+ pa_curr = ul_gpp_pa;
+ va_curr = ul_dyn_ext_base * hio_mgr->word_size;
+ gpp_va_curr = ul_gpp_va;
+ num_bytes = ul_seg1_size;
+
+ va_curr = iommu_kmap(mmu, va_curr, pa_curr, num_bytes,
+ IOVMF_ENDIAN_LITTLE | IOVMF_ELSZ_32);
+ if (IS_ERR_VALUE(va_curr)) {
+ status = (int)va_curr;
+ goto func_end;
+ }
+
+ pa_curr += ul_pad_size + num_bytes;
+ va_curr += ul_pad_size + num_bytes;
+ gpp_va_curr += ul_pad_size + num_bytes;
+
+ /* Configure the TLB entries for the next cacheable segment */
+ num_bytes = ul_seg_size;
+ va_curr = ul_dsp_va * hio_mgr->word_size;
+ while (num_bytes) {
+ /*
+ * To find the max. page size with which both PA & VA are
+ * aligned.
+ */
+ all_bits = pa_curr | va_curr;
+ dev_dbg(bridge, "all_bits for Seg1 %x, pa_curr %x, "
+ "va_curr %x, num_bytes %x\n", all_bits, pa_curr,
+ va_curr, num_bytes);
+ for (i = 0; i < 4; i++) {
+ if (!(num_bytes >= page_size[i]) ||
+ !((all_bits & (page_size[i] - 1)) == 0))
+ continue;
+ if (ndx < MAX_LOCK_TLB_ENTRIES) {
+ /*
+ * This is the physical address written to
+ * DSP MMU.
+ */
+ ae_proc[ndx].ul_gpp_pa = pa_curr;
+ /*
+ * This is the virtual uncached ioremapped
+ * address!!!
+ */
+ ae_proc[ndx].ul_gpp_va = gpp_va_curr;
+ ae_proc[ndx].ul_dsp_va =
+ va_curr / hio_mgr->word_size;
+ ae_proc[ndx].ul_size = page_size[i];
+ ae_proc[ndx].endianism = HW_LITTLE_ENDIAN;
+ ae_proc[ndx].elem_size = HW_ELEM_SIZE16BIT;
+ ae_proc[ndx].mixed_mode = HW_MMU_CPUES;
+ dev_dbg(bridge, "shm MMU TLB entry PA %x"
+ " VA %x DSP_VA %x Size %x\n",
+ ae_proc[ndx].ul_gpp_pa,
+ ae_proc[ndx].ul_gpp_va,
+ ae_proc[ndx].ul_dsp_va *
+ hio_mgr->word_size, page_size[i]);
+ ndx++;
+ }
+ pa_curr += page_size[i];
+ va_curr += page_size[i];
+ gpp_va_curr += page_size[i];
+ num_bytes -= page_size[i];
+ /*
+ * Don't try smaller sizes. Hopefully we have reached
+ * an address aligned to a bigger page size.
+ */
+ break;
+ }
+ }