/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #define PMIF_CMD_PER_3 (0x1 << PMIF_CMD_EXT_REG_LONG) #define PMIF_CMD_PER_1_3 ((0x1 << PMIF_CMD_REG) | (0x1 << PMIF_CMD_EXT_REG_LONG)) /* SPMI_MST, SPMI_SAMPL_CTRL */ DEFINE_BIT(SAMPL_CK_POL, 0) DEFINE_BITFIELD(SAMPL_CK_DLY, 3, 1) /* PMIF, SPI_MODE_CTRL */ DEFINE_BIT(SPI_MODE_CTRL, 7) DEFINE_BIT(SRVOL_EN, 11) DEFINE_BIT(SPI_MODE_EXT_CMD, 12) DEFINE_BIT(SPI_EINT_MODE_GATING_EN, 13) /* PMIF, SLEEP_PROTECTION_CTRL */ DEFINE_BITFIELD(SPM_SLEEP_REQ_SEL, 1, 0) DEFINE_BITFIELD(SCP_SLEEP_REQ_SEL, 10, 9) static const struct spmi_device spmi_dev[] = { { .slvid = SPMI_SLAVE_6, .type = BUCK_CPU, .type_id = BUCK_CPU_ID, }, { .slvid = SPMI_SLAVE_7, .type = BUCK_GPU, .type_id = BUCK_GPU_ID, }, }; static int spmi_read_check(struct pmif *pmif_arb, int slvid) { u32 rdata = 0; pmif_arb->read(pmif_arb, slvid, MT6315_READ_TEST, &rdata); if (rdata != MT6315_DEFAULT_VALUE_READ) { printk(BIOS_ERR, "%s next, slvid:%d rdata = 0x%x.\n", __func__, slvid, rdata); return -E_NODEV; } pmif_arb->read(pmif_arb, slvid, MT6315_READ_TEST_1, &rdata); if (rdata != MT6315_DEFAULT_VALUE_READ) { printk(BIOS_ERR, "%s next, slvid:%d rdata = 0x%x.\n", __func__, slvid, rdata); return -E_NODEV; } return 0; } static int spmi_cali_rd_clock_polarity(struct pmif *pmif_arb, const struct spmi_device *dev) { int i; bool success = false; const struct cali cali_data[] = { {SPMI_CK_DLY_1T, SPMI_CK_POL_POS}, {SPMI_CK_NO_DLY, SPMI_CK_POL_POS}, {SPMI_CK_NO_DLY, SPMI_CK_POL_NEG}, {SPMI_CK_DLY_1T, SPMI_CK_POL_NEG}, }; /* Indicate sampling clock polarity, 1: Positive 0: Negative */ for (i = 0; i < ARRAY_SIZE(cali_data); i++) { SET32_BITFIELDS(&mtk_spmi_mst->mst_sampl, SAMPL_CK_DLY, cali_data[i].dly, SAMPL_CK_POL, cali_data[i].pol); if (spmi_read_check(pmif_arb, dev->slvid) == 0) { success = true; break; } } if (!success) die("ERROR - calibration fail for spmi clk"); return 0; } static int spmi_mst_init(struct pmif *pmif_arb) { int i; if (!pmif_arb) { printk(BIOS_ERR, "%s: null pointer for pmif dev.\n", __func__); return -E_INVAL; } pmif_spmi_iocfg(); spmi_config_master(); for (i = 0; i < ARRAY_SIZE(spmi_dev); i++) spmi_cali_rd_clock_polarity(pmif_arb, &spmi_dev[i]); return 0; } static void pmif_spmi_force_normal_mode(int mstid) { struct pmif *arb = get_pmif_controller(PMIF_SPMI, mstid); /* listen srclken_0 only for entering normal or sleep mode */ SET32_BITFIELDS(&arb->mtk_pmif->spi_mode_ctrl, SPI_MODE_CTRL, 0, SRVOL_EN, 0, SPI_MODE_EXT_CMD, 1, SPI_EINT_MODE_GATING_EN, 1); /* enable spm/scp sleep request */ SET32_BITFIELDS(&arb->mtk_pmif->sleep_protection_ctrl, SPM_SLEEP_REQ_SEL, 0, SCP_SLEEP_REQ_SEL, 0); } static void pmif_spmi_enable_swinf(int mstid) { struct pmif *arb = get_pmif_controller(PMIF_SPMI, mstid); write32(&arb->mtk_pmif->inf_en, PMIF_SPMI_SW_CHAN); write32(&arb->mtk_pmif->arb_en, PMIF_SPMI_SW_CHAN); } static void pmif_spmi_enable_cmdIssue(int mstid, bool en) { struct pmif *arb = get_pmif_controller(PMIF_SPMI, mstid); /* Enable cmdIssue */ write32(&arb->mtk_pmif->cmdissue_en, en); } static void pmif_spmi_enable(int mstid) { struct pmif *arb = get_pmif_controller(PMIF_SPMI, mstid); u32 cmd_per; /* clear all cmd permission for per channel */ write32(&arb->mtk_pmif->inf_cmd_per_0, 0); write32(&arb->mtk_pmif->inf_cmd_per_1, 0); write32(&arb->mtk_pmif->inf_cmd_per_2, 0); write32(&arb->mtk_pmif->inf_cmd_per_3, 0); /* enable if we need cmd 0~3 permission for per channel */ cmd_per = PMIF_CMD_PER_3 << 28 | PMIF_CMD_PER_3 << 24 | PMIF_CMD_PER_3 << 20 | PMIF_CMD_PER_3 << 16 | PMIF_CMD_PER_3 << 8 | PMIF_CMD_PER_3 << 4 | PMIF_CMD_PER_1_3 << 0; write32(&arb->mtk_pmif->inf_cmd_per_0, cmd_per); cmd_per = PMIF_CMD_PER_3 << 4; write32(&arb->mtk_pmif->inf_cmd_per_1, cmd_per); /* * set bytecnt max limitation. * hw bytecnt indicate when we set 0, it can send 1 byte; * set 1, it can send 2 byte. */ write32(&arb->mtk_pmif->inf_max_bytecnt_per_0, 0); write32(&arb->mtk_pmif->inf_max_bytecnt_per_1, 0); write32(&arb->mtk_pmif->inf_max_bytecnt_per_2, 0); write32(&arb->mtk_pmif->inf_max_bytecnt_per_3, 0); /* Add latency limitation */ write32(&arb->mtk_pmif->lat_cnter_en, PMIF_SPMI_INF); write32(&arb->mtk_pmif->lat_limit_0, 0); write32(&arb->mtk_pmif->lat_limit_1, 0x4); write32(&arb->mtk_pmif->lat_limit_2, 0x8); write32(&arb->mtk_pmif->lat_limit_4, 0x8); write32(&arb->mtk_pmif->lat_limit_6, 0x3FF); write32(&arb->mtk_pmif->lat_limit_9, 0x4); write32(&arb->mtk_pmif->lat_limit_loading, PMIF_SPMI_INF); write32(&arb->mtk_pmif->inf_en, PMIF_SPMI_INF); write32(&arb->mtk_pmif->arb_en, PMIF_SPMI_INF); write32(&arb->mtk_pmif->timer_ctrl, 0x3); write32(&arb->mtk_pmif->init_done, 1); } int pmif_spmi_init(struct pmif *arb) { if (arb->is_pmif_init_done(arb) != 0) { pmif_spmi_force_normal_mode(arb->mstid); pmif_spmi_enable_swinf(arb->mstid); pmif_spmi_enable_cmdIssue(arb->mstid, true); pmif_spmi_enable(arb->mstid); if (arb->is_pmif_init_done(arb)) return -E_NODEV; } if (spmi_mst_init(arb)) { printk(BIOS_ERR, "[%s] failed to init spmi master\n", __func__); return -E_NODEV; } return 0; }