- // This takes the dphy_nclk/SysClk alignment circuit out of Continuous Update Mode.
- // ADR SysClk PR Control Registers : (SCOM Addr: 0x800080320301143F, 0x800084320301143F, 0x800180320301143F, 0x800184320301143F,
- // 0x800080320301183F, 0x800084320301183F, 0x800180320301183F, 0x800184320301183F)
- // DP18 SysClk PR Control Registers : (SCOM Addr: 0x800000070301143F, 0x800004070301143F, 0x800008070301143F, 0x80000C070301143F, 0x800010070301143F,
- // 0x800000070301183F, 0x800004070301183F, 0x800008070301183F, 0x80000C070301183F, 0x800010070301183F,
- // 0x800100070301143F, 0x800104070301143F, 0x800108070301143F, 0x80010C070301143F, 0x800110070301143F,
- // 0x800100070301183F, 0x800104070301183F, 0x800108070301183F, 0x80010C070301183F, 0x800110070301183F)
- FAPI_DBG("Step 13: .\n");
- i_data.setHalfWord(3, 0x8020);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S0_0x800080320301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S0_0x800180320301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S1_0x800084320301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S1_0x800184320301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_0_0x800000070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_0_0x800100070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_1_0x800004070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_1_0x800104070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_2_0x800008070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_2_0x800108070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_3_0x80000C070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_3_0x80010C070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_4_0x800010070301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_4_0x800110070301143F, i_data); if ( l_rc ) return l_rc;
-
-
-
- //
- // 14.Wait at least 32 memory clock cycles.
- FAPI_DBG("Step 14: Wait at least 32 memory clock cycles.\n");
- fapiDelay(delay_100ns, delay_2000simcycles); // wait 2000 simcycles (in sim mode) OR 100 nS (in hw mode)
-
-
-
- //
- // 15.For DD0, use of reset_all results in all DDR configuration informating being erradicated. Therefore, a
- // multitude of registers needs to be reprogrammed via SCOM. The entire list is enumerated in Section 5.2
- // Table 51 of the Neo Spec (those with a value of 2, 3 or 4 in the Notes column). The values of these registers
- // depend on system topology, configuration, physical and environmental characteristics and are maintained in
- // design data.
- // For DD1, this step is skipped as those registers would've been configured via scan initialization and should
- // still be valid due to use of reset_recover.
- FAPI_DBG("Step 15: This step can be skipped for DD1.\n");
-
-
-
- //
- // 16.Write 0x0010 to PC IO PVT N/P FET driver control register to enable internal ZQ calibration.
- // This step takes approximately 2112 (64 * 33) memory clock cycles.
- // (SCOM Addr: 0x8000C0140301143F, 0x8000C0140301183F, 0x8001C0140301143F, 0x8001C0140301183F)
- FAPI_DBG("Step 16: Write 0x0010 to PC IO PVT N/P FET driver control register to enable internal ZQ calibration.\n");
- i_data.setHalfWord(3, 0x0010);
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0_0x8000C0140301143F, i_data); if ( l_rc ) return l_rc;
- l_rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1_0x8001C0140301143F, i_data); if ( l_rc ) return l_rc;
-
- //
-
-
-
-
- FAPI_INF("");
- FAPI_INF("********* ************************** *********");
- FAPI_INF("********* mss_ddr_phy_reset complete *********");
- FAPI_INF("********* ************************** *********");
- return l_rc;
+ {
+
+ rc_ecmd |= i_data.setBitLength(64);
+ rc_ecmd |= j_data.setBitLength(64);
+ rc_ecmd |= k_data.setBitLength(64);
+ rc_ecmd |= l_data.setBitLength(64);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting ecmd data buffer bit length.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+
+
+
+ //
+ // Here are the specific instructions from section 14.7.3 of the Centaur Chip Specification:
+ //
+ // Run cen_ddr_phy_reset.C prepares the DDR PLLs. These PLLs were previously configured via scan init, but have
+ // been held in reset. At this point the PLL GP bit is deasserted to take the PLLs out of reset.
+ // Note - this is done in the cen_startclocks.C procedure.
+ //
+ // The cen_ddr_phy_reset.C now resets the DDR PHY logic. This process will NOT destroy any configuration values
+ // previously loaded via the init file. The intent is for the initialized phase rotator configuration to remain valid after the
+ // soft reset completes. If this assumption fails to hold true, it will require replacing this step with a PHY hard reset,
+ // and then using inband configuration writes to restore all the DDR Configuration Registers.
+ //
+ // The following steps must be performed as part of the PHY reset procedure.
+
+
+
+ //
+ // 1. Drive all control signals to the PHY to their inactive state, idle state, or inactive value.
+ // (Note: The chip should already be in this state.)
+ FAPI_DBG("Step 1: All control signals to the PHYs should already be set to their inactive state, idle state, or inactive values.\n");
+
+
+
+ //
+ // 2. For DD0: Assert dfi_reset_all (GP4 bit 5 = "1") for at least 32 memory clock cycles. This signal DOES
+ // erradicate all DDR configuration register initialization, thereby requiring the DDR registers to be reprogrammed
+ // via SCOM after the PHY reset sequence completes.
+ // For DD1: Set mcbist_ddr_dfi_reset_recover ="1" (CCS_MODEQ(25) SCOM Addr: 0x030106A7 & 0x03010EA7)
+ // for at least 32 memory clock cycles. This signal does NOT reset the configuration registers
+ // within the PHY.
+ FAPI_DBG("Step 2: MBA CCS_MODEQ(25), Setting mcbist_ddr_dfi_reset_recover = 1 for DDR PHY soft reset.\n");
+ rc = fapiGetScom( i_target, MEM_MBA01_CCS_MODEQ_0x030106A7, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error reading CCS_MODEQ register.");
+ break;
+ }
+ rc_ecmd |= i_data.setBit(25);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to set bit 25 of CCS_MODEQ register.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, MEM_MBA01_CCS_MODEQ_0x030106A7, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing CCS_MODEQ register .");
+ break;
+ }
+ rc = fapiDelay(DELAY_100NS, DELAY_2000SIMCYCLES); // wait 2000 simcycles (in sim mode) OR 100 nS (in hw mode)
+ if (rc)
+ {
+ FAPI_ERR("Error executing fapiDelay of 100ns or 2000simcycles.");
+ break;
+ }
+
+
+
+ //
+ // 3. For DD0: Deassert dfi_reset_all (GP4 bit 5 = "0")
+ // For DD1: Deassert mcbist_ddr_dfi_reset_recover = "0" (CCS_MODEQ(25) SCOM Addr: 0x030106A7 0x03010EA7)
+ FAPI_DBG("Step 3: MBA CCS_MODEQ(25), Setting mcbist_ddr_dfi_reset_recover = 0 to release soft reset.\n");
+ rc = fapiGetScom( i_target, MEM_MBA01_CCS_MODEQ_0x030106A7, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error reading CCS_MODEQ register .");
+ break;
+ }
+ rc_ecmd |= i_data.clearBit(25);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to clear bit 25 of CCS_MODEQ register.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, MEM_MBA01_CCS_MODEQ_0x030106A7, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing CCS_MODEQ register.");
+ break;
+ }
+
+
+
+ //
+ // 4. Write 0x0008 to PC IO PVT N/P FET driver control registers to assert ZCTL reset
+ // and reset the internal impedance controller.(SCOM Addr: 0x8000C0140301143F, 0x8000C0140301183F, 0x8001C0140301143F, 0x8001C0140301183F)
+ FAPI_DBG("Step 4: Write 0x0008 to PC IO PVT N/P FET driver control registers to assert ZCTL reset.\n");
+ rc_ecmd |= i_data.setDoubleWord(0, 0x0000000000000008ull);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to write 0x0008 into PC_IO_PVT_FET_CONTROL regs.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0_0x8000C0140301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1_0x8001C0140301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1 register.");
+ break;
+ }
+
+
+
+ //
+ // 5. Write 0x0000 to PC IO PVT N/P FET driver control registers to deassert ZCTL reset
+ // (SCOM Addr: 0x8000C0140301143F, 0x8000C0140301183F, 0x8001C0140301143F, 0x8001C0140301183F)
+ FAPI_DBG("Step 5: Write 0x0000 to PC IO PVT N/P FET driver control registers to deassert ZCTL reset.\n");
+ rc_ecmd |= i_data.setDoubleWord(0, 0x0000000000000000ull);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to write 0x0000 into PC_IO_PVT_FET_CONTROL regs.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0_0x8000C0140301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1_0x8001C0140301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1 register.");
+ break;
+ }
+
+
+
+ //
+ // 6. Write 0x4000 into the PC Resets Registers. This deasserts the PLL_RESET and leaves the SYSCLK_RESET bit active
+ // (SCOM Addr: 0x8000C00E0301143F, 0x8001C00E0301143F, 0x8000C00E0301183F, 0x8001C00E0301183F)
+ FAPI_DBG("Step 6: Write 0x4000 into the PC Resets Regs. This deasserts the PLL_RESET and leaves the SYSCLK_RESET bit active.\n");
+ rc_ecmd |= i_data.setDoubleWord(0, 0x0000000000004000ull);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to write 0x4000 into PC_RESETS registers.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_RESETS_P0_0x8000C00E0301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_RESETS_P0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_RESETS_P1_0x8001C00E0301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_RESETS_P1 register.");
+ break;
+ }
+
+
+
+ //
+ // 7. Wait at least 1 millisecond to allow the PLLs to lock. Otherwise, poll the PC DP18 PLL Lock Status
+ // and the PC AD32S PLL Lock Status to determine if all PLLs have locked.
+ // PC DP18 PLL Lock Status should be 0xF800: (SCOM Addr: 0x8000C0000301143F, 0x8001C0000301143F, 0x8000C0000301183F, 0x8001C0000301183F)
+ // PC AD32S PLL Lock Status should be 0xC000: (SCOM Addr: 0x8000C0010301143F, 0x8001C0010301143F, 0x8000C0010301183F, 0x8001C0010301183F)
+ FAPI_DBG("Step 7: Poll until DP18 and AD32S PLLs have locked....\n");
+ do
+ {
+ rc = fapiDelay(DELAY_1US, DELAY_20000SIMCYCLES); // wait 20000 simcycles (in sim mode) OR 1 usec (in hw mode)
+ if (rc)
+ {
+ FAPI_ERR("Error executing fapiDelay of 1us or 20000simcycles.");
+ break;
+ }
+ done_polling = 1;
+ rc = fapiGetScom( i_target, DPHY01_DDRPHY_PC_DP18_PLL_LOCK_STATUS_P0_0x8000C0000301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error reading DPHY01_DDRPHY_PC_DP18_PLL_LOCK_STATUS_P0 register.");
+ break;
+ }
+ if ( i_data.getHalfWord(3) != DP18_PLL_EXP_LOCK_STATUS ) done_polling = 0;
+ rc = fapiGetScom( i_target, DPHY01_DDRPHY_PC_DP18_PLL_LOCK_STATUS_P1_0x8001C0000301143F, j_data);
+ if (rc)
+ {
+ FAPI_ERR("Error reading DPHY01_DDRPHY_PC_DP18_PLL_LOCK_STATUS_P1 register.");
+ break;
+ }
+ if ( j_data.getHalfWord(3) != DP18_PLL_EXP_LOCK_STATUS ) done_polling = 0;
+ rc = fapiGetScom( i_target, DPHY01_DDRPHY_PC_AD32S_PLL_LOCK_STATUS_P0_0x8000C0010301143F, k_data);
+ if (rc)
+ {
+ FAPI_ERR("Error reading DPHY01_DDRPHY_PC_AD32S_PLL_LOCK_STATUS_P0 register.");
+ break;
+ }
+ if ( k_data.getHalfWord(3) != AD32S_PLL_EXP_LOCK_STATUS ) done_polling = 0;
+ rc = fapiGetScom( i_target, DPHY01_DDRPHY_PC_AD32S_PLL_LOCK_STATUS_P1_0x8001C0010301143F, l_data);
+ if (rc)
+ {
+ FAPI_ERR("Error reading DPHY01_DDRPHY_PC_AD32S_PLL_LOCK_STATUS_P1 register.");
+ break;
+ }
+ if ( l_data.getHalfWord(3) != AD32S_PLL_EXP_LOCK_STATUS ) done_polling = 0;
+ poll_count++;
+ } while ((done_polling == 0) && (poll_count < MAX_POLL_LOOPS)); // Poll until PLLs are locked.
+ if (rc) break; // Go to end of proc if error found inside polling loop.
+
+ if (poll_count == MAX_POLL_LOOPS)
+ {
+ if ( i_data.getHalfWord(3) != DP18_PLL_EXP_LOCK_STATUS )
+ {
+ FAPI_ERR("DP18 0x0C000 PLL failed to lock! Lock Status = %04X",i_data.getHalfWord(3));
+ FAPI_SET_HWP_ERROR(rc, RC_MSS_DP18_0_PLL_FAILED_TO_LOCK);
+ break;
+ }
+ if ( j_data.getHalfWord(3) != DP18_PLL_EXP_LOCK_STATUS )
+ {
+ FAPI_ERR("DP18 0x1C000 PLL failed to lock! Lock Status = %04X",j_data.getHalfWord(3));
+ FAPI_SET_HWP_ERROR(rc, RC_MSS_DP18_1_PLL_FAILED_TO_LOCK);
+ break;
+ }
+ if ( k_data.getHalfWord(3) != AD32S_PLL_EXP_LOCK_STATUS )
+ {
+ FAPI_ERR("AD32S 0x0C001 PLL failed to lock! Lock Status = %04X",k_data.getHalfWord(3));
+ FAPI_SET_HWP_ERROR(rc, RC_MSS_AD32S_0_PLL_FAILED_TO_LOCK);
+ break;
+ }
+ if ( l_data.getHalfWord(3) != AD32S_PLL_EXP_LOCK_STATUS )
+ {
+ FAPI_ERR("AD32S 0x1C001 PLL failed to lock! Lock Status = %04X",l_data.getHalfWord(3));
+ FAPI_SET_HWP_ERROR(rc, RC_MSS_AD32S_1_PLL_FAILED_TO_LOCK);
+ break;
+ }
+ }
+ else
+ {
+ FAPI_INF("DP18 and AD32S PLLs are now locked.");
+ }
+
+
+
+ //
+ // 8.Write '8024'x into the ADR SysClk Phase Rotator Control Registers and into the DP18 SysClk Phase Rotator Control Registers.
+ // This takes the dphy_nclk/SysClk alignment circuit out of reset and puts the dphy_nclk/SysClk alignment circuit into the Continuous Update Mode.
+ // ADR SysClk PR Control Registers : (SCOM Addr: 0x800080320301143F, 0x800084320301143F, 0x800180320301143F, 0x800184320301143F,
+ // 0x800080320301183F, 0x800084320301183F, 0x800180320301183F, 0x800184320301183F)
+ // DP18 SysClk PR Control Registers : (SCOM Addr: 0x800000070301143F, 0x800004070301143F, 0x800008070301143F, 0x80000C070301143F, 0x800010070301143F,
+ // 0x800000070301183F, 0x800004070301183F, 0x800008070301183F, 0x80000C070301183F, 0x800010070301183F,
+ // 0x800100070301143F, 0x800104070301143F, 0x800108070301143F, 0x80010C070301143F, 0x800110070301143F,
+ // 0x800100070301183F, 0x800104070301183F, 0x800108070301183F, 0x80010C070301183F, 0x800110070301183F)
+ FAPI_DBG("Step 8: Write '8024'x into the ADR SysClk Phase Rotator Control Regs and the DP18 SysClk Phase Rotator Control Regs.\n");
+ rc_ecmd |= i_data.setDoubleWord(0, 0x0000000000008024ull);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to write 0x8024 into Phase Rotator Registers.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S0_0x800080320301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S0_0x800180320301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S1_0x800084320301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S1 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S1_0x800184320301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S1 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_0_0x800000070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_0_0x800100070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_1_0x800004070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_1 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_1_0x800104070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_1 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_2_0x800008070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_2 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_2_0x800108070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_2 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_3_0x80000C070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_3 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_3_0x80010C070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_3 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_4_0x800010070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_4 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_4_0x800110070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_4 register.");
+ break;
+ }
+
+
+
+ //
+ // 9.Wait at least 5932 memory clock cycles to allow the clock alignment circuit to perform initial alignment.
+ FAPI_DBG("Step 9: Wait at least 5932 memory clock cycles to allow the clock alignment circuit to perform initial alignment.\n");
+ rc = fapiDelay(DELAY_100US, DELAY_2000000SIMCYCLES); // wait 2000000 simcycles (in sim mode) OR 100 usec (in hw mode)
+ if (rc)
+ {
+ FAPI_ERR("Error executing fapiDelay of 100us or 2000000simcycles.");
+ break;
+ }
+
+
+
+ //
+ // 10.Write 0x0000 into the PC Resets Register. This deasserts the SysClk Reset
+ // (SCOM Addr: 0x8000C00E0301143F, 0x8001C00E0301143F, 0x8000C00E0301183F, 0x8001C00E0301183F)
+ FAPI_DBG("Step 10: Write 0x0000 into the PC Resets Register. This deasserts the SysClk Reset.\n");
+ rc_ecmd |= i_data.setDoubleWord(0, 0x0000000000000000ull);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to write 0x0000 into the PC Resets registers.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_RESETS_P0_0x8000C00E0301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_RESETS_P0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_RESETS_P1_0x8001C00E0301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_RESETS_P1 register.");
+ break;
+ }
+
+
+
+ //
+ // 11.Write '8020'x into the ADR SysClk Phase Rotator Control Registers and into the DP18 SysClk Phase Rotator Control Registers.
+ // This takes the dphy_nclk/SysClk alignment circuit out of Continuous Update Mode.
+ // ADR SysClk PR Control Registers : (SCOM Addr: 0x800080320301143F, 0x800084320301143F, 0x800180320301143F, 0x800184320301143F,
+ // 0x800080320301183F, 0x800084320301183F, 0x800180320301183F, 0x800184320301183F)
+ // DP18 SysClk PR Control Registers : (SCOM Addr: 0x800000070301143F, 0x800004070301143F, 0x800008070301143F, 0x80000C070301143F, 0x800010070301143F,
+ // 0x800000070301183F, 0x800004070301183F, 0x800008070301183F, 0x80000C070301183F, 0x800010070301183F,
+ // 0x800100070301143F, 0x800104070301143F, 0x800108070301143F, 0x80010C070301143F, 0x800110070301143F,
+ // 0x800100070301183F, 0x800104070301183F, 0x800108070301183F, 0x80010C070301183F, 0x800110070301183F)
+ FAPI_DBG("Step 11: Write '8020'x into the ADR SysClk Phase Rotator Control Regs and the DP18 SysClk Phase Rotator Control Regs.\n");
+ rc_ecmd |= i_data.setDoubleWord(0, 0x0000000000008020ull);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to write 0x8020 into the Phase Rotator registers.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S0_0x800080320301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S0_0x800180320301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S1_0x800084320301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P0_ADR32S1 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S1_0x800184320301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_ADR_SYSCLK_CNTL_PR_P1_ADR32S1 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_0_0x800000070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_0_0x800100070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_1_0x800004070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_1 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_1_0x800104070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_1 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_2_0x800008070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_2 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_2_0x800108070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_2 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_3_0x80000C070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_3 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_3_0x80010C070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_3 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_4_0x800010070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P0_4 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_4_0x800110070301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_DP18_SYSCLK_PR_P1_4 register.");
+ break;
+ }
+
+
+
+ //
+ // 12.Wait at least 32 memory clock cycles.
+ FAPI_DBG("Step 12: Wait at least 32 memory clock cycles.\n");
+ rc = fapiDelay(DELAY_100NS, DELAY_2000SIMCYCLES); // wait 2000 simcycles (in sim mode) OR 100 nS (in hw mode)
+ if (rc)
+ {
+ FAPI_ERR("Error executing fapiDelay of 100ns or 2000simcycles.");
+ break;
+ }
+
+
+
+ //
+ // 13.Write 0x0010 to PC IO PVT N/P FET driver control register to enable internal ZQ calibration.
+ // This step takes approximately 2112 (64 * 33) memory clock cycles.
+ // (SCOM Addr: 0x8000C0140301143F, 0x8000C0140301183F, 0x8001C0140301143F, 0x8001C0140301183F)
+ FAPI_DBG("Step 13: Write 0x0010 to PC IO PVT N/P FET driver control register to enable internal ZQ calibration.\n");
+ rc_ecmd |= i_data.setDoubleWord(0, 0x0000000000000010ull);
+ if (rc_ecmd)
+ {
+ FAPI_ERR("Error 0x%x setting up ecmd data buffer to write 0x0010 into the PC_IO_PVT_FET_CONTROL registers.", rc_ecmd);
+ rc.setEcmdError(rc_ecmd);
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0_0x8000C0140301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P0 register.");
+ break;
+ }
+ rc = fapiPutScom( i_target, DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1_0x8001C0140301143F, i_data);
+ if (rc)
+ {
+ FAPI_ERR("Error writing DPHY01_DDRPHY_PC_IO_PVT_FET_CONTROL_P1 register.");
+ break;
+ }
+
+
+
+
+ } while(0);
+
+ FAPI_INF("********* mss_ddr_phy_reset complete *********");
+ return rc;
}
} //end extern C
@@ -429,13 +634,21 @@ ReturnCode mss_ddr_phy_reset(Target i_target) {
-
/*
*************** Do not edit this area ***************
This section is automatically updated by CVS when you check in this file.
Be sure to create CVS comments when you commit so that they can be included here.
$Log: mss_ddr_phy_reset.C,v $
+Revision 1.7 2012/05/31 18:27:54 mfred
+Removing some config settings that are now done in config file. See Gary Van Huben note May 3, 2012
+
+Revision 1.6 2012/03/21 18:16:25 mfred
+Remove some commented out lines.
+
+Revision 1.5 2012/03/21 18:12:24 mfred
+Made updates requested by GFW team during code review 1.
+
Revision 1.4 2012/02/22 18:36:36 mfred
update for PLL lock polling, and check for ddr3 vs ddr4
@@ -467,6 +680,5 @@ Revision 1.1 2011/04/07 16:15:03 mfred
Initial release.
-
*/
diff --git a/src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.H b/src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.H
index cb5556733..9ef643a3c 100644
--- a/src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.H
+++ b/src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.H
@@ -1,26 +1,27 @@
-// IBM_PROLOG_BEGIN_TAG
-// This is an automatically generated prolog.
-//
-// $Source: src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.H $
-//
-// IBM CONFIDENTIAL
-//
-// COPYRIGHT International Business Machines Corp. 2012
-//
-// p1
-//
-// Object Code Only (OCO) source materials
-// Licensed Internal Code Source Materials
-// IBM HostBoot Licensed Internal Code
-//
-// The source code for this program is not published or other-
-// wise divested of its trade secrets, irrespective of what has
-// been deposited with the U.S. Copyright Office.
-//
-// Origin: 30
-//
-// IBM_PROLOG_END
-// $Id: mss_ddr_phy_reset.H,v 1.1 2011/11/19 19:19:34 mfred Exp $
+/* IBM_PROLOG_BEGIN_TAG
+ * This is an automatically generated prolog.
+ *
+ * $Source: src/usr/hwpf/hwp/dram_training/mss_ddr_phy_reset/mss_ddr_phy_reset.H $
+ *
+ * IBM CONFIDENTIAL
+ *
+ * COPYRIGHT International Business Machines Corp. 2012
+ *
+ * p1
+ *
+ * Object Code Only (OCO) source materials
+ * Licensed Internal Code Source Materials
+ * IBM HostBoot Licensed Internal Code
+ *
+ * The source code for this program is not published or other-
+ * wise divested of its trade secrets, irrespective of what has
+ * been deposited with the U.S. Copyright Office.
+ *
+ * Origin: 30
+ *
+ * IBM_PROLOG_END_TAG
+ */
+// $Id: mss_ddr_phy_reset.H,v 1.2 2012/03/21 18:12:28 mfred Exp $
// $Source: /afs/awd/projects/eclipz/KnowledgeBase/.cvsroot/eclipz/chips/centaur/working/procedures/ipl/fapi/mss_ddr_phy_reset.H,v $
//------------------------------------------------------------------------------
// *! (C) Copyright International Business Machines Corp. 2011
@@ -49,18 +50,22 @@
#include <fapi.H>
+typedef fapi::ReturnCode (*mss_ddr_phy_reset_FP_t)(const fapi::Target& i_target);
+
extern "C"
{
+ // Target is centaur.mba
/**
- * @brief ddr_phy_reset procedure.
+ * @brief mss_ddr_phy_reset procedure. The purpose of this procedure is to do a soft reset of the DDR PHY logic and cause the DDR PLLs to lock.
*
- * @param[in] i_target Reference to target
+ * @param[in] i_target Reference to centaur.mba target
*
* @return ReturnCode
*/
-fapi::ReturnCode mss_ddr_phy_reset(const fapi::Target target);
+ fapi::ReturnCode mss_ddr_phy_reset(const fapi::Target& i_target);
+ // Target is centaur.mba
} // extern "C"
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